JP6738032B1 - Amusement machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gaming machine capable of more appropriately acquiring symbol data of a symbol on an activated line. A first position (lower left stage) that is a reference position of a left reel 31 and a second position (upper left stage) that is a symbol position on at least one activated line of the left reel 31. It is provided with a symbol array table storing symbol data. In the game in which the symbol of the predetermined symbol number (for example, 0) of the left reel 31 is stopped at the reference position (lower left stage), it is stopped on the effective line (upper left stage) based on the predetermined symbol number and the symbol arrangement table. It becomes possible to acquire the symbol data of the symbol (the symbol data of the symbol number 2). [Selection diagram] FIG. 228

Description

The present invention relates to a gaming machine.

Conventionally, a slot machine is known as one of the gaming machines (for example, refer to Patent Document 1).

JP, 2016-214434, A

The problem to be solved by the present invention is to improve the performance as a game machine.

The present invention solves the above-mentioned problems by the following solution means (shown in parentheses is the configuration of a corresponding embodiment) .
The present invention (Example 1 of the 27th embodiment (or 25th embodiment)) is
The reel (31) includes at least a first reel (left reel) and a second reel (middle reel),
A first position (lower left) which is a reference position of the first reel, and a second position (second position is different from the first position) which is a symbol position on at least one effective line of the first reel (upper left) ) And
Third position as the reference position of the second reel (the third position and the first position are located on the same horizontal line) (middle and lower), and a symbol on at least one effective line of the second reel Position 4th position (the 4th position and the 2nd position are not located on the same horizontal line. Further, the 4th position and the 3rd position may be different positions or the same position.) (Medium) Middle))) and
A first data table (the symbol arrangement table of FIG. 228(B) ) storing the symbol data corresponding to the first reel (“the symbol data” means data indicating the type of symbol. The same applies hereinafter ) , and
A second data table storing the symbol data corresponding to the second reel (the symbol array table of FIG. 228(B)) ;
In the storage area of the first address (1000 (H)) of the first data table, the symbol data of the reference symbol number (symbol number 2) of the first reel is stored,
In the game in which the symbol of the predetermined symbol number of the first reel stops at the first position, the symbol data of the symbol stopped at the second position can be acquired from the first data table based on the predetermined symbol number,
In the storage area of the first address (1100 (H)) of the second data table, the reference symbol number of the second reel (the reference symbol number of the second reel and the reference symbol number of the first reel are different) (symbol) The number 1) pattern data is stored,
In the game in which the symbol of the specific symbol number of the second reel stops at the third position, the symbol data of the symbol that stops at the fourth position can be acquired from the second data table based on the specific symbol number. And

According to the present invention, the performance as a game machine can be improved.

In the present embodiment, it is a block diagram showing an outline of control of a slot machine which is an example of a gaming machine. In the present embodiment, it is a front view for explaining how a medal inserted from a medal insertion slot passes through an insertion sensor. In the first embodiment (A), it is a diagram illustrating a voltage drop when a power failure occurs in a time chart. It is a figure explaining the relationship between an insertion sensor and passage of a medal in a 1st embodiment (B). In 1st Embodiment (B), it is a figure explaining ON/OFF of an injection|pouring sensor with a time chart. In the first embodiment (C), it is a schematic diagram when a medal is ejected from the medal payout device. In the first embodiment (C), it is a schematic diagram showing the state of ON (detection) / OFF (non-detection) of the payout sensor when the medal is sent from the medal payout device. In 1st Embodiment (C), it is a figure which shows ON/OFF of a payout sensor by a time chart. In 2nd Embodiment, it is a disassembled perspective view which shows the outline of a main control board and a board case. In 2nd Embodiment, (a) is a top view which shows the board case which accommodated the main control board. (B) is a sectional view taken along the line AA showing Example 1 of the trace of the gate. FIG. 6C is a cross-sectional view taken along the line AA showing Example 2 of the trace of the gate. FIG. 16 is a diagram illustrating a flow of processing when a disconnection occurs between a main control board and a sub control board in the third embodiment. In 4th Embodiment, it is sectional drawing (a schematic diagram) explaining movement of the stop button of a stop switch, (a) shows a no-load state, (b) is when a detection sensor changes from OFF to ON. The state is shown, (c) shows the state where the stop button is pushed to the deepest part, and (d) shows the state when the push of the stop button is released and the detection sensor is turned from on to off. In 4th Embodiment, it is a figure which shows the relationship of the movement of a stop button and the excitation state of a motor with a time chart, (a) shows Example 1, (b) shows Example 2. In the fifth embodiment, it is a diagram showing the relationship between the on/off of the power supply and the voltage level in a time chart, (a) shows the power off after the main program started, (b) before the main program started. Indicates a power failure. In the sixth embodiment, (a) is a plan view of the medal payout device showing a state before the last ejected medal is in contact with the fixed shaft and the movable shaft, and (b) is a plan view of the last ejected medal with the fixed shaft and FIG. 7 is a plan view of the medal payout device showing a state in which the rotation of the hopper disc has advanced from the state (a) before being brought into contact with the movable shaft. In the sixth embodiment, (a) is a plan view of the medal payout device showing a state in which the last ejected medal is in contact with the fixed axis and the movable axis, and (b) is movable by being pushed by the last ejected medal. It is a plan view of the medal payout device showing a state in which the shaft has moved. In the sixth embodiment, (a) is a plan view of a medal payout device showing a state at the moment when the last ejected medal is ejected from the ejecting section, and (b) is a diagram showing a state after ejecting the last ejected medal, It is a plan view of the medal payout device showing a state in which the rotation of the hopper disc is stopped. It is a time chart which shows the drive signal of a hopper motor in a 6th embodiment, the drive state of a hopper motor, and the relation of the discharge condition of the medal from a discharge part. It is a figure which shows the operation|movement of the main control board|substrate in 6th Embodiment, the drive state of a hopper motor, the detection state of a payout sensor, and the medal discharge timing. It is a flowchart which shows the flow of the payout process in 6th Embodiment. It is a flowchart which shows the modification of the flow of the payout process in 6th Embodiment. In the seventh embodiment, it is a side sectional view of the slot machine with the front door closed, and is a view for explaining the positional relationship between the main control board and the sub control board. FIG. 27 is a diagram illustrating a positional relationship between the main CPU on the main control board and the electrolytic capacitor on the sub control board when the slot machine is viewed from the front with the front door closed in the seventh embodiment. ) Indicates Example 1, and (b) indicates Example 2. FIG. 27 is a diagram illustrating a positional relationship between the main CPU on the main control board and the electrolytic capacitor on the sub control board when the slot machine is viewed from the front with the front door closed in the seventh embodiment. ) Indicates Example 3, and (d) indicates Example 4. In the eighth embodiment, it is an enlarged side cross-sectional view of the lower front portion (A portion in FIG. 22) of the housing of the slot machine in the state where the front door is closed, and is a view for explaining the gap between the cabinet and the front door. is there. In the ninth embodiment, (a) is a diagram showing types of special roles (features) and ending conditions, and (b) is a diagram showing types of gaming states and a prescribed number of each gaming state, (C) is a diagram showing a table of numbers of internal lottery and advantageous zone lottery in setting 1. It is a figure which shows the production|generation determination table used for non-RT and RT (non-AT) common in 9th Embodiment. It is a figure which shows the production|generation determination table used commonly in RB inside and BB inside in 9th Embodiment. It is a figure which shows the example 1 of a test pattern display of the management information display LED in 10th Embodiment. It is a figure which shows the example 2 of the test pattern display of the management information display LED in 10th Embodiment. In the eleventh embodiment, (A) is a diagram showing various LEDs on a display substrate, (B) is a diagram showing management information display LEDs, and (C) is a diagram showing set value display LEDs. Is. In the eleventh embodiment, it is a diagram showing the relationship between the digits 1a to 5a and the digits 1b to 5b and the segments A to G and P. It is a figure which shows the output port in 11th Embodiment. In the eleventh embodiment, (A) is a diagram showing a relationship among an interrupt, an LED display counter value, a digit signal and a segment signal. In addition, (B) is a diagram showing an LED display request flag. It is a figure which shows the address of the data memorize|stored in RWM, a label name, a name, etc. It is a figure explaining the concept of a difference number counter value, (a) shows Example 1 and (b) shows Example 2. It is a figure which shows the relationship between a difference number counter value and an advantageous area, (a) shows Example 1, (b) shows Example 2. It is a flow chart which shows program start processing (M_PRG_START) by a main control board. 39 is a flowchart showing the setting change process (M_RANK_SET) in step S212 in FIG. 38. It is a flowchart which shows the power supply restoration process (M_POWER_ON) of step S213 in FIG. It is a flowchart which shows the main process (M_MAIN) in 11th Embodiment. 41 is a flowchart showing the game start set processing (M_GAME_SET) in step S272 in FIG. 41 is a flowchart showing an AT game number counter updating process in step S281 in FIG. FIG. 42 is a flowchart showing an advantageous zone transition lottery process in step S283 in FIG. 45 is a flowchart showing an advantageous zone shift process in step S347 of FIG. 44. 47 is a flowchart showing an AT lottery process in step S355 of FIG. 46 is a flowchart showing an AT initial game number determination process in step S363 in FIG. 42 is a flowchart showing a pressing order instruction number setting process (M_ORD_INF) in step S284 of FIG. FIG. 42 is a flowchart showing a medal payout process (MS_WIN_PAY) by winning in step S294 in FIG. 42 is a flowchart showing the game end check processing (M_GAME_CHK) in step S301 of FIG. 41. It is a flowchart which shows the example 1 of the advantageous area counter management in step S416 of FIG. It is a flowchart which shows the example 2 of advantageous zone counter management in step S416 of FIG. It is a flowchart which shows an interruption process (I_INTR). It is a flowchart which shows the power-off process (I_POWER_DOWN) in step S453 of FIG. It is a flowchart which shows LED display control (I_LED_OUT) in step S453 in FIG. It is a flow chart which shows sub difference number counter management processing in an 11th embodiment. It is a flowchart which shows the sub difference number counter management process in 11th Embodiment, and is a flowchart following FIG. In the twelfth embodiment, (A) shows an accessory condition device and an operation end condition, (B) shows a specified number for each RT, and (C) shows a winning number for each winning number. It is a front view, a top view, and a right side view showing an outline of composition including a reel and a stop switch in a 13th embodiment. In 14th Embodiment (A), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated after the minimum game time has elapsed. In 14th Embodiment (A), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated before the minimum game time has elapsed. It is a flow chart which shows the main processing (M_MAIN) in a 14th embodiment (B). In 14th Embodiment (B), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated after the minimum game time has elapsed. In 14th Embodiment (B), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated before the minimum game time has elapsed. It is a flowchart which shows the main process (M_MAIN) in 14th Embodiment (C). It is a flowchart which shows the medal payout process (M_WIN_PAY) by winning in 14th Embodiment (C). In 14th Embodiment (C), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated after the minimum game time has elapsed. In 14th Embodiment (C), it is a time chart which shows the timing of the display start and the display end of the push order instruction information when the start switch is operated before the minimum game time has elapsed. It is a flowchart which shows the main processing (M_MAIN) in 14th Embodiment (D). In 14th Embodiment (D), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated after the minimum game time has elapsed. In 14th Embodiment (D), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated before the minimum game time has elapsed. It is a flow chart which shows the main processing (M_MAIN) in a 14th embodiment (E). In the fourteenth embodiment (E), it is a time chart showing the display start and display end timing of the pushing order instruction information when the start switch is operated after the minimum game time has elapsed. In 14th Embodiment (E), it is a time chart which shows the timing of the display start and display end of the push order instruction information when the start switch is operated before the minimum game time has elapsed. It is a front view which shows the outline of a structure containing the reel in 14th Embodiment (F), an operation instruction lamp, and a stop switch. In the fourteenth embodiment (F), it is a time chart showing the timing of starting and ending the display of the pushing order instruction information when the start switch is operated after the minimum game time has elapsed. In the fourteenth embodiment (F), it is a time chart showing the display start timing and display end timing of the pushing order instruction information when the start switch is operated before the minimum game time has elapsed. In the fourteenth embodiment (G), it is a time chart showing the timing of starting and ending the display of the pushing order instruction information when the start switch is operated after the minimum game time has elapsed. In the fourteenth embodiment (G), it is a time chart showing the timing of starting and ending the display of the pushing order instruction information when the start switch is operated before the minimum game time has elapsed. It is a figure which shows the execution timing of the addition process of the medal in 15th Embodiment (A). It is a figure which shows the execution timing of the addition process of the medal in 15th Embodiment (B). It is a figure which shows the execution timing of the addition process of the medal in 15th Embodiment (C). It is the schematic diagram which looked at the medal selector, the chute passage 48, and the chute sensor 49 in 16th Embodiment from the front. It is a front view of the passage formation member in a 17th embodiment. It is a rear view of the passage formation member in a 17th embodiment. It is a left view of the passage formation member in a 17th embodiment. FIG. 86 is a cross-sectional view taken along the line AA of FIG. 85 of the passage forming member according to the seventeenth embodiment. It is a figure which shows the main thing of the storage area of RWM demonstrated in 18th Embodiment. It is a time chart (example 1) which shows the output timing of the external signal 4 and the external signal 5 in 18th Embodiment. It is a time chart (example 2) which shows the output timing of the external signal 4 and the external signal 5 in 18th Embodiment. It is a flowchart (example 1) which shows an external signal output process in 18th Embodiment. It is a flowchart (example 1) which shows an external signal output process in 18th Embodiment, and is a flowchart following FIG. It is a flowchart (example 2) which shows an external signal output process in 18th Embodiment. It is a flowchart (example 3) which shows an external signal output process in 18th Embodiment. It is a block diagram showing an outline of control of a slot machine in a nineteenth embodiment (A). In the 19th embodiment, it is a time chart showing a relationship between a setting change state, a setting change end sound and a lamp effect, and one game time described later. It is an external perspective view of the pachinko gaming machine as viewed from the front side (player side). It is an external perspective view of the pachinko gaming machine seen from the back side. It is a block diagram in a pachinko game machine. It is a flow chart explaining the flow of starting after turning on the power of the pachinko game machine. It is a flowchart which shows the setting change process in step S702 of FIG. It is a flow chart showing a flow of one game in a pachinko game machine. FIG. 4 is an exploded perspective view of the board case (upper case and lower case) and the main control board as seen from the front side. FIG. 4 is an exploded perspective view of the board case (upper case and lower case) and the main control board as viewed from the rear side. FIG. 6 is an external perspective view showing a state in which a main control board is accommodated in a board case. It is the front view which looked at the state where the main control board was stored in the board case from the front side. It is the front view which looked at the state where the main control board was stored in the board case from the back (back) side. FIG. 4 is a side sectional view showing a fitting state between the upper case and the lower case, (a) showing a temporary fitting state (before sliding movement), and (b) showing a final fitting state (after sliding movement). .. FIG. 9 is a plan view of the vicinity of the side wall as seen from the lower case side in the temporarily fitted state. It is a top view showing the state where the harness was connected to the connector of the main control board. It is a front view which shows a harness and its connector terminal in detail. It is a perspective view which shows the example which hides the lead wire regarding starting. FIG. 6 is a side sectional view showing a positional relationship among an upper case of the substrate case, a cover, a setting key insertion opening, and a setting change (reset) switch. It is a figure which shows the symbol arrangement of the reel in 23rd Embodiment. It is a figure which shows the display window, the effective line, etc. in 23rd Embodiment. It is a figure (1) which shows the symbol combination of a winning combination, the number of payouts, etc. in a 23rd embodiment. It is a figure (2) which shows the symbol combination of a winning combination, the number of payouts, and the like in the twenty-third embodiment. It is a figure (3) which shows the symbol combination of a winning combination, the number of payouts, and the like in the twenty-third embodiment. It is a figure (4) which shows the symbol combination of a winning combination, the number of payouts, and the like in the twenty-third embodiment. It is a figure (5) which shows the symbol combination of a winning combination, the number of payouts, and the like in the twenty-third embodiment. It is a figure (6) which shows the symbol combination of a winning combination, the number of payouts, and the like in the twenty-third embodiment. It is a figure (1) which shows the condition device and winning combination in 23rd Embodiment. It is a figure (2) which shows the condition device, a winning combination, etc. in 23rd Embodiment. It is a figure (3) which shows the condition device, winning combination, etc. in 23rd Embodiment. It is a figure (4) which shows the condition apparatus, winning combination, etc. in 23rd Embodiment. It is a figure which shows the number table (non-RT) in 23rd Embodiment. It is a figure which shows the register table (RT1) in 23rd Embodiment. It is a figure in the 23rd Embodiment which shows the numerical table (during 1BB operation and RB non-inside). It is a figure which shows the numerical table (during 1BB operation|movement and inside RB) in 23rd Embodiment. It is a figure which shows the numerical table (during 1BB operation and RB operation) in 23rd Embodiment. It is a figure which shows RT transition in 23rd Embodiment. It is a figure which shows the transition of the main game state in 23rd Embodiment. It is a figure (1) which shows the content of RWM in 23rd Embodiment. It is a figure (2) which shows the content of RWM in 23rd Embodiment. It is a figure (3) which shows the content of RWM in 23rd Embodiment. It is a figure (4) which shows the content of RWM in 23rd Embodiment. It is a figure (5) which shows the content of RWM in 23rd Embodiment. It is a figure (6) which shows the content of RWM in 23rd Embodiment. It is a flowchart which shows the main processing (M_MAIN) in 23rd Embodiment. It is a flow chart which shows start switch acceptance processing (M_START_CTL) in a 23rd embodiment. It is a flow chart which shows a symbol stop signal set (S_IF_SET) in a 23rd embodiment. It is a figure which shows the stop acceptance designation table 1 (TBL_ORD_INF1) and the stop acceptance designation table 2 ((TBL_ORD_INF1)) in 23rd Embodiment. It is a flow chart which shows standby production start (M_TARPIC_EXE) in a 23rd embodiment. It is a figure showing the reel production data table (TBL_TARPIC_DAT) in a 23rd embodiment. It is a figure which shows the reel production execution timer tables 1-8 (TBL_TARPIC_TM1-TM8) in 23rd Embodiment. It is a flowchart which shows the reel stop acceptance check (M_STOP_CHK) in 23rd Embodiment. It is a flow chart which shows a stop design set (M_STOPPIC_SET) in a 23rd embodiment. It is a flow chart which shows the game end check processing (M_GAME_CHK) in step S753 of FIG. 139. It is a flow chart which shows the main game state game end time processing in step S941 of FIG. 148. FIG. 146 is a flowchart showing an advantageous section end preparation (M_ADVEND_STBY) in step S957 of FIG. 149. FIG. It is a flowchart which shows the interruption process (I_INTR) in 23rd Embodiment. It is a flowchart which shows the reel drive management (I_REEL_ADM) in 23rd Embodiment. It is a flowchart which shows the reel control data address set (C_RLDAT_SET) in 23rd Embodiment. It is a flow chart which shows reel drive control (I_REEL_CTL) in a 23rd embodiment. It is a flowchart following FIG. It is a figure which shows the acceleration/deceleration pulse output counter table (TBL_PULSE_UP) in 23rd Embodiment. It is a flowchart which shows the reel drive pulse update (I_PULSE_INC) in 23rd Embodiment. It is a figure which shows the reel drive pulse table (TBL_REEL_PULSE) in 23rd Embodiment. It is a flowchart which shows the deceleration start inspection (I_REDUCE_CHK) in 23rd Embodiment. It is a flowchart which shows the slip-in prevention output in 23rd Embodiment. It is a flow chart which shows confrontation production output control in a 23rd embodiment. It is a figure explaining volume setting in a 23rd embodiment. It is a flowchart which shows the volume setting of the administrator mode in 23rd Embodiment. It is a figure which shows the structure of the hardware of a main CPU. It is a figure which shows the structure of ROM and RWM of FIG. 164 in detail. (A) is a diagram showing A to F, H, L, and Q registers, and (B) is a diagram showing a structure of an F register. (A) is a figure which shows an example of an instruction, (B) is a figure explaining execution of an instruction. It is a figure which shows the kind (1) of instructions in 24th Embodiment. It is a figure which shows the kind (2) of a command in 24th Embodiment. It is a figure which shows the kind (3) of instructions in 24th Embodiment. It is a figure which shows the kind (4) of instructions in 24th Embodiment. It is a figure which shows the content of RWM which memorize|stores the data regarding an advantageous area (AT) in 24th Embodiment. It is a figure which shows the content (1) of RWM in 25th Embodiment. It is a figure which shows the content (2) of RWM in 25th Embodiment. It is a figure which shows the content (3) of RWM in 25th Embodiment. It is a figure which shows the definition data (1) in 25th Embodiment. It is a figure which shows the definition data (2) in 25th Embodiment. It is a figure which shows the definition data (3) in 25th Embodiment. It is a figure which shows the definition data (4) in 25th Embodiment. It is a figure which shows the outline of various tables used by 25th Embodiment. It is a diagram showing a first reel symbol array table (TBL_PICARG_1). It is a diagram showing a first reel symbol combination table (TBL_PICCMB_1) (1). It is a diagram showing a first reel symbol combination table (TBL_PICCMB_1) (2). It is a diagram showing a first reel symbol combination table (TBL_PICCMB_1) (3). It is a diagram showing a second reel symbol array table (TBL_PICARG_2). It is a diagram showing a second reel symbol combination table (TBL_PICCMB_2) (1). It is a diagram showing a second reel symbol combination table (TBL_PICCMB_2) (2). It is a diagram showing a second reel symbol combination table (TBL_PICCMB_2) (3). It is a diagram showing a third reel symbol array table (TBL_PICARG_3). It is a diagram showing a third reel symbol combination table (TBL_PICCMB_3) (1). It is a diagram showing a third reel symbol combination table (TBL_PICCMB_3) (2). It is a diagram showing a third reel symbol combination table (TBL_PICCMB_3) (3). It is a diagram showing a payout number table (TBL_WIN_CTL ). It is a flowchart showing a reel stop acceptance check (M_STOP_PIC). It is a flow chart which shows a stop design set (M_STOPPIC_SET) in Step S1024 of Drawing 194. It is a flowchart which shows the reel symbol data set (M_PICDAT_SET) in step S1033 of FIG. 195. It is a flowchart which shows table selection (R_TBL_SEL) in step S1043 of FIG. 196. It is a flowchart which shows 4-bit data acquisition (M_4BITDAT_GET) in step S1045 of FIG. 196. It is a flowchart which shows the number-of-bits count (M_BIT_COUNT) in step S1052 of FIG. 196. It is a flowchart which shows 1 line display determination (M_LINE_JUDGE). It is a flowchart which shows designation|designated data acquisition (M_SELDAT_SET) in step S1103 of FIG. It is a flow chart which shows RB operation management in a 25th embodiment. It is a figure which shows the structure of RWM53 in 26th Embodiment. (A) is a diagram showing a symbol control data table (TBL_PIC_DAT), and (B) is a diagram showing a reel symbol search table address offset table (TBL_PIC_SRCH). It is a diagram showing a first reel symbol search table (TBL_PICARG_1) (1). It is a diagram showing a first reel symbol search table (TBL_PICARG_1) (2). It is a diagram showing a first reel symbol search table (TBL_PICARG_1) (3). It is a diagram showing a first reel symbol search table (TBL_PICARG_1) (4). It is a diagram showing a first reel symbol search table (TBL_PICARG_1) (5). It is a diagram showing a second reel symbol search table (TBL_PICARG_2) (1). It is a diagram showing a second reel symbol search table (TBL_PICARG_2) (2). It is a diagram showing a second reel symbol search table (TBL_PICARG_2) (3). It is a diagram showing a second reel symbol search table (TBL_PICARG_2) (4). It is a diagram showing a second reel symbol search table (TBL_PICARG_2) (5). It is a diagram showing a third reel symbol search table (TBL_PICARG_3) (1). It is a diagram showing a third reel symbol search table (TBL_PICARG_3) (2). It is a diagram showing a third reel symbol search table (TBL_PICARG_3) (3). It is a diagram showing a third reel symbol search table (TBL_PICARG_3) (4). It is a diagram showing a third reel symbol search table (TBL_PICARG_3) (5). It is a figure which shows the payout number table (TBL_WIN_CTL) (1) in 26th Embodiment. It is a figure which shows the payout number table (TBL_WIN_CTL) (2) in 26th Embodiment. It is a flow chart which shows the main processing in a 26th embodiment. It is a flowchart which shows the start switch acceptance process in step S1133 of FIG. 222. FIG. 229 is a flowchart showing reel rotation start preparation processing in step S1142 of FIG. 223. FIG. It is a flowchart which shows the reel stop control in step S1135 of FIG. 222. It is a flow chart which shows a symbol arrangement address buffer set in Step S1165 of Drawing 225. It is a flowchart which shows the display determination process in step S1137 of FIG. 222. It is a figure which shows the example 1 of a symbol arrangement table in 27th Embodiment. It is a figure which shows the example 2 of a symbol arrangement table in 27th Embodiment. It is a figure which shows the display window and effective line, and RWM area|region in 28th Embodiment. It is a figure which shows the symbol arrangement in 28th Embodiment. It is a figure which shows the 1st reel symbol arrangement table (TBL_PICARG_1) in 28th Embodiment. It is a figure which shows the 2nd reel symbol arrangement table (TBL_PICARG_2) in 28th Embodiment. It is a figure which shows the 3rd reel symbol arrangement table (TBL_PICARG_3) in 28th Embodiment. It is a figure which shows the winning combination definition in 28th Embodiment. It is a flow chart which shows the main processing (M_MAIN) in a 29th embodiment. It is a figure which shows the content of RWM in 30th Embodiment. It is a flow chart which shows the main processing (M_MAIN) in a 30th embodiment. It is a flowchart which shows the reel stop acceptance check in step S1312 of FIG. 238. It is a flowchart which shows the input inspection in step S1313 of FIG. 238. It is a flowchart which shows the all reel stop check in step S1316 of FIG. 238. It is a flow chart which shows the main processing (M_MAIN) in a 31st embodiment. It is a figure which shows the content of RWM in 32nd Embodiment. It is a flowchart which shows the main processing (M_MAIN) in 32nd Embodiment. It is a flowchart which shows the reel stop acceptance check in step S1361 of FIG. 244. It is a flowchart which shows the out-of-step inspection preparation in step S1374 of FIG. 245. It is a flowchart which shows the out-of-step inspection in step S1382 of FIG. 246. It is a flowchart which shows the stop acceptance permission waiting in step S1387 of FIG. 246. It is a figure which shows the content of RWM in 33rd Embodiment. It is a figure which shows each signal input into the input port 0 in 33rd Embodiment. It is a flow chart which shows the main processing (M_MAIN) in a 33rd embodiment. It is a flowchart which shows the modification of the main process (M_MAIN) in 33rd Embodiment. It is a figure which shows the content (1) of RWM in 34th Embodiment. It is a figure which shows the content (2) of RWM in 34th Embodiment. (A) is a figure which shows a stop switch determination table (TBL_STPBTN_CHK), and (b) is a figure which shows a stop acceptance possible determination table. It is a flowchart which shows the main processing (M_MAIN) in 34th Embodiment. It is a flowchart which shows the reel stop acceptance check in step S1421 of FIG. It is a flow chart which shows a stop acceptance possibility inspection in Step S1432 of Drawing 257. It is a figure which shows a stop switch acceptance table (TBL_STOP_BTN). It is a flow chart which shows reel stop acceptance check in a 35th embodiment. It is a schematic diagram which shows the operation order of the stop switch 42 in a 36th embodiment, the stop order of the reel 31, the stop display of a symbol, and the output of the tempo sound. It is a schematic diagram which shows the operation order of the stop switch 42 in a 36th embodiment, the stop order of the reel 31, the stop display of a symbol, and the output of the tempo sound. It is a schematic diagram which shows the operation order of the stop switch 42 in a 36th embodiment, the stop order of the reel 31, the stop display of a symbol, and the output of the tempo sound. It is a flow chart which shows the main processing (M_MAIN) in a 36th embodiment.

In the present specification, the meanings of the terms are as follows.
"Bet" means betting a medal (game medium) for playing a game. In order to bet medals, an actual medal is carefully inserted through the medal insertion slot 47, or the bet switch 40 is operated to bet a credited (stored) medal.
On the other hand, “credit (also referred to as “store”)” means storing medals inside the slot machine 10 unlike “bet” described above. In this specification, the term "credit" is used in a meaning not including "bet".
Furthermore, “inserting” means betting or crediting a medal.
Further, the "specified number" refers to the number of bets that can start (execute) a game in the game. For example, in a game in which the specified number is "2" or "3", the game can be started with either the bet number "2" or "3" and the bet number "1" cannot be played.
For convenience of explanation, the "specified number" may be referred to as the "bet number".
On the other hand, the term "bet number" may refer to something other than the "specified number". For example, in the game of the prescribed number “2” or “3”, at the time when one medal is inserted (before the game starts), the bet number is “1” (the number bet at that time).

“Maintenance” means that the player inserts medals through the medal insertion slot 47 (described later).
The “care bet” means that the player bets a medal by taking care of the medal from the medal insertion slot 47.
The “care credit” means that the player credits a medal (adds credit) by taking care of the medal from the medal insertion slot 47.
The "bet medal" means a medal that has been bet.
The "stored medal" is a medal that has been credited (stored).

The “reserved bet” is a bet for playing a part or all of the credited medals within the range where the player can bet by operating the bet switch 40 (described later) in order to play the game. It means to do.
The “automatic bet” means that, when a replay is won, the number of medals previously bet in the game is automatically bet by the control processing of the slot machine 10.
Here, the symbol combination corresponding to the small winning combination is stopped and displayed (meaning that the winning combination is stopped on the activated line. The same applies hereinafter) is referred to as "small winning combination". On the other hand, in the "Rules regarding the approval of gaming machines and the verification of the model (hereinafter simply referred to as "rules")", when the symbol combination corresponding to the replay is stopped and displayed, it is the operation of the condition device relating to the replay. It is understood that it is not a "winning prize". However, in the present application (such as in the present specification), replay is also treated as one of the winning combinations (replay winning combination), and the symbol combination corresponding to the replay is sometimes displayed as "replay winning".
"Payment" means paying out bet medals and/or accumulated medals to the player. In the present embodiment, the settlement process is executed when the settlement switch 43 (described later) is operated.

“Paying out” means paying out medals to a player based on winning a winning combination, or paying out medals by the above settlement. When paying out the medals to the player based on the winning of the winning combination, they are stored as credits (adding the stored medals, in other words, updating the electronic data stored in the RWM 53 (described later)), and the payout. Both include paying out actual medals from the mouth (not shown). For the payout of medals, for example, "50" is set as the limit number of credits, and the medals for which the number of credits exceeds "50" are controlled to be actually paid out to the player.
The “payout” may be referred to as “grant”. Therefore, the “payout number” may be referred to as the “granting number”.

The "gaming medium" is a medal in this embodiment, but in the case of an enclosed (ECO) gaming machine, electronic information (electronic medal, electronic data) is used as the gaming medium. The "electronic information" means, for example, when money (banknotes) is put into a lending machine, it is converted into electronic information corresponding to the money, and a part or all of the electronic information is played on a gaming machine. It is possible to credit the game machine as a game medium for performing the game.
The "game medium" may also be referred to as the "game value".

Further, in the case where the game medium is electronic information, “payout of medals” means to credit (add) to the game medium credit device provided in the game machine. Therefore, “payout of medals” does not only mean that medals are actually paid out from the hopper 35 (described later), but the game medium credit device is credited with electronic information of the payout amount corresponding to the winning combination. The process of adding) is also included.

"N-1" game item, "N" game item, "N+1" game item, ... ("N" is an integer greater than or equal to 2), the current game is "N" game When it is an eye, the "N" game eye game is called a "current game". Also, the game of the "N-1" game is referred to as "previous game". Furthermore, the game of the "N+1" game is called a "next game".

In the present specification, a numerical value in which “(B)” is added to the end (especially 8 bits) of the numeral means a binary number. Similarly, a numerical value with "(H)" added to the end of the numeral means a hexadecimal number. Specifically, for example, a numerical value indicating "16" in decimal is expressed as "00010000 (B)" in binary and "10 (H)" in hexadecimal. Further, a numerical value that means a decimal number is expressed as "16(D)" as necessary.
However, when it is clear which is a binary number, a decimal number, or a hexadecimal number, the trailing symbols of “(B)”, “(D)”, and “(H)” may be omitted. ..

The “operation mode” of the stop switch 42 means the pressing order of the stop switch 42 and/or the operation timing (the timing of pressing the stop switch for stopping the target symbol on the activated line).
Further, the "advantageous operation mode" of the stop switch 42 has a payout or a large number of payouts in a game in which the operation result of the stop switch 42 produces an advantage/disadvantage in a game result (a symbol combination that stops on an effective line). An operation mode in which a symbol combination stops, an operation mode in which a symbol combination that shifts to an advantageous RT (promotion) stops, or an operation mode in which a symbol combination that does not shift (fall) to an unfavorable RT stops. The “advantageous operation mode” is also referred to as a correct operation mode and a correct pressing order.

The "game in which the game result is advantageous/disadvantageous depending on the operation mode of the stop switch 42" is, for example, a game (so-called "push order bell") that is won in any one of winning numbers "3" to "8" shown in FIG. Corresponding to the winning game). Although not shown in FIG. 58, for example, in a game in which a plurality of types of replays are won (duplicate replay wins. A game in which a so-called “push order replay” is won), RT is changed depending on the type of replay that is won. This is also the case.

The “instruction function” means a function of instructing the player how to operate the stop switch 42. In principle, the instruction function is a function of instructing the player about an advantageous operation mode of the stop switch 42.
In other words, "instruction function" refers to a device that facilitates winning.
It is to be noted that visually indicating the contents of the "instruction" is "display", and notifying the player of the contents of the instruction is "notification". Therefore, the “instruction function” is both a “display function” and a “notification function”.

Further, the notification of the operation mode of the stop switch 42 may not be limited to the notification of the most advantageous operation mode. Then, although the notification of the operation mode of the stop switch 42 which is the most advantageous may be the “operation of the instruction function”, the notification of any operation mode including the operation mode of the stop switch 42 which is the most advantageous is the “operation of the instruction function”. It may be "actuated".
For example, when the pushing order bells shown in the winning numbers “3” to “8” of FIG. 58B described later are the 6-choice pushing order, the payout at the time of pushing the pushing order bell is 10 in the example of FIG. 58 or It is assumed that the number is one, but instead of this, one, three, four, ten, or a dropout (non-win) is performed depending on the pressing order.
Here, notifying the pressing order for winning the winning combination of 10 is a notification of an advantageous operation mode of the stop switch 42, and of course corresponds to “operation of the instruction function”.
On the other hand, notifying the pressing order for winning the one-win, three-win, or four-win role may be referred to as "information of advantageous operation mode (operation of the instruction function)", and "advantageous operation mode" It is not necessary to say "notification of".

The pushing order for winning the four-card combination is not the most advantageous operation mode because the pushing order is for not winning the ten-card combination. However, since the payout number is "4" with respect to the bet number "3", and the difference number of the game is "+1", this is an operation mode for increasing the difference number, which is not necessarily a disadvantageous operation mode.
Similarly, the pushing order for winning the three-card combination is not the most advantageous operation mode because the pushing order is for not winning the ten-card combination. However, since the payout number is “3” with respect to the bet number “3”, and the difference number is maintained as it is (the difference number is not reduced), it is not necessarily a disadvantageous operation mode.

Further, similarly, the pushing order for winning one winning combination is the pushing order for not winning ten winning combinations, and thus is not the most advantageous operation mode. Further, the payout number is "1" with respect to the bet number "3", which is an operation mode for reducing the difference number. However, since it can be said that the operation mode does not lose the role, there is a possibility that it cannot be said to be an unfavorable operation mode.

In the present embodiment, in the operation of the instruction function when the push order bell is won, the operation mode (correct answer push order) in which the winning combination with the largest payout number is won is notified.
However, for example, when the difference counter value (described later) in the advantageous section approaches the upper limit value (“2400(D)”), but there is a margin in the number of remaining games in the advantageous section (the advantageous section clear counter value described later). It is conceivable that, when the push order bell is won, the push order in which, for example, three or four winning combinations are won as described above is notified, and control is performed so that the difference number counter value is maintained as it is.

Further, in the present embodiment, the operation of the instruction function is limited to one specified number. For example, it is assumed that the prescribed number of operating the indicating function is set to "3". In this case, in the game of the specified number "2" or "3" in AT, when the game is started with the bet number "3" and the push order bell is won, the instruction function can be operated. On the other hand, when the game is started with the bet number “2”, the instruction function cannot operate even when the push order bell is won.

The “game section” includes a “normal section (non-advantageous section)” and a “advantageous section”. Unit 5.9 had a "stand-by section" (a game section that won the advantageous section lottery but has not yet moved to the advantageous section). Is not provided. However, not limited to this, a game section other than the normal section and the advantageous section may be provided.
The “normal section” is a signal related to the instruction function, specifically, a push order instruction number and a winning and replay condition device number (information that can determine the correct push order) described later on a peripheral board (for example, the sub control board 80). ) Is a game section that is prohibited from being transmitted to, and that does not affect the performance related to the instruction function at all (does not execute the processing related to the instruction function). In other words, the normal section is a game section in which the operation mode cannot be notified. However, in addition to the lottery of the winning combination, it is possible to make a decision (lottery, etc.) as to whether or not to shift to the advantageous section.

Since the instruction function should not be operated in the normal section, the pressing order instruction information cannot be displayed on a predetermined display device (LED or the like) electrically connected to the main control board 60, and the instruction function is not possible. Since the signal related to (1) is not transmitted to the peripheral board, it is not possible to display (notify) an advantageous operation mode by the image display device 23 electrically connected to the sub control board 80.

On the other hand, the “advantageous section” is a game section having the performance related to the instruction function (the instruction function may be activated), and specifically, when operating the instruction function, the instruction is given on the main control board 60. Only when the push order instruction information is displayed so that the content (operation mode of the stop switch 42) can be identified, it indicates a game section in which a signal related to the instruction function can be transmitted to the sub control board 80. In other words, the advantageous section is a game section in which the instruction function can be operated (may operate the instruction function), that is, a game section in which the operation mode of the stop switch 42 can be displayed (may be displayed).
However, the sub control board 80 cannot output an effect contrary to the instruction content given by the main control board 60 or the received signal relating to the instruction function.

Further, the advantageous section may be a game in which the game result is advantageous/disadvantageous depending on the operation mode of the stop switch 42, or the instruction function may not be activated.
On the other hand, during the advantageous section, in a game in which a game result is advantageous/disadvantageous depending on the operation mode of the stop switch 42, the instruction mode may always be activated to display the operation mode of the stop switch 42.
AT (notification game state) is a game state in which the operation mode of the stop switch 42 is notified in the game in which the game result is advantageous/disadvantageous depending on the operation mode of the stop switch 42. Therefore, the AT is always in the advantageous section, and the AT is not executed in the non-advantageous section.

Further, the AT may always notify (at 100%) the operation mode of the stop switch 42 in a game in which the game result is advantageous/disadvantageous depending on the operation mode of the stop switch 42. It may be considered that the operation mode of the stop switch 42 is not notified even in a game in which the operation mode of the stop switch 42 gives an advantage/disadvantage to the game result, for example, in order to be within the range determined by the rule.
For example, in the case where the upper limit value of the difference counter is approached during AT, but the number of AT games still remains, the operation mode of the stop switch 42 is temporarily not notified from the viewpoint of extending the life of the AT. It is also possible to (do not activate the indicating function).

In addition, the relationship between the advantageous section and the AT can be variously set. For example, firstly, it is possible to set “advantageous section=AT”. In this case, winning the advantageous section is equivalent to winning the AT. Then, the AT is started from the first game of the advantageous section. Further, the AT ends with the end of the advantageous section.

Secondly, setting “AT≠advantageous section” can be mentioned.
In this case, the start (execution) condition of the AT is not satisfied only by shifting to the advantageous section, and on the condition that the AT is in the advantageous section, whether or not to execute the AT is determined by lottery or the like, and the AT is When it is decided to execute the AT, the AT is executed until the predetermined termination condition of the AT is satisfied. In addition, when it is non-AT at the time of shifting to the advantageous zone, for example, as the main game state, it is possible to set a normal zone, a sign, CZ (chance zone (a period in which it is easy to win an AT)), or the like.

When transitioning to the aura after the transition to the advantageous zone, the aura may be surely transitioned to the AT after the predetermined number of games of the aura has ended. Alternatively, at the time of transition to the advantageous zone or after the transition to the advantageous zone, it may be determined by lottery or the like whether to make the present sign or the sign of gasse. .. In addition, when it is determined that the warning sign is okay, the advantageous section may be maintained after the end of the warning sign, or the normal section may be shifted to.
Furthermore, when the AT termination condition is satisfied, both the AT and the advantageous section may be terminated. Alternatively, when the AT ends, but the end condition of the advantageous section is not satisfied, the advantageous section may be continued (non-AT and advantageous section). The same applies when AT is started at the same time as the advantageous section.

Further, it is possible to determine the number of games in the advantageous section when starting the advantageous section, and not to execute the lottery or the like regarding the advantageous section during the advantageous section.
Furthermore, when the advantageous zone is started, the initial number of games in the advantageous zone is determined, and during the advantageous zone, it is determined (lottery, etc.) whether or not to add (add) the number of games remaining in the advantageous zone. It can be mentioned.
Furthermore, when a predetermined ending condition is set for the advantageous section and the predetermined ending condition of the advantageous section is satisfied, even if there is a remaining number of games of the advantageous section (or a remaining number of games of AT), that time point Ending the advantageous section with.

Here, the "predetermined ending condition" of the advantageous section is that the difference number counter value described later exceeds "2400 (D)" or the advantageous section clear counter (the number of games in the advantageous section) described later is " 1500(D)” has been reached. When any of these conditions are satisfied, it is determined that the end condition of the advantageous section is satisfied, and the next game shifts to the normal section (non-advantageous section). In this case, even if the final game is AT, AT will end simultaneously with the end of the advantageous section.

In the advantageous section, an advantageous section display LED (also referred to as “section indicator”) 77 described later is turned on. The advantageous zone display LED 77 may be constantly turned on during the advantageous zone, but may be turned on when a predetermined lighting condition is satisfied after the transition to the advantageous zone.
Here, the "predetermined lighting condition" is, for example, when the instruction function is activated in a gaming state in which the advantageous section is provided and the section Sim payout rate exceeds "1". It should be noted that, after the advantageous section display LED 77 is once turned on, the lighting is maintained during the advantageous section.

Further, the "section Sim (simulation) payout rate" means that the symbol combination corresponding to the winning combination is always stopped and displayed (even when the winning combination of "PB≠1" is won, the symbol corresponding to the winning combination) It is assumed that the combination is stopped), and when there are multiple types of symbol combinations corresponding to the winning combination, the symbol combination that is most advantageous to the player (the highest payout bell that is the maximum payout when the push-order bell is won) It is the payout rate when it is assumed that the display is stopped. In the calculation of the section Sim payout rate, the payout (the number of payouts) due to the accessory operation (1BB operation or the like) is not included. In addition, when the bet number is “3” in the game won by the replay, the payout number is counted as “0”, and the bet number is calculated in the re-play based on the winning of the replay (the next game of the game won by the replay). It is calculated as “0”, the payout amount “x” (“x” is the payout amount in the game). Alternatively, the payout number of the game won in the replay and the bet number of the next game may not be counted.
Furthermore, the "gaming state in which the section Sim payout rate exceeds "1"" includes an RT and a main gaming state in which the section Sim payout rate exceeds "1".
Here, as the RT in which the section Sim payout rate exceeds “1”, for example, an RT in which the replay winning probability is set to be high is cited.
Assuming that a CZ (chance zone), an AT, a withdrawal section, etc. are usually provided as the main gaming state, AT is listed as the main gaming state in which the section Sim payout rate exceeds "1".

When ending the advantageous section, more specifically, in the final game of the advantageous section, for example, during the game end check process described later or the game start set processing in the next game of the last game of the advantageous section, the advantageous section display LED 77 is turned off. To do. When the condition for ending the advantageous period is satisfied, the advantageous period display LED 77 is turned off in the subsequent interrupt process by executing the initialization process of the advantageous period display LED flag described later.

Examples of the “processing relating to the advantageous section” include the following processing.
1) Advantageous zone (shift) lottery 2) Updating of advantageous zone clear counter (subtraction, clear)
3) Update the difference counter (calculation, clear)
4) Update of advantageous zone type flag 5) Control of advantageous zone display LED 77 (update of advantageous zone display LED flag)

Further, the “processing relating to the instruction function” includes, for example, the following processing.
1) Display of push order instruction information (operation of instruction function)
2) AT lottery 3) In the case of a game number management type AT (a specification that terminates AT when the remaining number of games reaches "0"), the AT game number counter is updated (subtraction, addition, clear)
4) In the case of the difference number management type AT (specification in which AT is terminated when the remaining difference number becomes "0"), the AT difference number counter is updated (subtraction, addition addition, clear)

In addition, according to the rules at the present time, both the process related to the advantageous section and the process related to the instruction function are determined to be executable in a prescribed number in a gaming state (RT) except for the following. Therefore, in the present embodiment, the specified number “3” can execute the process related to the advantageous section and the process related to the instruction function, and the specified number “2” cannot execute the process related to the advantageous section and the process related to the instruction function. And
However, during the advantageous period, it is necessary to update the advantageous period clear counter and the difference counter regardless of the specified number.

Further, in the present embodiment, when the winning combination lottery result is non-winning (for example, when the winning number “0” in FIG. 26 or FIG. 58 described later), in other words, in the game when the condition device is not operating, It is determined that the processing related to the advantageous section (lottery for shifting to the advantageous section) is not executed. However, the present invention is not limited to this, and the processing relating to the advantageous section may be executed even if the winning combination lottery result is a non-winning result.
On the other hand, in this embodiment, even if the winning combination lottery result is non-winning, if the non-winning probability is equal to or higher than a predetermined value (when the probability is not extremely low. For example, “1/17500” or more), the instruction function is involved. The process (AT lottery process) can be executed.

Furthermore, as a result of executing the advantageous section transition lottery (processing relating to the advantageous section), when the advantageous section transition lottery is won, it becomes the advantageous section from the next game. Therefore, the advantageous section transition lottery (processing related to the advantageous section) cannot be executed, and the correct winning order notification (processing related to the instruction function) cannot be executed in the game in which the advantageous section is won.
However, it is possible to perform the advantageous section transition lottery (processing relating to the advantageous section) and the AT lottery (processing relating to the instruction function) in one game. Furthermore, for example, when a specific hand lottery result is obtained, it may be determined as an advantageous section and AT (without executing the lottery).

The management information display LED (also referred to as a "role ratio monitor" or "ratio display") 74 is composed of four LEDs as shown in FIG. It is composed of an LED that indicates which of the items is a predetermined symbol or the like) and a two-digit ratio segment (an LED for displaying the calculated ratio).

The management information display LED 74 repeatedly displays the ratio of the following 5 items 1) to 5) every predetermined time.
1) Advantageous section ratio (cumulative) (7U.) or commanded accessory ratio (cumulative) (7P.) 2) Continuous character ratio (6000 games) (6y.)
3) Role ratio (6000 games) (7y.)
4) Percentage of consecutive role items (cumulative) (6A.)
5) Role ratio (cumulative) (7A.)

For example, in the case of displaying the character ratio (total), if the ratio is “50”%, the symbol “7A.” indicating the character ratio (total) is displayed in the identification segment and “50” is displayed. Display in the ratio segment.
Here, the "cumulative" refers to the sum of the numerical values that have continued to be counted, and in the present embodiment, counting is performed at least until the number of times of "175000" games has been reached. When the cumulative total is less than "175000" game times, for example, the ratio is displayed by blinking display, and when the cumulative number is "175000" game times or more, for example, the ratio is displayed by lighting display. The cumulative total continues to be added until it reaches a value (upper limit value) that can be stored in a predetermined address of the RWM 53, even after the number of times of playing “175000” or more.
Further, "6000 games" is the total number of times that one set is "400" game times and that 15 sets are totaled.

The "advantageous section ratio" refers to a ratio (ratio) of staying in the advantageous section with respect to all game sections (non-advantageous section + advantageous section). Specifically, for example, when the number of games in all the game sections is “1000” and the number of games in the advantageous section during that time is “700”, the advantageous section ratio is “70%”.
The "instruction-included accessory ratio" is a value obtained by dividing the total number of payouts when the accessory is activated and the number of payouts in the game in which the instruction function is activated by the total number of payouts. In a slot machine not equipped with accessory products, the “instructed accessory product ratio” is a value obtained by dividing the number of payouts in the game in which the instruction function is activated by the total number of payouts.
The total number of payouts when the accessory is activated and the total number of payouts in the game in which the instruction function is activated are counted by the instructed accessory counter.

Furthermore, "the number of payouts in the game in which the instruction function is operated" is based on the operation of the stop switch 42 in accordance with the pushing order displayed by the operation of the instruction function, for example, in FIG. When 10 bells of "3" to "8" are won, "10" is added to the indicated accessory counter.
On the other hand, in the game in which the instruction function is activated, the stop switch 42 is operated in a push order different from the displayed push order, so when the one-bell in the example of FIG. Is incremented by "1".
Similarly, in the game in which the instruction function is operated, when the winning combination is missed (when the winning combination is not winning) because the stop switch 42 is operated in a pressing order different from the displayed pressing order, the instruction-included accessory counter Is not added to. In other words, the count value in the previous game remains unchanged.

In the example of FIG. 26, which will be described later, when the common bell (winning number “3”) is won during AT, the instruction function is activated in the same manner as when the push order bell is won, and the winning number display LED 78 is pressed. There are a case where the normal instruction information (dummy) is displayed and a case where the instruction function is not operated. When the instruction function is activated when the common bell is won, the number of payouts in the game is added to the instruction-included accessory counter.

On the other hand, when the common bell is won and the instruction function is not activated, the number of payouts of the game is not added to the instruction-included accessory counter. However, the total payout number is added to the counter. In this case, the case where the sub-control board 80 notifies the correct pressing order by image or voice is also included.

The "continuous accessory ratio" refers to the ratio of the number of payouts during the operation of the first-class special accessory (RB) to the total number of payouts. Therefore, in the present embodiment, it refers to “the number of payouts during 1BB operation with respect to the total number of payouts”.
For example, when the total payout number in the number of times of playing "6000" is "2000", and the payout number at the time of operation of the "first class special accessory (RB)" is "500", the "continuous winning effect" The ratio (6000 games) is "25 (%)".

In addition, the "feature ratio" refers to the ratio of the number of payouts when the accessory is operated to the total number of payouts. Here, the "feature" is also referred to as a second-class special accessory (CB) and MB (2BB) in addition to the first-class special accessory described above. Continuous operation.), SB (single bonus) are included.
In addition, in the above-mentioned five items, in a gaming machine that does not have a function corresponding to the item, the ratio segment is displayed as "---".
For example, when "RB (first type special accessory)" is not provided, there is no continuous accessory ratio, so when the ratio display numbers "2" and "4" are displayed, the ratio segment is set to "--". Is displayed.
As described above, five types of ratios are displayed on the management information display LED 74, but as shown in FIGS. 29 and 30 described later, a test pattern is displayed at a predetermined timing when a predetermined condition is satisfied. To do.

In addition, the advantageous section ratio and the ratio of instructed accessory products are stipulated by rules to be 70% or less. Further, it is stated that the character role ratio should be 70% or less, and the continuous character ratio should be 60% or less.
Therefore, by looking at the information displayed on the management information display LED 74, it can be confirmed whether or not the information is within the legal range.

It should be noted that a gaming machine with a specification of an advantageous section ratio of 70% or less is called a "7U" type, and a gaming machine with a specification of an instruction-included accessory ratio of 70% or less is called a "7P" type. In a gaming machine provided with an advantageous section, it is either a "7U" type or a "7P" type. In the case of "7U" type, the advantageous section ratio (cumulative) is displayed on the management information display LED 74, and in the case of "7P" type, the commanded accessory ratio (cumulative) is displayed.
In the "7U" type, the ratio of the advantageous section to all the game sections must be "70"% or less, but in the "7P" type, the total number of payouts paid out by the operation of the instruction function and the accessory operation is total. It may be 70% or less of the number of payouts, and for example, all or most of the game section may be an advantageous section.

For example, when shifting to a non-advantageous section, it is set to win the advantageous section lottery with a probability of 100%, and to set to win the advantageous section lottery with a probability of almost 100% (for example, about 98%). Alternatively, it may be set to win the advantageous section lottery with a high probability (for example, 70%).
The "7U" type cannot perform the processing related to the instruction function (for example, AT lottery) by referring to the set value itself, but the "7P" type performs the processing related to the instruction function by referring to the set value itself. It is possible.
In a twelfth embodiment described later, most of the inside of the BB2 is in the advantageous section, and a lottery is performed to determine whether or not to execute the AT in this advantageous section.

The management information display LED 74 can also be applied to a pachinko gaming machine as a performance display monitor.
The management information display LED 74 (performance display monitor) in this case is composed of a two-digit identification segment and a two-digit ratio segment, as in the case of the slot machine (turning type gaming machine). Then, a real-time (measurement) base value (“base value” indicates how many safe balls are out of 100 out-balls) for each “60000” out-balls, and “60000”. The base values before, twice, and three times for each number are sequentially displayed. For example, the real-time base value identification segment is displayed as “bL.”, the previous base value identification segment is displayed as “b1.”, and the second previous base value identification segment is “b2.”. Is displayed, and the identification segment of the base value three times before is displayed as “b3.”.
As described above, the management information display LED 74 is applied not only to the slot machine of the gaming machine but also to the pachinko gaming machine.

An embodiment of the present invention will be described below with reference to the drawings and the like.
FIG. 1 is a block diagram showing an outline of control of a slot machine 10 which is an example of a gaming machine in the present embodiment. FIG. 1 is a block diagram common to the first to fifth embodiments.
A main control board 50 and a sub control board 80 are provided as typical control boards provided in the slot machine 10.
The main control board 50 has an input port 51 and an output port 52, and includes an RWM 53, a ROM 54, a main CPU 55, and the like (which does not mean to include only those shown in FIG. 1). The appearance of the main control board 50 and the fact that the main control board 50 is housed in the board case 56 will be described in the second embodiment (FIGS. 9 and 10).

In FIG. 1, the main control board 50 and peripheral devices for game progression including operation switches such as the bet switch 40 are electrically connected via an input port 51 or an output port 52. The input port 51 is a connection unit for inputting signals such as operation switches, and the output port 52 is a connection unit for transmitting signals to peripheral devices such as the motor 32.
In FIG. 1, a peripheral device for input is indicated by an arrow indicating a signal from the peripheral device toward the main control board 50, and a peripheral device for output is indicated by an arrow directed from the main control board 50 to the peripheral device. It is shown (similar to the sub-control board 80).

The RWM 53 is a storage medium capable of storing (updating) various data (variables) based on the progress of a game and the like.
The ROM 54 is a storage medium that stores programs and various data (for example, a data table) necessary for the progress of the game.
The main CPU 55 refers to a CPU (IC having an arithmetic function) provided on the main control board 50, and executes a program necessary for the progress of the game, arithmetic, etc. Specifically, a lottery for the winning combination and the reel 31. Drive control and payout at the time of winning.

An MPU including a RWM 53, a ROM 54, a main CPU 55, and a register is mounted on the main control board 50. It should be noted that the RWM 53 and the ROM 54 may be provided outside, in addition to the one mounted inside the MPU.
An MPU including the RWM 83, the ROM 84, and the sub CPU 85 is also mounted on the sub control board 80 described below. Note that the RWM 83 and the ROM 84 may be provided outside the MPU, instead of being mounted inside the MPU.

In FIG. 1, the medals inserted from the medal insertion slot 47 are sent inside the medal selector.
The movement of medals inserted from the medal insertion slot 47 within the medal selector will be described later with reference to FIG.
As shown in FIG. 1, a passage sensor 46, a blocker 45, and a loading sensor 44 (a pair of loading sensors 44a and 44b) are provided in the medal selector (but not limited to these). These are electrically connected to the main control board 50.
The medal inserted from the medal insertion slot 47 is first detected by the passage sensor 46.

Further, a blocker 45 is provided on the downstream side of the passage sensor 46. The blocker 45 is for permitting/disallowing the insertion of medals. When the insertion of medals is not permitted, the blocker 45 forms a medal passage for returning the medals inserted from the medal insertion opening 47 from the payout opening. To do. On the other hand, when the insertion of medals is permitted, a medal passage for guiding the medals inserted from the medal insertion opening 47 to the hopper 35 is formed. The blocker 45 is, for example, a switching member that closes an opening (an opening leading to the medal return port) formed in a part of the medal passage in the medal selector to form a medal passage for guiding the medals to the hopper 35 side. And an actuator or the like for driving the switching member.

Here, in the blocker 45, during the game (from the start of rotation of the reels 31 until all reels 31 are stopped and the payout corresponding to the winning combination is finished at the time of winning the winning combination), the insertion of medals is not permitted. To do. That is, the blocker 45 permits the insertion of medals at least when the game is not being played.

An insertion sensor (optical sensor) 44 is provided further downstream of the blocker 45 in the medal selector. In the present embodiment, the insertion sensor 44 is composed of a pair of insertion sensors 44a and 44b arranged at a predetermined distance, and the other insertion sensor 44b after a predetermined time has elapsed since the medal was detected by one insertion sensor 44a. Is configured to be detected by. Then, it is determined whether or not a correct medal has been inserted based on the timing at which the pair of insertion sensors 44 are turned on/off.

Further, as shown in FIG. 1, on the main control board 50, a bet switch 40 (40a or 40b), a start switch 41, a (left, middle, right) stop switch 42, and an operation switch operated by the player. The settlement switch 43 is electrically connected.
Here, the “operation switch (or simply, “switch”)” switches on/off of the electric signal based on the operation of the operation body by the player (operator) (receives a force from the outside). It refers to a device (including an electric circuit and/or an electric component) and does not limit the shape of the operating body operated by the player.

When the operation switch is in the off state, for example, light from the light emitting element continues to enter the light receiving element (when the light receiving element continues to detect light, the operation switch is in the off state). When a player or the like operates the operation switch (the operation body of the operation switch), the light from the light emitting element does not enter the light receiving element. When this state is detected, an electric signal indicating that the operation switch is turned on is transmitted to the main control board 50. Contrary to the above, when the operation switch is in the off state, the light from the light emitting element does not enter the light receiving element, and the light from the light emitting element enters the on state when entering the light receiving element. You may.

In the present embodiment, the operating body of the start switch 41 is in the shape of a lever (bar) (henceforth, also referred to as “start lever (switch) 41”), the bet switch 40, the stop switch 42, and the adjustment switch. The operating body 43 has a push button shape (for this reason, it is also referred to as a “bet button (switch) 40”, a “stop button (switch) 42”, and a “payment button (switch) 43”). In a fourth embodiment described later, the operating body of the stop switch 42 (the portion pushed by the player) is referred to as a "stop button 42a".

Further, although not shown in FIG. 1, an LED (light emitting means) is provided on the operation body of the operation switch and/or around or in the vicinity thereof. When the operation acceptance of the operation switch is permitted, for example, the LED or the like corresponding to the operation switch emits blue light, and when the operation acceptance of the operation switch is not permitted, for example, the operation switch The LED or the like emits red light to indicate to the player whether the operation switch is permitted or not.

Specifically, for example, when all the reels 31 are rotating and the operation of the stop switches 42 is acceptable, the LEDs of all the stop switches 42 are made to emit blue light to indicate that the operation is possible. Shown in. When one stop switch 42 is operated, the reel 31 corresponding to the operated stop switch 42 is stop-controlled. After that, the remaining stop switches 42 can be operated because the excitation state of the motor 32 corresponding to the reel 31 that is stop-controlled is ended and the detection sensor 42e of the stop switch 42 that has been operated (the fourth stop to be described later). Embodiment) is turned off. Therefore, during that time, the LEDs of all the stop switches 42 emit red light. Then, when the excitation state of the motor 32 corresponding to the operated stop switch 42 ends and the detection sensor 42e corresponding to the stop switch 42 is turned off, the LED of the already operated stop switch 42 is The red light is still emitted, but the LED of the stop switch 42 that has not been operated is made to emit blue light.

The bet switch 40 is an operation switch operated by the player when betting the stored medals for the current game. In this embodiment, a 1-bet switch 40a for inserting one medal and a 3-bet switch 40b for inserting three (maximum number, specified number) medals are provided.
Note that the present invention is not limited to this, and a bet switch for two-bed bet may be provided.

The specified number is determined in advance, for example, depending on whether or not the accessory is in operation/in operation. Specifically, it is set such that the accessory is not operated, the SB is operated, the 1BB is operated, 3 pieces are operated, the 2BB is operated, 2 pieces are operated, and the like. When the 1-bet switch 40a is operated twice, two medals can be inserted, and when it is operated three times, three medals can be inserted. When the specified number is 3, three medals can be inserted at a time by operating the 3 bet switch 40b. When the specified number is 2, the 3 bet switch 40b is operated. You can insert two medals at a time. If the 3-bet switch 40b is operated while the bet of less than the specified number is already bet, the bet processing is performed so that the bet number becomes three.

The start switch 41 is an operation switch operated by the player when starting the reels 31 (all left, middle, and right).
Furthermore, three stop switches 42 are provided corresponding to the three (left, middle, right) reels 31, and are operation switches operated by the player when stopping the corresponding reels 31.
Furthermore, the settlement switch 43 is an operation switch operated by the player when paying out (paying out) medals betted and/or stored (credited) inside the slot machine 10.

Further, as shown in FIG. 1, a display board 75 is electrically connected to the main control board 50. In addition, in practice, a relay board is provided between the main control board 50 and the display board 75, and the main control board 50 and the relay board, and the relay board and the display board 75 are connected. In FIG. 1, the illustration of the relay board is omitted. Thus, the main control board 50 and the display board 75 may be directly connected by a harness or the like, but another board may be interposed therebetween.
Furthermore, the control boards are not limited to being directly connected to each other by a harness or the like, but may be connected via another separate board (relay board or the like). For example, one or more other boards (relay boards, etc.) may be interposed between the main control board 50 and the sub control board 80.

On the display substrate 75, a credit number display LED 76 and an acquired number display LED 78 are mounted.
The credit number display LED 76 is an LED that displays the number of medals accumulated (credited) inside the slot machine 10, and is composed of two digits, an upper digit and a lower digit.

The winning number display LED 78 is an LED that displays the number of payouts (the number of players acquired) when winning a winning combination, and, like the credit number display LED 76, includes two digits, an upper digit and a lower digit. ..
The acquired number display LED 78 may be controlled to be turned off when there are no medals to be paid out. Alternatively, the upper digit may be turned off and only the lower digit may be displayed as "0".

The acquired number display LED 78 normally displays the acquired number, but functions as an LED that displays the content (type) of the error when an error occurs.
Furthermore, the acquired number display LED 78 functions as an LED that displays push order instruction information (notifies an advantageous push order) in a game in which the push order is notified during AT. Therefore, the acquired number display LED 78 in the present embodiment is an LED that also serves to display the acquired number, error content, and push order instruction information. However, the present invention is not limited to this, and it goes without saying that a dedicated LED or the like for displaying the pushing order instruction information may be provided.
In addition, during the AT, the notification of the advantageous pressing order is also executed by the image display device 23 connected to the sub control board 80.

In FIG. 1, the main control board 50 is electrically connected to a motor (stepping motor in this embodiment) 32 of the symbol display device.
The symbol display device includes reels (three in the present embodiment) 31 for displaying symbols, a motor 32 for driving each reel 31, and a reel sensor 33 for detecting the position of the reel 31.

The motor 32 serves as a drive unit for rotating the reel 31, is connected to the center of rotation of each reel 31, and is controlled by a reel control unit 65 described later. Here, the reel 31 includes a left reel 31, a middle reel 31, and a right reel 31, and a stop switch 42 operated when stopping the left reel 31 is a left stop switch 42, and when the middle reel 31 is stopped. The stop switch 42 operated is the middle stop switch 42, and the stop switch 42 operated when stopping the right reel 31 is the right stop switch 42.

The reel 31 has a ring shape, and a reel tape having a plurality of types of symbols (symbols forming a symbol combination corresponding to a winning combination) printed thereon is attached to the outer peripheral surface thereof.
Further, each reel 31 is provided with one (or two or more) indexes. The index is provided in a convex shape, for example, on the circumferential side surface of the reel 31, and is used when detecting whether the reel 31 has passed a predetermined position, whether it has rotated once, or the like. Then, each index is detected by the reel sensor 33. The signal from the reel sensor 33 is electrically connected to the main control board 50. When the index detects (cuts) the reel sensor 33, the input signal is input to the main control board 50, and it is detected that the reel 31 has passed a predetermined position.

Further, the symbol on the reference position at the moment when the reel sensor 33 detects the index of the reel 31 is stored in the ROM 54 in advance. Thereby, the symbol on the reference position at the moment when the index is detected can be detected. Further, from the moment when the reel sensor 33 detects the index of the reel 31, how many pulses the (stepping) motor 32 is driven to stop the number of symbols ahead from the symbol on the reference position on the effective line. It becomes possible to identify whether or not it is possible.

Further, a medal payout device is electrically connected to the main control board 50. The medal payout device is a hopper 35 for accumulating medals, a hopper motor 36 that is driven when paying out medals of the hopper 35 from a payout opening, and a payout for detecting medals paid out from the hopper motor 36. The sensor 37 is provided.

The medals that have been cared for through the medal slot 47 and that have been received (judged to be normal) are formed so as to be housed in the hopper 35.
In the present embodiment, the payout sensor (optical sensor) 37 includes a pair of payout sensors 37a and 37b arranged at a predetermined distance. Then, when the medal is paid out, a predetermined moving member (a movable piece 39a in FIG. 7, which will be described later) is moved by the medal. The payout sensors 37a and 37b are turned on/off by the movement of a predetermined moving member. Whether or not the medals have been correctly paid out is determined based on whether or not the payout sensors 37a and 37b are turned on/off within a predetermined time period.

For example, when the pair of payout sensors 37 are not detected to be turned on even though the hopper motor 36 is driven, it is determined that no medals have been paid out, and a hopper error (no medals) is detected.
On the other hand, when at least one of the payout sensors 37 keeps outputting the ON signal, it is detected that the medal clogging has occurred.
Details of these operations will be described later with reference to FIGS.

When the player starts the game, he or she inserts a credited medal in advance by operating the bet switch 40 (reservation bet) or care-inserts a medal from the medal insertion opening 47 (care bet). When the start switch 41 is operated with a specified number of medals of the game being betted, a signal generated at that time is input to the main control board 50. When this signal is received, the main control board 50 (specifically, a reel control means 65 to be described later) performs a lottery by the winning lottery means 61 and drives and controls all the motors 32 so that all the reels 31 are removed. Control to rotate. As the reel 31 is thus rotated by the motor 32, the symbols on the reel 31 are moved and displayed in the vertical direction in the display window at a predetermined speed.

Then, the player presses the stop switch 42 to stop the rotation of the reel 31 corresponding to the stop switch 42 (for example, the left reel 31 corresponding to the left stop switch 42). When the stop switch 42 is operated, the signal generated at that time is input to the main control board 50. When this signal is received, the main control board 50 (specifically, a reel control means 65 to be described later) drives and controls the motor 32 corresponding to the stop switch 42, and the lottery result of the combination lottery means 61 (internal lottery). (Result determined by the means), stop control of the reel 31 related to the motor 32 is performed.

Then, the game result of the current game is displayed by the symbol combination when all reels 31 are stopped. Furthermore, when the symbol combination corresponding to any of the winning combinations is stopped on the activated line (when the winning combination of the winning combination is achieved), the payout of medals corresponding to the winning combination is performed.

Next, a specific configuration of the main control board 50 will be described.
As shown in FIG. 1, the main CPU 55 of the main control board 50 is provided with the following role lottery means 61 and the like. The following respective means in the present embodiment are exemplifications, and are not limited to the means shown in the present embodiment.

The role lottery means 61 performs lottery (determination, selection) of winning numbers. Here, the "lottery of the winning number by the role lottery means 61" is the same as the "internal lottery" in the rules of the wind management law (rules regarding the approval of game machines and the verification of the model, etc., hereinafter simply referred to as "rules"), The result of the lottery by the part lottery means 61 is the same as the “result determined by the internal lottery” in the rule. Therefore, the role lottery means 61 is also referred to as "internal lottery means 61" in an expression conforming to the rules.
When the winning number is determined by the role lottery means 61, the prize and replay condition device number and the accessory condition device number are determined based on the winning number, and the prize and replay condition device operable in the game. Also, the accessory condition device will be determined. Therefore, the winning combination lottery means 61 is also referred to as a condition device number determining (lottery or selection) means, a winning combination determining (lottery or selection) means, or the like.

The role lottery means 61 is based on, for example, a random number generating means (hardware random number) for lottery, a random number extracting means for extracting a random number generated by the random number generating means, and a random number value extracted by the random number extracting means. A winning number determining means for determining a winning number is provided.

The random number generating means generates a random number in a predetermined area (for example, "0" to "65535" in decimal). The random number is, for example, a counter that counts 1 at 200 n (nano) sec and continues counting as 1 cycle in the range of “0” to “65535”. While the slot machine 10 is powered on, the random number is Keep counting.

The random number extracting means extracts the random number generated by the random number generating means at a predetermined time, in the present embodiment, when the player operates (turns on) the start switch 41. The determination unit determines the winning number corresponding to the area to which the random number value belongs by collating the random number value extracted by the random number extraction unit with a lottery table described later.

The winning flag control means 62 controls ON/OFF of the winning flag corresponding to each winning combination, based on the lottery result by the winning combination lottery means 61. In the present embodiment, a winning flag is provided for each winning combination for all winning combinations. When any of the winning combination is won in the lottery by the winning combination lottery means 61, the winning flag of the winning combination is turned on (the winning flag is set). The winning of the winning combination may be a single winning combination (single winning) or a multiple winning combination (double winning).

The push order instruction number selection means 63 selects a push order instruction number (a number corresponding to the correct answer push order) based on the lottery result (push order bell or at the time of push order replay win) of the winning number by the role lottery means 61 ( Decision).
The “push order” of the push order instruction number selected here means a push order (correct answer push order) advantageous to the player. For example, when the push order bell is elected, it refers to the push order in which the higher bell is awarded (correct answer push order). In the case of replay overlapping wins, it refers to a push order in which the RT is promoted to an advantageous RT or a push order in which the RT is not lowered.

In the present embodiment, each winning number is provided with a unique push order instruction number.
When the push order bell or the push order replay is won during AT, the main control board 50 causes the above-mentioned acquisition number display LED 78 to indicate the push order instruction information corresponding to the push order instruction number, specifically, " =*” (“*”=1, 2,...) Is displayed. In this way, the function of displaying the push order instruction information when the condition device having an advantageous push order is activated is also referred to as an instruction function.
In addition, when the push order bell or the push order replay is won during AT, the main control board 50 is a sub control board at the start of the game (after the start switch 41 is operated and the winning number is determined). The command corresponding to the pressing order instruction number is transmitted to 80.
When the sub-control board 80 receives the command, the correct-pressing order is displayed on the image display device 23 as an image.

The pushing order instruction number selected by the main control board 50 can be transmitted to the sub control board 80 only during the advantageous period (AT). Therefore, even if the pushing order instruction number is selected by the pushing order instruction number selecting unit 63 in the normal section, the pushing order instruction number is not transmitted to the sub-control board 80. In addition, in the normal section, it is not necessary to select the push order instruction number.

The effect group number selection means 64 is for selecting an effect group number corresponding to the winning number, which number is to be transmitted to the sub control board 80.
Here, the effect group number corresponding to the winning number is predetermined. Then, when the winning number is determined by operating the start switch 41, the effect group number selecting means 64 selects the effect group number corresponding to the winning number of the game, and the main control board 50 causes the selected effect group. The number is transmitted to the sub control board 80. The sub control board 80 outputs an effect related to the winning combination based on the received effect group number. The effect group number is different from the above-mentioned push order instruction number, is selected for each game, and is transmitted from the main control board 50 to the sub control board 80.

Further, the main control board 50 does not transmit the winning number of the game to the sub control board 80. Therefore, the sub control board 80 cannot know the winning number of the game. However, since the sub-control board 80 receives each game and effect group number, it is possible to output effects based on the received effect group number. However, even when the push order bell or the push order replay is won, since the correct answer push order cannot be determined from the effect group number, the sub control board 80 does not notify the correct answer order based on the effect group number. .. On the other hand, during AT, when the push order bell or the push order replay is won, the push order instruction number is transmitted from the main control board 50 to the sub control board 80. As a result, the sub-control board 80 can inform the correct pressing order based on the received pressing order instruction number.

The reel control means 65 controls to start the rotation of all (three) reels 31 when a rotation start command of the reels 31 is received, particularly when the operation of the start switch 41 is detected in this embodiment. ..
Further, after the winning number is determined by the role lottery means 61, the reel control means 65 refers to ON/OFF of the winning flag in this game, and refers to the stop position determination table corresponding to ON/OFF of the winning flag. When the stop switch 42 is operated, the stop position of the reel 31 corresponding to the stop switch 42 is determined based on the timing when the operation of the stop switch 42 is detected. The drive is controlled so that the reel 31 is stopped at the determined position.

For example, in the game in which at least one winning flag is turned on, the reel control means 65 activates the symbol combination corresponding to the winning combination (the winning flag is turned on) within the range of the stop control of the reel 31. The reel 31 is stopped and controlled so that it can be stopped on the line, and the reel 31 is stopped and controlled so that symbol combinations corresponding to winning combinations (winning flags for which the winning flag is off) are not stopped on the activated line.

Here, "within the stop control range of the reel 31" means the time from the moment the stop switch 42 is operated until the reel 31 actually stops or the amount of rotation of the reel 31 (the number of moving symbols (frames)). Means within the range.
In this embodiment, the reel 31 is rotated at a speed of about 80 rotations per minute at a constant speed.
Then, when the stop switch 42 is operated, the time from the moment the stop switch 42 is operated until the reel 31 is stopped is within 190 ms except for the predetermined reel 31 (for example, the middle reel 31) that is in the MB operation. Is set to. As a result, in the present embodiment, the maximum number of symbols to be moved from the symbol at the moment the stop switch 42 is operated to when the reel 31 is stopped is set to 4 symbols, except for the predetermined reel 31 during MB operation.

On the other hand, for the predetermined reel 31 during MB operation, the time from the moment the stop switch 42 is operated until the reel 31 is stopped is set within 75 ms. Thereby, for the predetermined reel 31 during MB operation, the maximum number of symbols to be moved from the symbol at the moment the stop switch 42 is operated until the reel 31 stops is set to one symbol.

Then, at the moment when the operation of the stop switch 42 is detected, when any of the symbols within the stop control range of the reel 31 is a symbol to be stopped on a predetermined effective line, when the stop switch 42 is operated In addition, the design is controlled so as to stop at a predetermined effective line.
That is, when the reel 31 is immediately stopped at the moment when the stop switch 42 is operated, when the symbol of the winning combination corresponding to the winning number does not stop on a predetermined effective line, the reel 31 is stopped before the reel 31 is stopped. By controlling the rotational movement of the reel 31 within the range of the stop control, the symbol of the winning combination corresponding to the winning number is controlled to be stopped on a predetermined effective line as much as possible (pull-in stop control).

On the contrary, when the reel 31 is stopped immediately when the stop switch 42 is operated, when the symbol combination of the winning combination not corresponding to the winning number stops on the activated line, when the reel 31 stops, the reel 31 By controlling the reel 31 to rotate and move within the range of the stop control, the symbol combination of the winning combination that does not correspond to the winning number is controlled so as not to stop on the activated line (kicking stop control).
Further, in a game in which a plurality of winning combinations are won (for example, when the push order bell is selected), the priority order of winning combinations is predetermined according to the pressing order of the stop switch 42 and the operation timing of the stop switch 42. Therefore, according to the predetermined priority order, the drawing stop control of the symbol relating to the highest priority combination is performed.

The winning determination means 66 is for determining whether or not the symbol combination of the reel 31 stopped on the activated line is a symbol combination corresponding to any winning combination when the reel 31 is stopped.
Here, the winning determination means 66 does not actually detect whether or not the symbol combination corresponding to the winning combination has stopped on the activated line. Specifically, from the condition device operated in the game, the pressing order of the stop switch 42 and/or the operation timing of the stop switch 42, a symbol combination to be stopped in the effective line before the reel 31 is actually stopped is previously set. It is determined or the symbol combination stopped on the activated line after the reel 31 is stopped is determined in advance.

The control command transmitting means 71 transmits to the sub control board 80 information (control command) necessary for the performance output by the sub control board 80.
The control commands include, for example, information when the bet switch 40 is operated, information when the start switch 41 is operated, and a push order instruction number (only when the winning number in AT and the correct answer pushing order is won). , Production group number, RT (game state) information, information when the stop switch 42 is operated, information of winning combinations, and the like.

In FIG. 1, a sub-control board 80 controls selection and output of effects (information) during a game and a game standby.
Here, the main control board 50 and the sub control board 80 are electrically connected to each other, and the main control board 50 (control command transmitting means 71) is directed to the sub control board 80 in one direction by parallel communication. Sends information (control command) necessary for output.
The main control board 50 and the sub control board 80 are not limited to being electrically connected, but may be a connection using an optical communication unit. Furthermore, both the electrical connection and the optical communication connection are not limited to parallel communication, but may be serial communication, or serial communication and parallel communication may be used together.

Like the main control board 50, the sub control board 80 includes an input port 81, an output port 82, a RWM 83, a ROM 84, a sub CPU 85, and the like.
Peripheral devices for production such as the following production lamp 21 as shown in FIG. 1 are electrically connected to the sub-control board 80 via an input port 81 or an output port 82. However, the peripheral devices for performance are not limited to these.
The RWM 83 is a storage medium capable of temporarily storing the data and the like taken in when the sub CPU 85 controls the effect.
Further, the ROM 84 is a storage medium that stores, as the effect data, a program for performing a lottery related to the effect, various data, and the like.

The effect lamp 21 is made of, for example, an LED or the like, and lights up in a predetermined pattern when a predetermined condition is satisfied. The effect lamp 21 is arranged on the inner peripheral side of each reel 31, and is a back lamp for illuminating the symbols displayed on the reel 31 (three symbols that are vertically continuous from the display window) from the rear of the reel 31. A fluorescent lamp that illuminates the symbols on the reel 31 from the upper part, a frame lamp that is arranged in front of the front door of the slot machine 10 and blinks when winning a winning combination, and the like are included.

Further, the speaker 22 outputs a predetermined sound when a predetermined condition is satisfied in order to perform various effects during the game.
Furthermore, the image display device 23 is composed of a liquid crystal display, an organic EL display, a dot display, etc., and various effect images during the game (correct answer pressing order, effects corresponding to condition devices operating in the game, etc.). In addition, game information (the number of games played and the number of games acquired during the advantageous period (AT), etc.) is displayed.

FIG. 2 is a diagram showing a state in which the medal M inserted from the medal insertion slot 47 passes through the insertion sensors 44a and 44b, and is a schematic view seen from the front. In FIG. 2, the inside of the medal selector is visible. Further, the medal M shows M1 to M4 according to the position thereof. The position of M1 indicates a state in which the medal M is placed on the medal placement portion 47b of the medal insertion slot 47 (state before being released). That is, at the position of M1, the lowest point of the outer peripheral edge of the medal M and the upper surface of the medal placing portion 47b are in contact with each other when viewed from the front.
In addition, in FIG. 2 (and FIG. 4 to be described later), it is assumed that the entire substantially square portions displayed as the closing sensors 44a and 44b are the light receiving/emitting ranges (eyes of the sensors) of the closing sensors 44a and 44b (respectively). It is not the housing of the input sensors 44a and 44b.).

The position of M2 indicates the position at the moment when the medal M cannot be seen from the front. That is, at the position of M2, the uppermost point of the outer peripheral edge of the medal M and the upper surface of the medal holder 47b overlap each other. For example, assuming that the player releases the medal M when the medal M is at the position M1, the medal M falls from the position M1. Therefore, at the position of M2, the player is released from the player's hand and dropped (moved) to the downstream side.
The "upstream side" means the medal insertion slot 47 side, and the "downstream side" means the insertion sensor 44b side (the hopper 35 side). In terms of the position of the medal M, M1→M2→M3→M4 from the upstream side toward the downstream side.

In the example of FIG. 2, the passage sensor 46 is arranged so that the passage sensor 46 detects the medal M when the medal M is located at M2.
Furthermore, the position of M3 indicates the position at the moment (on) when the medal M is detected by the insertion sensor 44a. The position of M4 indicates the position at the moment (OFF) when the medal M is no longer detected by the insertion sensor 44b.

The medal insertion slot 47 is a portion for inserting the medal M into the slot machine 10 (medal selector) when the player bets or credits the medal M as a game medium. The medal insertion slot 47 includes a medal guard section 47a and a medal placement section 47b. The medal holder 47b has a substantially curved surface (having a curvature slightly larger than the peripheral edge of the medal M) extending in the direction perpendicular to the plane of the drawing so that a plurality of medals M (up to about 10) can be placed at the same time. Curved surface).

The substantially curved surface of the medal rest portion 47b and the surface of the medal guard portion 47a in contact with the medal M (the surface visible in FIG. 2) are formed so as to intersect substantially vertically.
Further, although not shown in FIG. 2, there is an opening through which one medal M can flow down at a portion where the medal placing portion 47b and the medal guard portion 47a intersect. The medal M does not drop from the opening when the two medals M are stacked, but the medal M flows down from the opening when the medal M has a thickness of one. Therefore, for example, the player places a plurality of stacked medals M on the medal holder 47b and presses the plurality of medals M toward the medal guard part 47a while strengthening the pressing force. By weakening it, it is possible to drop the medals M placed on the medal holder 47b one by one into the medal selector through the opening.

When the medal M is thrown in from the medal slot 47 (released downward), the medal M flows down the passage in the medal selector. A passage sensor 46, a loading sensor 44a, and a loading sensor 44b are provided in the medal selector from the upstream side. Further, the blocker 45 described above is provided between the passage sensor 46 and the input sensor 44a (below the input sensor 44a in FIG. 2).

When the medal M enters the medal selector, it is first detected by the passage sensor 46. The passage sensor 46 is a sensor provided for determining whether or not there is a clogging of a medal or a goto action, and detects the medal M for a predetermined time (predetermined) from the time when the passage sensor 46 detects the medal M, Furthermore, when the medal M is no longer detected after the lapse of a predetermined time, it is determined to be normal. On the other hand, if the passage sensor 46 continues to detect the medals M even after a lapse of a predetermined time after detecting the medals, it is determined to be a medal retention error. Further, when the passage sensor 46 detects the medal M and then stops detecting the medal M before a predetermined time elapses, it is determined that the medal M is illegally passed.

When the medal M flows down in the medal passage, it reaches the position of the blocker 45. The blocker 45 is arranged on the lower surface side in the medal passage. The blocker 45 forms a medal flow path so that the medal M can be detected by the insertion sensors 44a and 44b when the blocker 45 is in the ON state (the output port of the output port 52 related to the blocker 45 is ON). In other words, it has a role of sending the medal M, which has moved from the upstream side, to the insertion sensors 44a and 44b without sending it out of the medal passage.

On the other hand, when the output port 52 is in the off state (the output port of the blocker 45 is off), the blocker 45 must move so as to be displaced in the direction perpendicular to the plane of the drawing in FIG. Thus, an opening (pitfall) is formed in the medal passage. As a result, when the blocker 45 is in the off state, the medal M falls from this opening and is sent out of the medal passage (M5 in FIG. 2) immediately before reaching the M3. The medal M dropped from this opening is returned to the medal return port (not shown) without being detected by the insertion sensor 44a.

For example, when the specified number of games is already bet and the number of credits reaches the upper limit, it is not possible to bet and credit any more medals, so the blocker 45 is controlled to the off state. As a result, even if the medal M is inserted from the medal insertion opening 47 in that state, it drops from the opening and is returned to the medal return opening.
On the other hand, when the blocker 45 is in the ON state, since the opening is blocked by the blocker 45, the medal M flowing down in the medal passage passes over the blocker 45 and the insertion sensors 44a and 44b. Can be moved to the side.

In this embodiment, the blocker 45 is arranged as shown in FIG. 2, but the arrangement is not limited to this. The passage sensor 46 can detect the medal M regardless of the on/off state of the blocker 45, and can guide the medal M to the insertion sensors 44a and 44b when the blocker 45 is on, and It is sufficient that the medal M can be sent to the medal return port without being detected by the insertion sensors 44a and 44b when the blocker 45 is off. In other words, the blocker 45 may be located between the passage sensor 46 and the input sensor 44a.

Further, the passage sensor 46 only needs to be located on the upstream side of the blocker 45, and is arranged at a position where the medal M inserted from the medal insertion slot 47 can be detected even when the blocker 45 is in the off state. Just do it. Further, in FIG. 2, the passage sensor 46 is arranged so as to be able to detect the medal M when the medal M is located at M2. However, the present invention is not limited to this, and the passage sensor 46 is further downstream than the position of the medal M. It is also possible to arrange the passage sensor 46 so as to detect the medal M when it moves to.

The insertion sensors 44a and 44b are sensors for detecting the medal M that has passed through the blocker 45, and these two sensors are installed at a predetermined distance. First, when the medal M reaches the position of M3, the insertion sensor 44a on the upstream side can detect the medal M (it turns from off to on). When the medal M further flows down, the insertion sensor 44b next detects the medal M (turns from off to on). By determining the on/off timing of these two insertion sensors 44a and 44b, it is determined whether or not the inserted medal M is normal. When the medal M reaches the position of M4, it is no longer detected by the insertion sensors 44a and 44b. The medal M that has passed through the insertion sensors 44a and 44b is sent to the hopper 35.

In FIG. 2, the medal selector is designed as follows.
First, the medal M is at the position of M2, that is, the position at which the medal M is at the position of M4, that is, the position at which the medal M is not detected by the insertion sensor 44b from the moment when the medal M becomes invisible when the medal selector is viewed from the front. The time until reaching (the moving locus is shown by the dotted line in FIG. 2) is set to time T2. It is a value when the medal M is located at M1 and the hand is released from the medal M (at the initial velocity "0") and released downward. Therefore, the speed when the medal M is located at M2 exceeds “0”.

Further, the acceleration of the medal M increases as it moves further downward from the position of M2. On the other hand, in FIG. 2, an impact member (not shown in FIG. 2) is provided at a portion where the medal passage is bent from the vertical direction to the horizontal direction. When the medal M comes into contact with the impact member, the speed of the medal M is decelerated and moves toward the insertion sensors 44a and 44b.
The time from the moment when the medal M is located at M3 (the moment when it is detected by the insertion sensor 44a) to the moment when it is located at M4 (the moment when it is no longer detected by the insertion sensor 44b) is set to time T3. ..

<First Embodiment (A)>
FIG. 3 is a diagram showing a time chart for explaining the first embodiment (A) of the present embodiment.
FIG. 3 shows voltage levels when the power of the slot machine 10 is turned off (for example, when the power switch 11 is turned off or when a power failure occurs).
In FIG. 3, the voltage when the power supply is normally turned on is the supply level V0. In the state of the supply level V0, the slot machine 10 operates normally.

FIG. 3 shows an example in which the power supply is cut off at time S11 (the event in which the power supply is cut off). In this embodiment, when the power failure occurs, the voltage drops to the power failure detection level V1 at time T0.
The time T0 from the occurrence of power failure (time S11; supply level V0) to the detection of power failure (time S12; power failure detection level V1) is at least 20 interrupts (1 interrupt time 2.235 ms×20). Interrupt = 44.7 ms) or more.
On the main control board 50, a voltage monitoring device (not shown) (power interruption detection circuit) is provided. When the power supply voltage becomes equal to or lower than the power cutoff detection level V1 which is a predetermined value, the power cutoff detection signal is input to a predetermined bit in the input port 51, and the power is detected by detecting whether or not the signal is input. Detect disconnection.

When the voltage further decreases from the power-off detection level V1 and falls below the drive voltage limit V2 of the main CPU 55, the main CPU 55 cannot be driven (the operation of the main CPU 55 cannot be guaranteed).
In the example of FIG. 3, the voltage level reaches the drive voltage limit V2 of the main CPU 55 at time S13, and then decreases to Low. Since the main control board 50 cannot execute the power-off process when the voltage becomes lower than the drive voltage limit V2, when the power-off occurs at time S11, the power-off process can be completed at least by time S13. Is set to.

The detection of power failure is executed in the interrupt processing executed every 2.235 ms, but when the power failure is detected for two consecutive interrupts, the power interruption processing is executed in the next interrupt processing. Therefore, in FIG. 3, time S12 is the timing at which it is determined that the voltage is at the power-off detection level V1 or less by the interrupt processing for two consecutive times and the power-off is detected. Then, the power interruption process is executed in the next interrupt process.
In the interrupt processing, the following processing is executed. First, it is determined whether or not the power failure is detected, and when the power failure is detected, the process proceeds to the power-off process (without proceeding to the normal interrupt process). In the power-off process, first, the output port 52 is turned off. The blocker 45 is turned off by the process of turning off the output port 52. Further, a stack pointer saving process, a power-off process completed flag (a flag for determining whether or not a normal power-off is performed), a checksum execution process of the RWM 53, a write prohibition process of the RWM 53, and the like are performed. After the sequential execution, the reset waiting state (loop processing state) is entered. This reset waiting state is a state in which no processing is performed by design.
Therefore, as shown in FIG. 3, the power-off process is executed and the blocker 45 is turned off in the interrupt process following the interrupt process (time S12) when the power-off is detected.
The power-off process is not limited to being executed in the interrupt process subsequent to the interrupt process in which the power-off is detected, and the power-off process may be executed in the interrupt process in which the power-off is detected. In this case, "T1=S12-S11".

On the other hand, FIG. 3 also shows the medal positions (M2, M4) after the medals have been inserted. In FIG. 2, it is assumed that the player releases the medal M while the medal M is at the position M1. In this case, the medal M drops at the initial velocity "0". As a result, the medal M is released in the medal selector. In FIG. 3, the time S11 when the power is cut off and the time when the medal M reaches the position of M2 are matched.

As shown in FIG. 2, the time from the moment when the medal M is located at M2 to the moment when it is located at M4 is T2, but similarly in FIG. 3, the time T2 elapses from the moment when the medal M is located at M2. Later, it is assumed that the medal M is located at M4.
In this case, the present embodiment is designed so as to satisfy the relationship of “T2>T1”.

Therefore, if the power is cut off at the moment when the medal M is located at M2, the power off process is executed before the medal M reaches M4, and the insertion sensor 44b does not detect the medal M. Therefore, when the power is cut off at the moment when the medal M is located at M2, the medal M is sent to the medal return port (lower plate) without being detected by the insertion sensor 44b. Therefore, the medal M does not normally pass through the insertion sensors 44a and 44b. Therefore, the medal M will be swallowed, but after the power is cut off (after time S11), the process of adding "1" to the medal M (adding "1" to the bet or the credit) is executed. Not done. As a result, it is possible to eliminate the possibility that the bet or credit process is executed after the power is cut off.

For example, in the case where the power is cut off at the moment when the medal M is located at M2, when the time T1 has elapsed (during the power off processing), when the medal M is located immediately before M4 in FIG. (After passing the position of M3), the medal M is detected by the insertion sensor 44a, but is not detected by the insertion sensor 44b and the power is turned off.
In the case where the power is cut off at the moment when the medal M is located at M2, the medal M is located upstream of the position of M3 in FIG. 2 when the time T1 elapses (during power off processing). At this time, the medal M is turned off without being detected by either the insertion sensor 44a or the insertion sensor 44b.

Further, in FIG. 2, the time from the moment when the medal M is located at M2 to the moment when it is located at M3 is defined as time T2′.
In this case, it is preferable to design so as to satisfy the relationship of “T2′>T1”.
In the case of designing in the above relationship, if the power is cut off at the moment when the medal M is located at M2, when the medal M reaches M3, the power cut-off process is executed to turn off the blocker 45. ing. Therefore, the medal M is sent out of the medal passage without being detected by the insertion sensor 44a and is sent to the medal return port.

Here, the difference between the conventional technique and the first embodiment (A) will be described.
Conventionally, when a power failure occurs at the moment the medal M is located at M2, the medal M has already passed the position of the insertion sensor 44b when the power failure is detected and the blocker 45 is turned off. Therefore, the medal “1” addition process (bet process or credit process) is executed after the power is cut off. However, it is not preferable to execute the medal addition process after the power is cut off. This is because after the power is cut off, all the processing related to the progress of the game should be stopped immediately.
Therefore, with the configuration of the first embodiment (A), even if the player inserts the medal M from the medal insertion slot 47 and the power is cut off at the moment when the medal M is located at M2 (immediately after the insertion). Since the medal “1” addition process is not executed, the function of the slot machine 10 can be enhanced.

<First embodiment (B)>
The first embodiment (B) defines the relationship between the closing sensors 44a and 44b and the power-off.
FIG. 4 is a front view showing a process from when the medal M is detected by the insertion sensor 44a to when it is no longer detected by the insertion sensor 44b. In FIG. 4, the arrow direction indicates the traveling (flowing) direction of the medal M.
FIG. 4A shows a view at the moment when the medal M is detected by the insertion sensor 44a. At this time, the closing sensor 44a is at the moment when it is turned on from off, and the closing sensor 44b remains off. Note that this position corresponds to M3 in FIG.

Next, when the medal M advances to the left side in FIG. 4 and enters the state shown in FIG. 4B, the insertion sensor 44a remains in the state of detecting the medal M, and the insertion sensor 44b detects the medal M. Like Therefore, in FIG. 4B, the closing sensor 44a is on and the closing sensor 44b is at the moment when it is turned on.
Note that, in FIG. 4, even when the insertion sensors 44a and 44b and the medal M overlap each other, both the insertion sensors 44a and 44b and the medal M are shown by solid lines, but the medal M and the insertion sensor 44a and It does not represent the positional relationship of 44b. The insertion sensors 44a and 44b may be arranged on the front side or the back side of the medal M in the direction perpendicular to the paper surface of FIG.

When the medal M further advances and enters the state of FIG. 4C, the medal M is detected by both the insertion sensors 44a and 44b. Therefore, the closing sensor 44a in this case is on, and the closing sensor 44b is also on.
Here, the diameter of the medal M is, for example, 25 mm (so-called 25 pie (φ)) in the general specification and 30 mm (so-called 30 pie (φ)) in the special specification. Therefore, it is necessary to set the distance between the closing sensors 44a and 44b so that the state of FIG. Here, as will be described later, whether or not the state of FIG. 4C, that is, the time during which both the insertion sensors 44a and 44b are ON (detecting the medal M) is within a predetermined range. Determines whether to determine a medal insertion error. Therefore, the distance between the closing sensors 44a and 44b also depends on how to set the time when both the closing sensors 44a and 44b are on.

When the medal M further advances from the state of FIG. 4(c), the insertion sensor 44a stops detecting the medal M, as shown in FIG. 4(d). In this case, the closing sensor 44a is at the moment when it is turned off, and the closing sensor 44b remains on. When the medal M further advances, the insertion sensor 44b no longer detects the medal M, as shown in FIG. 4(e). Therefore, in this case, the closing sensor 44a remains off, and the closing sensor 44b is at the moment when it is turned off. The position of the medal M in FIG. 4(e) corresponds to M4 in FIG.

FIG. 5 is a time chart showing ON/OFF of the input sensors 44a and 44b. In FIG. 5, time S21 is the moment when the closing sensor 44a is turned on from off (the closing sensor 44b remains off), and corresponds to the timing of FIG. 4(a).
Next, the time at the moment (FIG. 4B) when the insertion sensor 44b detects the medal M (turned from OFF to ON) is S22. Furthermore, the time when the insertion sensor 44a stops detecting the medal M (from ON to OFF) (FIG. 4D) is S23. Further, the time at the moment when the insertion sensor 44b stops detecting the medal M (from ON to OFF) (FIG. 4E) is S24.

Here, if the time Ta (between times S21 and S23) during which the insertion sensor 44a detects the medal M is within the range of 6.705 ms (3 interrupts) or more and less than 185.505 ms (83 interrupts). (Condition 1), the main control board 50 determines that the medal M is normally passed, and if it is out of this range, it is determined as a medal passing error.

Further, the time Tb (between times S22 and S23) during which both the insertion sensors 44a and 44b detect the medal M is within the range of 4.47 ms (2 interrupts) or more and less than 118.455 ms (53 interrupts). If so (condition 2), the main control board 50 determines that the medal M is normally passed, and if it is out of this range, it is determined as a medal passing error.

Furthermore, if the time Tc during which the insertion sensor 44b detects the medal M (between times S22 and S24) is within the range of 6.705 ms (3 interrupts) or more and less than 185.505 ms (83 interrupts). (Condition 3), the main control board 50 determines that the medal M is normally passed, and if it is out of this range, a medal passing error is determined.
When all of the above conditions 1 to 3 are satisfied, it is determined that the passage of the medal M is normal, and when at least one condition is not satisfied, a medal passage error is determined.

Further, as shown in FIG. 5, when both the closing sensors 44a and 44b are turned off (time S24), the closing monitoring counter is decremented by "1".
Here, the throw-in monitoring counter becomes “+1” when the passage sensor 46 detects the medal M, and when the medal normally passes through the throw sensors 44a and 44b (both the throw sensors 44a and 44b are turned off). The counter is incremented by “−1” at the time of →ON→OFF, and therefore at time S24. That is, under normal conditions, "1" and "0" are repeated.
On the other hand, when the passage sensor 46 does not detect the medal M and only the insertion sensors 44a and 44b detect the passage of the medal, the insertion monitoring counter becomes "-1", and the main control board 50 determines that the medal passage error. To do.

When the passage sensor 46 detects the medal M (insertion monitoring counter=“+1”) and the insertion sensors 44a and 44b do not detect passage of the medal M, the passage sensor 46 further detects the medal M. When the insertion monitoring counter reaches a predetermined value of "2" or more, the main control board 50 determines that there is a medal jam error. For example, when the normal value of the insertion monitoring counter is set to "0" to "2" and the insertion monitoring counter becomes "3" or more, the main control board 50 determines that it is a medal jam error. To be
The throw-in monitoring counter is cleared when the blocker 45 changes from the off state to the on state.

In FIG. 5, at time S24, when the insertion sensor 44b is switched from ON to OFF, the insertion monitoring counter is decremented by “1”, and it is determined that the medal M has passed normally, the main control board 50 causes the medal insertion. Processing (bet processing or credit processing) is executed. For example, at that point, if the bet number is less than the specified number, the bet number “1” addition process is executed. Specifically, when the specified number in the game is "3" and the bet number at that time is "0", the bet number is changed from "0" by "1" addition processing of the bet number. Update to "1".

In addition, at that time, when the bet amount has already reached the specified number and the credit amount has not reached the maximum number “50”, the credit amount “1” addition process is executed. For example, when the number of credits at that time is "10", the number of credits is updated to "11".
It should be noted that when the bet number reaches the specified number and the credit amount reaches the maximum number “50”, the main control board 50 turns off the blocker 45. Thereby, even if the medal M is inserted from the medal insertion slot 47, the medal M is returned. In other words, in this case, even if the medal M is inserted, it will not be detected by the insertion sensors 44a and 44b.

In FIG. 5, in addition to turning on/off the closing sensors 44a and 44b, timings at the time of power failure occurrence and power failure detection are displayed. FIG. 5 shows Example 1 and Example 2, both of which exemplify the case where the power is cut off at the timing (time S21) when the closing sensor 44a is turned on.
In Example 1, the power failure is detected after the time T1 has elapsed from the time S21 when the power failure occurred. Here, in Example 1, “T1>T3” is set. Therefore, when the insertion sensor 44a detects the medal M at the moment when the power is cut off, the power-off process is started after the "1" addition process for the medal M has already been executed.

Here, the time T3 from time S21 to S24 can be represented by "Ta+Tc-Tb". Therefore, the minimum time of the time T3 corresponds to 4 interrupts and is "8.94 ms".
Also, the maximum time of the time T3 corresponds to 113 interrupts and is “252.555 ms”.
Then, in Example 1, it is set so that the power-off process is always executed after the lapse of time S24. Therefore, for example, the time T1 from the occurrence of power shutdown (time S21) to the execution of power shutdown processing is set to be 114 interrupts or more.

With the above setting, even if the power is cut off at the moment (time S21) when the insertion sensor 44a detects the medal M, the power off process is executed after the "1" addition process of the medal M is executed. , The medal M is normally bet or credited. Therefore, swallowing of the medal M can be prevented.

Contrary to Example 1, Example 2 is an example in which the power-off process is executed before the “1” addition process for the medal M is executed. That is, in the second example, the relationship of “T1<T3” is set.
The time T3 from the time S21 to S24 corresponds to 4 interrupts at the minimum time as described above. Therefore, in order to satisfy the relationship of “T1<T3”, it is necessary to execute the power-off process within 3 interrupts after the power-off occurs. However, since it is difficult to set the power-off process to be executed within 3 interrupts after the power-off occurs, the minimum time Tc is set to be longer than 4 interrupts. For example, the minimum time of the time Tc may be set to 15 interrupts. Then, if the time T1 from the occurrence of power interruption (time S21) to the power interruption processing is set to about 10 interrupts, when the power interruption occurs at time S21, the power interruption processing is executed before the time S24. It becomes possible.

When the power-off process is executed, the “1” addition (bet or credit) process for the medal M is not executed thereafter. Therefore, in Example 2, even if the insertion sensor 44a detects the medal M at the time of time S21 (when the power is cut off), the "1" addition process for the medal M1 is not executed. As a result, there is a disadvantage that the medal M is swallowed, but as described in the first embodiment (A), after the power is cut off, the “1” addition process of the medal M is not executed. The power-off process can be executed as quickly as possible.

<First embodiment (C)>
The first embodiment (C) defines the relationship between the payout sensors 37a and 37b and power-off.
When the medals to be paid out are added to the credits, the hopper motor 36 is not driven, and the storage area for the number of credits provided in the RWM 53 of the main control board 50 is updated. Further, the value indicated by the credit number display LED 76 is updated so that the number corresponds to the number of credits stored in the storage area.

Then, when paying out medals after the number of credits reaches the upper limit value “50”, the hopper motor 36 is driven to pay out medals from the hopper 35 (discharging from the payout opening). In this case, the payout sensors 37a and 37b are configured to detect ON/OFF each time one medal is paid out. When the on/off detection result by the payout sensors 37a and 37b is within the normal range, it is determined that one medal M has been correctly paid out, and when the detection result is not within the normal range, the medal M is detected. The main control board 50 determines that the medal payout error has occurred.

FIG. 6 is a plan view for explaining the operation when the medals M are paid out from the medal payout device. Although not shown in FIG. 6, a hopper disc (substantially disc-shaped rotating disc) is attached to the bottom surface of the hopper 35, and the hopper disc is rotated by the drive of the hopper motor 36. In this hopper disc, a plurality of openings capable of holding the medals M are formed along the outer circumference of the hopper disc. Then, the medal M in the hopper 35 is configured to enter the opening of the hopper disc. When the hopper motor 36 is driven in this state, the hopper disc is rotated and the medals M held in the opening of the hopper disc are ejected one by one. A new medal M in the hopper 35 is inserted into the empty opening where the medal M is discharged.

In FIG. 6, the medal M located at M1 is the one immediately after being ejected from the opening of the hopper disc. Both the fixed shaft 38a and the movable shaft 38b are components that form a medal payout device. The fixed shaft 38a is a shaft that does not move when the medals M are paid out. On the other hand, the movable shaft 38b is a shaft that reciprocates each time one medal M is paid out. In the unloaded state, the movable shaft 38b is arranged at the position shown by the solid line in the figure, and is fixed by a spring (not shown in FIG. 6, which corresponds to the spring 39b in FIG. 7 described later). It is biased to the 38a side. Immediately after being ejected from the opening of the hopper disc, the medal M (M1) comes into contact with both the fixed shaft 38a and the movable shaft 38b.
In addition, when the medal M is arranged at the position (M1) shown by the solid line in FIG. 6 and is in contact with both the fixed shaft 38a and the movable shaft 38b, the medal M is located between the fixed shaft 38a and the movable shaft 38b. Narrower than diameter. Therefore, at this point, the medal M cannot pass through between the fixed shaft 38a and the movable shaft 38b.

The pushing force in the F1 direction in FIG. 6 acts on the medal M discharged from the opening of the hopper disc. When the pushing force in the F1 direction acts on the medal M, the medal M can move in the F1 direction, and the pushing force pushes the movable shaft 38b in the F2 direction in the drawing. The fixed shaft 38a does not move. As a result, the movable shaft 38b moves in the F2 direction in the figure while maintaining the state of being in contact with the medal M. Further, the movable shaft 38b moves between the fixed shaft 38a and the movable shaft 38b to a position where the medal M can pass. In other words, the gap between the fixed shaft 38a and the movable shaft 38b becomes wider than the diameter of the medal M. The position of the movable shaft 38b at this time is shown by a two-dot chain line in the figure.

As a result, the medal M passes through between the fixed shaft 38a and the movable shaft 38b, and is discharged in the F1 direction (medal payout opening side) in the figure. The medal M at this time is shown by a two-dot chain line in FIG. 6 (M2). When the medal M is discharged, the force for pushing the movable shaft 38b in the F2 direction is released. As a result, the movable shaft 38b is returned to the position shown by the solid line in FIG. 6 again by the force of the spring.

FIG. 7 is a plan view illustrating an ON (detection)/OFF (non-detection) state of the payout sensors 37a and 37b when the medal M is paid as described above in the medal payout device. FIG. 7 shows that the movable piece 39a moves in the order of (a)→(b)→(c)→(d)→(a) every time one medal M is paid out.

FIG. 7A shows the state of the movable piece 39a when the movable shaft 38b is arranged at the position shown by the solid line (initial position) in FIG. The movable piece 39a is attached so as to be rotatable around a central axis in the figure, and is urged clockwise by a spring 39b.
When the movable piece 39a is biased clockwise in the drawing, the movable shaft 38b in FIG. 6 is biased toward the fixed shaft 38a in the drawing.
In the state where the movable piece 39a is biased clockwise in FIG. 7 by the spring 39b and no force other than the tensile force of the spring 39b acts on the movable piece 39a, the movable piece 39a has a predetermined stopper (not shown). No.), the vehicle is stopped at the position shown in FIG.

As shown in FIG. 7A, payout sensors 37a (upper side in the figure) and 37b (lower side in the figure) are arranged on the left side of the movable piece 39a in the figure. The movable piece 39a is formed so as to extend toward the payout sensors 37a and 37b. When the movable piece 39a is stopped at the position in FIG. ing.
Note that, in FIG. 7, the payout sensors 37a and 37b both show the housing of the sensor, and the illustration of the light emitting/receiving unit (eyes of the sensor) is omitted. In this respect, it differs from the input sensors 44a and 44b in FIGS. 2 and 4 in which only the light emitting/receiving unit (sensor eyes) is shown.

Here, the payout sensor 37a is in an ON state (for example, FIG. 7A) when detecting the movable piece 39a, and is in an OFF state (for example, FIG. 7B) when it does not detect the movable piece 39a. Is set to be.
Similarly, the payout sensor 37b is in an off state (for example, FIG. 7A) when the movable piece 39a is not detected, and is in an on state (for example, FIG. 7C) when the movable piece 39a is detected. Is set to.
In the state of FIG. 7A, the payout sensor 37a detects the movable piece 39a and is in the ON state, and the payout sensor 37b is not detected in the movable piece 39a and is in the OFF state.

As described in FIG. 6, when the pushing force in the F1 direction in FIG. 6 acts on the medal M, the movable shaft 38b starts moving in the F2 direction in FIG. 6, but the movable shaft 38b moves in this way. When moved, in FIG. 7A, the movable piece 39a starts rotating counterclockwise against the biasing force of the spring 39b. Then, when the movable piece 39a moves to the position of FIG. 7B, the tip of the movable piece 39a goes out from inside the dispensing sensor 37a. As a result, the payout sensor 37a does not detect the movable piece 39a, so that it is turned off. Even if the movable piece 39a is rotated to the position shown in FIG. 7B, the tip of the movable piece 39a does not reach the dispensing sensor 37b. Therefore, in the state of FIG. 7B, the payout sensor 37a is off and the payout sensor 37b is off.

6, when the movable shaft 38b further moves in the F2 direction and reaches the position of the two-dot chain line portion in FIG. 6 (the position where the medal M can pass through the gap between the fixed shaft 38a and the movable shaft 38b), 7, the movable piece 39a further rotates counterclockwise and reaches the position shown in FIG. 7(c). As a result, the tip of the movable piece 39a enters the dispensing sensor 37b, and the dispensing sensor 37b detects the movable piece 39a. Therefore, in the state of FIG. 7C, the payout sensor 37a is in the off state and the payout sensor 37b is in the on state.

In FIG. 6, when the medal M is further ejected from the position of M2, the force for urging the movable shaft 38b in the F2 direction in FIG. 6 disappears, so that the movable shaft 38b moves to the position shown by the solid line in FIG. Return. The returning force at this time is due to the force of the spring 39b in FIG. As a result, in FIG. 7, the movable piece 39a rotates clockwise, the tip of the movable piece 39a goes out of the dispensing sensor 37b, and the dispensing sensor 37b no longer detects the movable piece 39b. FIG. 7D shows the state at this time. In the state of FIG. 7D, the payout sensor 37a is off and the payout sensor 37b is off.

When the movable piece 39a further rotates in the clockwise direction, the tip of the movable piece 39a enters the payout sensor 37a, and the payout sensor 37a detects the movable piece 39a. As a result, the state (initial state) of FIG. 7A is restored. In the state of FIG. 7A, as described above, the payout sensor 37a is on and the payout sensor 37b is off. Further, when returning to this position, the movable shaft 38b returns to the position indicated by the solid line in FIG.

FIG. 8 is a time chart showing ON/OFF of the payout sensors 37a and 37b.
In FIG. 8, it is assumed that the medal payout process is started and the hopper motor drive signal is in the ON state.
In FIG. 8, the state before time S31 is the state shown in FIG. When time S31 is reached, the state shown in FIG. 7B is entered and the payout sensor 37a is turned off (the payout sensor 37b is off). Next, when the time S32 is reached, the payout sensor 37b is turned on. This state is the state shown in FIG. In FIG. 8, the time from time S31 to S32 is Td.

The payout sensor 37a is in the OFF state and the payout sensor 37b is in the ON state until time S33, and the payout sensor 37b is in the OFF state at the time S33. This state is the state shown in FIG. In FIG. 8, the time from time S32 to S33 is Te. Then, when time S34 is reached, the state returns to the state (initial position) of FIG. 7A, and the payout sensor 37a is turned on. In FIG. 8, the time from time S32 to S34 is Tf.

In the payout process, the main control board 50 monitors the time during which the payout sensors 37a and 37b are in the on/off state, and when the time is not within the predetermined time range, determines that the medal payout error has occurred.
For example, in FIG. 8, the time Td is set to less than 29.055 ms (13 interrupts). Therefore, when the payout sensor 37b is turned on by the 12th interrupt after the payout sensor 37a is turned off, it is determined to be normal, but if the payout sensor 37b is on by the 12th interrupt. If not, a medal payout error occurs.

The time Te during which the payout sensor 37a is off and the payout sensor 37b is on is set to be 11.175 ms (5 interrupts) or more and less than 62.58 ms (28 interrupts). Therefore, at time S32 (when the payout sensor 37b is turned on), the time Te until the payout sensor 37b is turned off is monitored, and when the time Te is not within the range of the predetermined time, The main control board 50 determines that there is a medal payout error.

Furthermore, after the payout sensor 37b is turned on (time S32), the time Tf until the payout sensor 37b is turned off and the payout sensor 37a is turned on (time S34) is 11.175 ms (5 interrupts). ) Or more and less than 62.58 ms (28 interrupts). Therefore, at time S32 (when the payout sensor 37b is turned on), the time Tf until the payout sensor 37b is turned off and the payout sensor 37a is turned on is monitored. When it is not within the range of the predetermined time, the main control board 50 determines that it is a medal payout error.

Further, in FIG. 8, similarly to FIGS. 3 and 5, the time from the occurrence of power cutoff to the power cutoff process is also displayed.
First, it is assumed that the power is cut off at the timing of time S31, that is, the timing at which the payout sensor 37a is turned off. In this case, in the example of FIG. 3, an example in which the power interruption is detected by 20 interrupts has been described. However, in the example of FIG. The power-off is detected after the elapse of T1), and the power-off processing is set to be executed.

Here, since the maximum time of the time "Td+Tf" (normal time) is the "12+27=39" interrupt, the time T1 from power-off to execution of the power-off processing is, for example, 40 interrupts (89.4 ms). Set. With this setting, even if the power-off occurs at the moment when the payout sensor 37a is turned off, the power-off process can be started after the payout process for one medal is normally completed. That is, “(Td+Tf)<T1” can be set.

Conventionally, there has been a case where a power interruption (power failure, etc.) occurs during the medal payout process. In this case, depending on the occurrence timing of the medal payout process and the power-off, it is determined that the medal has been paid out even though the medal has not been paid out, which may cause a loss to the player.
On the other hand, in the first embodiment (C), even if the power is cut off during the medal payout process, the medals can be paid out correctly.

In particular, when the medal payout process is started, that is, even when the power is cut off at the timing of time S31 in FIG. 8, the power cutoff is detected after one medal payout process is completed, and the process proceeds to the power cutoff process. Therefore, for example, the power-off process is not executed when the payout sensor 37a is in the off state or when the payout sensor 37b is in the on state. Thus, it is possible to prevent the power-off process from being executed in the middle of the medal payout process and the medal payout process to be stopped before the (one piece) medal payout process ends normally.

If the time T1 is set longer than necessary, the payout process for the next medal may be executed. Therefore, the power-off process is executed at least before the next medal payout process is executed. In FIG. 8, for example, assuming that the cycle of one coin payout process is time T4 and the payout sensor 37a is changed from the on state to the off state at the timing of time S35, "T1<T4" is set.

<Second Embodiment>
The second embodiment relates to a trace of a gate formed on the board case of the main control board 50.
In the prior art, the shape, size, position, etc. of the gate traces on the substrate case were determined by the mold designer at the time of manufacturing the mold, for the sake of convenience in manufacturing the mold.
However, since the trace of the gate becomes an uneven surface, even if a hole is made aiming at the trace of the gate, for example, it may not be visually recognizable (not noticeable).

If the main CPU 55 of the main control board 50 is arranged right below the gate mark, a hole is made in the gate mark, and a wire is passed through the hole, so that the main CPU 55 is accessed. There is a possibility that it will be done). In particular, when the gate trace is formed to have a thinner wall thickness than other portions, it becomes easier to make a hole than other portions.
Therefore, in the second embodiment, it is possible to prevent the goto action from being performed by using the gate mark of the substrate case.

FIG. 9 is an external perspective view showing the main control board 50 and the board case 56 (the upper cover 57 and the lower cover 58) in an exploded manner.
The substrate case 56 is composed of an upper cover 57 and a lower cover 58, both of which are (injection) molded products made of transparent resin. Therefore, when the main control board 50 is housed inside, the state of the main control board 50 can be clearly confirmed visually from the outside of the board case 56.

On the main control board 50, electronic components such as the above-mentioned main CPU 55, management information display LED 74 (four-digit LED, also referred to as “combination ratio monitor” or “ratio indicator”), set value display LED 73, etc. It is installed. Although many electronic components such as the RWM 53 and the ROM 54 described above are mounted on the main control board 50, their illustration is omitted in FIG. 9. Further, although not shown in FIG. 9, on the main control board 50, there are mounted bet switches 40a and 40b, a start switch 41, a stop switch 42, a passage sensor 46 in the medal selector, and failure confirmation LEDs of the insertion sensors 44a and 44b. Has been done. The failure confirmation LED is not limited to this.
For example, the failure confirmation LED of the start switch 41 is off when the start switch 41 is off, and when the start switch 41 is operated (when the start switch 41 is operated and the sensor detects that the switch is on). ) Is an LED that is turned on (lit).

The failure confirmation LED of the start switch 41 and the failure confirmation LEDs of other operation switches and sensors, which will be described later, are turned off when the operation switch is operated (when the sensor detects that the switch is on), and when it is off. It may be configured to light up.

Further, two LEDs for failure confirmation of the bet switches 40a and 40b are provided for the bet switches 40a and 40b, and are turned off when the bet switch 40 is not operated, and the bet switch 40 is operated. It is an LED that lights up when an electric signal at that time is received.
Furthermore, a total of three failure confirmation LEDs of the passage sensor 46 and the insertion sensors 44a and 44b are provided for each sensor, and are turned off when no medal is detected, and are turned on when a medal is detected. It is an LED.
Then, the administrator operates the start switch 41, for example, and confirms whether the failure confirmation LED of the start switch 41 mounted on the main control board 50 is turned on or off. Can be confirmed. The same applies to other switches or sensors.

The failure confirmation LED may be turned on/off by operating the start switch 41 or the like when the front door is opened during normal operation (the setting is not being changed and the setting is not being confirmed). .. Alternatively, the failure confirmation may be performed by performing a predetermined operation after opening the front door and causing a door open error. Further, it may be turned on/off by operating the start switch 41 or the like at all times (even while changing the setting or confirming the setting).

The model number of the board is displayed (printed or the like) on the main control board 50. Although not shown in FIG. 9, the model numbers and the like are similarly displayed on the upper surfaces of the RWM 53 and the ROM 54.
Furthermore, screw holes 50a for passing screws are formed at the four corners of the main control board 50.
On the other hand, bosses 58c for screwing are formed at four corners on the inner surface of the lower surface of the lower cover 58. When the main control board 50 is placed on the lower cover 58, the screw hole 50a and the boss 58c overlap each other, and the main control board 50 is fixed to the lower case 58 by screwing the screw from the screw hole 50a to the boss 58c. can do.

When the upper cover 57 is placed on the lower cover 58 in this state, the upper cover 57 and the lower cover 58 are formed to fit with each other (in FIG. 9, the concrete shape of the fitting portion is not shown). Further, caulking portions 57a are provided on the left and right sides of the upper cover 57 in the figure. Similarly, a caulking portion 58a is provided on the left and right rows of the lower cover 58 in the drawing. Note that, in FIG. 9, the concrete shape and the detailed shape of the caulking portions 57a and 58b are not shown.

When the upper cover 57 and the lower cover 58 are fitted to each other and caulking is performed using the caulking portions 57a and 58a, at least a part of the caulking portions 57a and 58a must be destroyed thereafter (without plastic deformation). The cover 57 and the lower cover 58 cannot be opened.
Thereby, the security of the main control board 50 can be ensured.

Further, as shown in FIG. 9, gate traces 57b are provided at two locations on the outside of the upper surface of the upper cover 57. In the board case 56 (with the upper cover 57 and the lower cover 58 fitted together), the side in which the main control board 50 is housed is called “inside”, and the side exposed to the outside is called “outside”. ..
In FIG. 9, the gate traces 57b are provided at two places, but not limited to this, they may be provided at some places.

Here, the "gate" is a sprue for pouring resin (hot water) into the mold during resin molding, and the gate mark is a mark that remains at the boundary between the gate and the molded product after resin molding. is there.
When the substrate case 56 (the upper cover 57 and the lower cover 58) has a shape as shown in FIG. 9, it is low cost to form the mold in the vertical direction in FIG. Further, in the case of a multi-cavity mold, it is preferable to use a pin gate, and from the viewpoint of the fluidity of the resin (hot water), it is preferable to provide the gate near the center of the molded product. Therefore, in the second embodiment, the gate positions of the upper cover 57 and the lower cover 58 are formed not on the side surface but on the upper surface in FIG.

Further, considering the cutting of the protrusion of the gate mark at the time of molding, the gate mark is preferably provided on the outside.
From the above, the gate mark 57b of the upper cover 57 is provided outside the upper surface.
Further, for the same reason as above, the gate mark 58b of the lower cover 58 is also provided outside the lower surface (the surface opposite to the visible surface in FIG. 9). In FIG. 9, the gate mark 58b of the lower cover 58 is provided in two places like the gate mark 57b of the upper cover 57, but it may be provided in one place, or in three or more places. Good.

Further, when the resin (hot water) flows from the gate into the mold, the spread of the resin (hot water) in the mold is not uniform, and if a cooling time difference occurs, the molded product may be warped and deformed. Therefore, it is preferable that the gate position of the molded product is arranged at a position where the resin (hot water) spreads uniformly in the mold. Furthermore, when the gates are provided at a plurality of locations, it is preferable that the distance from the end of the molded product to the gates and the distance between the gates are as uniform as possible.

10A is a plan view showing the positional relationship between the gate traces 57b of the upper cover 57 and the gate traces 58b of the lower cover 58 of the substrate case 56 and the main control substrate 50. As shown in FIG. FIG. 10A shows a state in which the main control board 50 is accommodated in the board case 56 (a state in which the main control board 50 is fixed to the lower cover 58 and the upper cover 57 and the lower cover 58 are fitted to each other). Is a plan view seen from above. Further, the main control board 50 is seen through from the upper surface side of the upper cover 57.

Furthermore, (b) shows Example 1 of the sectional view taken along the line AA in FIG. Indicates. Note that hatching is omitted in these cross-sectional views from the viewpoint of easy viewing of the drawings.
As shown in FIG. 10A, in a state where the main control board 50 is accommodated in the board case 56, the two gate marks 57b extend vertically (on the main control board 50 side) (directly below) the upper cover 57. The model number display, management information display LED 74, set value display LED 73, and main CPU 55 (socket) are set so as not to be located. As described above, the RWM 53, the ROM 54, and the failure confirmation LED are also mounted on the main control board 50, but it is preferable that the gate mark 57b is not located directly above them.

The gate trace 57 is arranged as described above for the following reason.
It is necessary for the main control board 50 to visually confirm whether any unauthorized modification has been made even after the slot machine 10 has been installed in the market. In particular, it is necessary to confirm whether or not the main CPU 55 and the like (including the RWM 53 and the ROM 54. The same applies hereinafter) and whether or not the main CPU 55 has been altered by a goto act. Further, since the main control board 50 is housed in the board case 56 and the board case 56 is sealed as described above, it is necessary to visually confirm the main control board 50 from the outside of the board case 56. is there.
The board case 56 accommodating the main control board 50 therein is mounted inside the housing of the slot machine 10, for example, on the inside of the back surface. This is because the numerical values displayed by the set value display LED 73 and the management information display LED 74 are mounted at a position where it is easy to see.

Therefore, it is considered that the manager of the slot machine 10 visually views the board case 56 (main control board 50) from the direction perpendicular to the upper surface of the upper cover 57. That is, it is considered that the board case 56 (main control board 50) is visually observed as shown in FIG. Therefore, if the main CPU 55 and the like are arranged in the vertical direction (directly below) the gate mark 57b, the gate mark 57 may hinder the visibility. In particular, the information displayed (printed or the like) on the upper surface of the main CPU 55 or the like can be viewed without hindering the visibility.

Since the entire upper cover 57 is molded from transparent resin, the visibility is not completely impeded even just below the gate mark 57b. However, as shown in (b) and (c) in FIG. 10, since the cross section of the gate trace 57b becomes an uneven surface, the visibility directly below the gate trace 57b is deteriorated (becomes worse than the plane). Things are certain. Further, in the cross-sectional view of FIG. 10B, since the upper end surface of the protrusion 57d is a cut surface, whitening may occur due to the stress when the resin is cut. Therefore, also in this case, the visibility under the gate mark 57b is hindered.

Further, since the upper surface of the upper cover 57 is a smooth surface which is transparent and has no unevenness except for the gate mark 57b, even if a hole is formed by, for example, a got action, it can be easily visually recognized.
On the other hand, the gate mark 57b is an uneven surface obtained by cutting the resin. Therefore, if a hole is formed in the gate hole 57b and then the hole is sealed with, for example, a resin material, it may not be possible to easily visually determine whether or not the hole is formed in the gate mark 57b. Therefore, there is a possibility that a goto act using the gate mark 57b is performed.

On the other hand, when a hole is formed in the gate mark 57b, if the main CPU 55 or the like is located in the vertical direction (directly below) the gate mark 57b, it becomes easy to carry out goto. Therefore, unless the main CPU 55 and the like are arranged in the vertical direction (directly below) the gate mark 57b, it becomes difficult to access the main CPU 55 and the like, and it is possible to make the goto action difficult.

In addition, the model number displayed (printed or the like) on the surface of the main control board 50 is also important information for checking the presence or absence of fraud, so the model number is displayed in order to make it easy to confirm (read). The gate trace 57b was not arranged directly above the area. Further, when there is a gate mark 57b directly above the model number display, a hole is made in the gate mark 57b to access the inside of the substrate case 56, and to prevent the model number display from being tampered with, The gate mark 57b should not be arranged directly above the model number display.

Further, regarding the set value display LED 73, it is necessary to see the displayed numerical value when changing the setting or confirming the setting. Also, regarding the management information display LED 74, it is necessary to look at the displayed numerical value in order to confirm whether the advantageous section ratio, the accessory ratio, etc. are within the proper ranges. Therefore, the gate trace 57b is not arranged directly above these LEDs. Further, in the same manner as described above, in order to make it difficult for the LED in the substrate case 56 to be accessed through the holes formed in the gate trace 57b by utilizing the gate trace 57b, and thus it is difficult to perform the goto action, the true value of these LEDs is to be improved. The gate mark 57b is not arranged above.

As for the failure confirmation LED described above, the administrator of the slot machine 10 operates the operation switch to confirm whether or not the failure confirmation LED corresponding to the operation switch is turned on. Therefore, it is preferable that the gate mark 57b is not located directly above the failure confirmation LED. It is similar to the above that the failure confirmation LED is not arranged in the vertical direction (directly below) the gate mark 57b to make it difficult to carry out the goto action.

In FIG. 10, the cross-sectional views of Example 1 shown in (b) and Example 2 shown in (c) have the same outer shape of the gate trace 57b. Then, in the example 1 of (b), the inside of the upper surface of the gate mark 57b is left flat. On the other hand, in Example 2 of (c), the inside of the upper surface of the gate trace 57b is formed in a projection shape (thickness).
The outside of the gate trace 57b has a protrusion 57d at the center thereof, and a recess 57c formed so as to sink in a cylindrical shape on the outer periphery thereof. The boundary between the gate and the molded product is connected at the time of molding, and when the molded product is separated from the mold, this boundary is cut with a cutter. Therefore, the upper end surface of the protrusion 57d is a cut surface by the cutter. There are two methods for cutting the boundary between the gate and the molded product: a method of cutting automatically at the time of injection by a molding machine and a method of cutting in a post process.

Here, at the time of cutting the boundary between the gate and the molded product, it is costly to process the cut surface to be a completely smooth surface, in other words, to make the height of the protrusion 57d substantially "0". High and difficult. Therefore, the recess 57c is formed so that the projection 57d does not protrude above the outer surface of the upper surface of the upper cover 57 even if the projection 57d has some height. As a result, for example, when an operator who assembles touches the upper cover 57, it is possible to prevent the protrusion 57d from being injured.

As shown in FIG. 10B, when the recess 57c is provided in the gate mark 57, the wall thickness of the upper cover 57 becomes thin accordingly. In this way, if there is a part where the wall thickness is thin, there is a possibility that the goto action of making a hole in the recess 57c and accessing the inside of the substrate case 56 becomes easy.
Therefore, in Example 2 of FIG. 10C, a protrusion 57e is provided on the opposite side (inner side) of the upper surface outside where the gate trace 57b is provided to prevent the thickness of only the recess 57c from becoming thin. There is. If the protrusion 57e is not provided and the thinned portion is not provided, it is possible to make the goto action of making a hole in the recess 57c difficult.

Further, the protrusion 57e not only contributes to countermeasures against fraud by preventing a part of the wall thickness of the gate trace 57b from becoming thin, but also functions as a dimple (a pool of hot water) at the time of molding. In FIG. 10( b ), when the resin (hot water) collides with the inside of the upper surface when the resin (hot water) is injected from the gate (the position corresponding to the protrusion 57 d) of the mold, the resin (hot water) There is a risk that the flow will change rapidly and it will not be able to flow stably. Therefore, by providing a dimple (reservoir pool) at a position facing the tip of the gate, the flow of the resin (hot water) is prevented from changing abruptly when the resin (hot water) is injected from the gate. (Hot water) will be able to flow stably. The protrusion 57e may have various shapes such as a quadrangular cross section, a triangular cross section, a trapezoidal cross section (in the case of FIG. 10C), a dome cross section, and the like. Any shape may be used as long as it can prevent this.

As for the visibility of the gate trace 57b in the vertical direction (directly below), the smoothness of the lower side of the gate trace 57 is superior to the uneven shape. Therefore, regarding the visibility directly under the gate mark 57b, the shape of FIG. 10B is superior to the shape of FIG. 10C. Further, the shape of FIG. 10B does not need to form a portion corresponding to the protrusion 57e in the mold as compared with the shape of FIG. 10C, and thus the shape of the mold is simplified ( Cost can be reduced).

Further, the gate mark 58b of the lower cover 58 is also provided on the outer side (lower side in FIG. 9). Furthermore, the protrusion 57d and the recess 57c shown in FIG. 10B are formed on the outer side. This is because, as described above, it is more convenient in terms of molding processing to provide the protrusion 57d and the recessed portion 57c on the outside of the molded product.
Then, when the main control board 50 is fixed to the lower cover 58, the pin position of the main CPU 55 and the like of the main control board 50 is set so as not to be located in the vertical direction of the gate mark 58b of the lower cover 58. This is to make a hole in the gate mark 58b of the lower cover 58 so that the pins of the main CPU 55 and the like cannot be accessed.
When the gate mark 58b of the lower cover 58 has the shape shown in FIG. 10C, the protrusion 57e of FIG. 10C faces the pin side of the main control board 50. It goes without saying that the pins protruding from the lower surface side of the control board 50 and the protrusions 57e are formed so as not to interfere (contact) with each other.

Further, as shown in FIG. 10A, when the upper cover 57 and the lower cover 58 are fitted to each other, the gate mark 57b of the upper cover 57 and the gate mark 58b of the lower cover 58 overlap in the vertical direction. It is preferable to arrange (shift) so that it does not occur. Particularly, in the case of the gate traces 57b and 58b shown in FIG. 10B, the wall thickness of a part (the recess 57c) of the gate traces 57b and 58b is thin, but the thin wall portion is the upper cover. By arranging 57 and the lower cover 58 in a position where they do not overlap, it is possible to prevent overlapping of easily targeted portions.
Further, when the gate mark 57b of the upper cover 57 and the gate mark 58b of the lower cover 58 overlap in the vertical direction, the position of the gate mark of the other cover can be known only by looking at one cover. turn into. In order to prevent this, the gate mark 57b of the upper cover 57 and the gate mark 58b of the lower cover 58 do not overlap in the vertical direction.

<Third Embodiment>
In the third embodiment, when the command is transmitted from the main control board 50 to the sub control board 80, when the communication between the main control board 50 and the sub control board 80 is temporarily disabled (breakage of wire). Later, when communication is restored, communication fails due to the influence of noise, etc.).
As described above, the control command transmitting means 71 of the main control board 50 transmits commands such as the push order instruction number and information on the operated stop switch 42 to the sub control board 80. Then, the sub control board 80 outputs the effect based on the command received from the main control board 50, and updates the effect in accordance with the operation of the operation switch during the game.

Here, there is a possibility that the main control board 50 and the sub-control board 80 are disconnected and communication becomes impossible. Causes thereof include poor contact, radio waves, and the like. When the sub control board 80 does not receive a command from the main control board 50, the production is stopped in the current state. Further, neither the main control board 50 nor the sub control board 80 determines whether or not there is a disconnection in the communication between them. Therefore, the main control board 50 progresses the game (operation of the bet switch 40, the start switch 41, and the stop switch 42) even when a disconnection occurs between the main control board 50 and the sub control board 80. Etc.), the command transmission process is continued to the sub control board 80. On the other hand, when the sub control board 80 does not receive a command from the main control board 50, it maintains the effect state at that time.
Even when the main control board 50 and the sub-control board 80 are disconnected, the main control board 50, by the operation of the instruction function, presses the acquired number display LED 78 in the order of pressing, for example, during AT. Display instruction information. Thereby, even if the sub control board 80 is not functioning normally, the player can operate the stop switch 42 in the correct pressing order by looking at the pressing order instruction information.
Furthermore, since the player can compare the push order instruction information displayed on the acquired number display LED 78 with the effect contents (correct answer push order) displayed as an image on the image display device 23, both pieces of information are inconsistent. While doing so, it is possible to know that there is a problem in the image display by the sub control board 80.

For example, when a disconnection occurs in the middle of the "N" game and communication is restored in the middle of the "N+1" game, the sub control board 80 can receive the command transmitted from the main control board 50. At times, the effect cannot be suddenly switched to the "N+1" game. Even when the communication is restored, the sub control board 80 does not receive the command “N+1” when the command related to the operation of the start switch 41 (command for informing the game start) is not received. This is because it cannot be determined. Therefore, when the communication between the main control board 50 and the sub control board 80 is broken and then restored, there is a possibility that the player may be misunderstood depending on the content of the effect.
Therefore, in the third embodiment, when the communication between the main control board 50 and the sub-control board 80 is restored after the disconnection, the player is given a sense of discomfort while avoiding misunderstanding as much as possible. Output a production that does not exist.

FIG. 11 shows an operation of the main control board 50 (described as “main operation” in FIG. 11) and display of effects by the sub control board 80 (described as “sub display” in FIG. 11) in the third embodiment. .), and shows five examples including pattern 1 (example 1) to pattern 5 (example 5).
Patterns 1 to 5 all show an example in which communication is lost in the middle of the “N” game (disconnection occurs) and communication is restored in the middle of the “N+1” game.
In the main operation of FIG. 11, “bet” means that the bet switch 40 is operated and the specified number of bets are effectively bet. In addition, "start" means that the game is started by operating the start switch 41 after a specified number of bets have been bet. Furthermore, for example, "right stop" means that the right stop switch 42 is operated (the right reel 31 is stopped).

Further, in the sub-display, the "push order effect" means, for example, an effect in which the correct answer push order is displayed as an image in a game in which a push order bell or a push order replay is won. Specifically, for example, “display in the middle of right and left” means an effect that notifies that the correct pressing order is in the order of “middle of right and left”. In addition, for example, "left middle display" means that the left stop switch 42 is operated, and the second stop switch to be operated is left, and the third stop switch 42 is to be inside. It means an effect to be notified.
Furthermore, for example, "right stop effect" means an effect that the right stop switch 42 is operated (the right reel 31 is stopped) when a command indicating that the right stop switch 42 is operated is received. means.

In the pattern 1, when the start switch 41 is operated at the "N" game, the main control board 50 performs the lottery of the winning combination as described above. In the game, “right-left-middle” is an example in which a push order bell in which the correct answer order is selected is won. In this case, the main control board 50 transmits a pressing order instruction number (command) corresponding to the correct pressing order “middle right, left” to the sub control board 80 during AT. Upon receiving this command, the sub-control board 80 outputs, to the image display device 23, a pressing order effect for displaying the correct pressing order of "right left middle".
Although not shown, the main control board 50 displays the push order instruction information corresponding to the correct answer push order “right left middle” on the acquired number display LED 78 (operation of the instruction function).

Next, it is assumed that the player operates the right stop switch 42 as the first stop, looking at the correct pressing order (right stop). As a result, the right reel 31 is stopped and a command to that effect is transmitted to the sub control board 80. When the sub-control board 80 receives the command, the sub-control board 80 outputs the effect that the right stop switch 42 is operated (the right reel 31 is stopped) (right stop effect), and displays the right-left center display and the left-center display (in addition, other). Are displayed as “−middle left”, “xmiddle left”, etc.).
Then, in pattern 1, an example in which a disconnection occurs after the right reel 31 is stopped and communication between the main control board 50 and the sub control board 80 is disabled (sub disconnection) is shown. That is, this is an example in which communication is disabled during the game.

The main control board 50 can progress the game even if communication between the main control board 50 and the sub control board 80 is disabled (even if the sub control board 80 is not functioning). In the example of the pattern 1, in the "N" game, after the occurrence of the disconnection, the left and middle stop switches 42 are respectively operated (the left and the middle reel 31 are stopped) (left middle stop). ).

Next, it is assumed that the bet operation for the "N+1" game is performed and the start switch 41 is operated. In the "N+1" game, as in the "N" game, "right-left-middle" shows an example in which the push-order bell (or push-order replay) that is the correct answer push order is won. Note that, in the "N+1" game, as in the "N" game, an example is shown in which the stop switch 42 is operated in the right-left-middle pushing order. However, when a winning combination having the right-right-middle pushing order is won. Not limited to, any role lottery result may be used.

In addition, when the push order bell (or the push order replay) having the correct push order is won in the “N+1” game, the main control board 50 displays the push order instruction information on the acquired number display LED 78. Therefore, the player can operate the stop switch 42 in the correct press order by the press order instruction information displayed on the acquired number display LED 78 even when the correct press order is not displayed on the image display device 23. Become.

In the "N+1" game, the player first operates the right stop switch 42. After that, it is assumed that the communication between the main control board 50 and the sub control board 80 is restored before operating the second left stop switch 42.
Thereby, when the player operates the left stop switch 42 which is the second stop switch 42, the command is transmitted to the sub control board 80. Upon receiving this command, the sub control board 80 updates the image display so as to correspond to the received command. That is, an image indicating that the left stop has been performed is displayed (left stop effect). Here, the sub-control board 80 updates as a continuation of the already displayed effect, that is, as an effect of the "N" game.

Therefore, actually, the second stop switch 42 (left) of the "N+1" game is operated, but the sub-control board 80 has the second stop switch 42 (left) of the "N" game. Outputs the performance when operated. Since the second correct answer pressing order in the "N" game is left, in this example, the correct answer pressing order is performed. Therefore, the sub-control board 80 outputs the left stop effect (press order correct effect effect) and the final middle display effect.

Then, in the "N+1" game, when the last middle stop switch 42 is operated, a command to that effect is transmitted to the sub control board 80. Upon receiving this command, the sub control board 80 outputs an effect corresponding to the third stop of the "N" game, that is, an intermediate stop effect.
Even if the winning combination having the correct answer pressing order is won in the "N+1" game and the correct answer pressing order is other than right, left or right, in the situation of pattern 1, the effect is output as described above. To be done. That is, in the "N+1" game, when the pressing order operated by the player is right and left, even if the pressing order corresponds to the incorrect pressing order, the pressing order fails as in pattern 2 described later. No production is output.

Furthermore, in the "N+1" game, even if a winning combination that does not have the correct answer pressing order is won, or even if the winning combination is not won, if the pressing order operated by the player is in the middle of right and left, the above The same effect as is output. That is, even if the “N+1” game does not have the correct pressing order, the sub control board 80 indicates that the left stop switch 42 has been operated after the communication is restored (in the example of pattern 1). When the command is received, the left stop effect (press order correct effect effect) is output, and further, the middle display is output.

Next, when a bet is placed for the "N+2" game and the "N+2" game is started by operating the start switch 41, the main control board 50 tells the sub-control board 80 " The command corresponding to the start of the "N+2" game is transmitted. As a result, the sub-control board 80 outputs an effect at the start of the "N+2" game. Specifically, when the start switch 41 is operated, commands of the effect group number and the pressing order instruction number are transmitted to the sub control board 80. Upon receiving these commands, the sub-control board 80 displays the pressing order effect and the correct answer pressing order as at the start of the "N" game.

From the above, in pattern 1, until the third stop of the "N+1" game, the sub-control board 80, based on the command ("N+1" game) received from the main control board 50, "N" game Is continuously output, and when the "N+2" game item is started, the effect is updated to the "N+2" game item.
Further, the main control board 50 may transmit a command for the number of acquired sheets to the sub-control board 80 at the end of the game, and the sub-control board 80 may also display the image of the number of acquired sheets in the AT. In such a case, the sub-control board 80 cannot receive the command of the number of acquisitions at the end of the "N" game, that is, during the disconnection, so at the end of the "N" game, "N-1". The number of cards acquired at the end of the game will remain displayed. Then, when the communication is restored and the command of the acquired number is received at the end of the “N+1” game, the sub-control board 80 updates the image display so that the acquired number is obtained at the end of the “N+1” game. ..

In pattern 2, the main operation is the same as in pattern 1. Further, the timing of disconnection is the same as that of pattern 1, but the timing of communication recovery is different from that of pattern 2. In pattern 2, in the "N+1" game, communication is restored after the second stop, that is, the left stop.
In the pattern 2, the main operation and the sub-display in the “N” game are the same as those in the pattern 1, and the description thereof will be omitted.
Next, in the "N+1" game, the stop switch 42 is operated in the order of right and left, but communication is restored after the second left stop.

Immediately before the communication is restored, the sub control board 80 is outputting the right stop effect of the “N” game and the middle left display. When communication is restored in this state and the player operates the stop switch 42 (third stop) in the "N+1" game, the command is transmitted to the sub control board 80. When the sub-control board 80 receives a middle stop command while the left center display is being performed, the sub control board 80 determines that it is the incorrect pressing sequence, and outputs a pressing sequence failure effect. In the third embodiment, after the pressing order failure effect is output, the subsequent pressing order effects are not output.

In the "N+1" game, assuming that the stop switch 42 is operated in the order of pushing the left and right sides of the middle, the communication is restored after the middle left stop, and the right stop is performed after that, so the right stop command is sub-controlled. When transmitted to the board 80, the pressing order failure effect is output as in the above. Since the sub control board 80 is in the process of outputting the right stop effect and the middle left display, if the right stop command is received at this point, the same stop command is received twice in one game. .. Even in such a case, it is processed as a failure in the pressing order and the effect is output without notifying an error.
Then, when the "N+2" game is started in the same manner as in pattern 1, the command at the start of the "N+2" game is transmitted to the sub control board 80. As a result, the sub-control board 80 starts producing the "N+2" game.

In pattern 3, the main operation and sub-display of the "N" game are the same as in pattern 1.
Pattern 3 shows an example in which communication is restored after the first stop right and the second stop during the "N+1" game. Therefore, in the "N+1" game, after the communication is restored, the command of the left stop which is the third stop is transmitted to the sub control board 80. Since the sub-control board 80 outputs the "left middle display" of the "N" game, when it receives a command to stop to the left in this state, it determines that it is the correct answer pressing order. Therefore, the sub-control board 80 outputs the left stop effect (push order correct effect effect), and then outputs the middle display.

However, on the side of the main control board 50, the "N+1" game ends with the third stop on the left. Next, when the command at the start of the “N+2” game is sent to the sub control board 80, the sub control board 80 receives the command, and then the “N+2” game is started. Switch to the production at the start. Therefore, the left stop effect and the middle display which have been output until then are canceled. Further, even if the command at the start of the "N+2" game is received during the output of the middle display, no error notification is given and the effect at the start of the "N+2" game is output according to the received command. ..

Pattern 4 is an example of displaying the number of remaining games in AT in the sub display. In pattern 4, the main operation, the disconnection timing, and the communication recovery timing are the same as in pattern 3.
The main control board 50 transmits a command of the number of remaining games of the AT to the sub-control board 80 at the start of each game. When the sub control board 80 receives a command for the number of remaining games of the AT from the main control board 50, it updates the display of the number of remaining games of the AT. In addition, during AT, the display of the number of remaining games is not displayed alone but is output together with the pressing order effect of the pattern 3.

In pattern 4, the main control board 50 transmits a command for the number of remaining games in AT to the sub control board 80 when the start switch 41 is operated (when the game is started). Here, in the "N" game, it is assumed that the number of remaining AT games is 10 games.
At the start of the “N” game, the sub control board 80 displays the number of remaining games in AT (10 games remaining) based on the command received from the main control board 50.
Then, if the disconnection occurs in the middle of the "N" game and the disconnection state continues even at the start of the "N+1" game, the main control board 50 will start the sub at the start (start) of the "N+1" game. The sub-control board 80 cannot receive the command (due to disconnection) although it executes processing for transmitting a command for the number of remaining games (9 games) in the AT to the control board 80. Therefore, in the "N+1" game, the "remaining 10 games" of the "N" game remains displayed.

Then, when communication is restored in the middle of the “N+1” game (after stopping in the left) and the game shifts to the “N+2” game, the main control board 50 is switched to the sub control board 80 at the start of the “N+2” game. On the other hand, the command of the number of remaining games (8 games) in AT is transmitted. Upon receiving this command, the sub control board 80 updates the display of the remaining 10 games to the display of the remaining 8 games.

Pattern 5 is an example when the main operation, the disconnection timing, and the communication recovery timing are the same as those in Pattern 4, but the "N" game is the remaining one game of AT.
At the start of the “N” game (when the start switch 41 is operated), the main control board 50 transmits to the sub control board 80 a command for the number of remaining games in AT (one game remaining). Upon receiving this command, the sub control board 80 updates the display of the remaining 1 game (from the display of the remaining 2 games until then).
When a disconnection occurs after the right stop of the "N" game, the main control board 50 determines that the number of remaining games in AT is 0 at the start of the "N+1" game (when the start switch 41 is operated). Although the command to the effect that it is a game is transmitted to the sub control board 80, the sub control board 80 cannot receive the command (same as pattern 4). Therefore, at the start of the “N+1” game, the display indicating that the remaining one AT game is continued.

Further, the sub control board 80 outputs an AT end effect when the AT is ended. The AT end effect is executed at the end of the game based on the reception of the command (at the start of the game) that the number of remaining games in AT is 0 game.
However, in the example of pattern 5, since the sub-control board 80 has not received the command indicating that the number of remaining games in AT is 0 game, the AT end effect is not output. Therefore, even at the end of the "N+1" game, the effect indicating that there is one remaining AT game is output.

Then, when the “N+1” game ends and the “N+2” game starts, the main control board 50 sends a command indicating the normal game (non-AT) to the sub control board 80 at the start of the “N+2” game. Send. Based on the reception of this command, the sub control board 80 erases the display of "remaining one game" and outputs a normal (non-AT) effect.
At the end of AT, an image such as "Pachinko/pachislot is a game machine that you can enjoy moderately" is displayed to prevent slipping in. However, in the case of pattern 5, since the sub-display has not returned to normal at the end of the "N+1" game, the image display cannot be performed. Therefore, as a countermeasure for this, the game history is managed on the side of the sub-control board 80, and when the game shifts to the next game (in the example of FIG. 11, "N+2" game) over the end of AT, the game is The image may be displayed at the start of.

In the above patterns 1 to 5, when a disconnection occurs in the "N" game, the sub-control board 80 continues to output the effect immediately before the disconnection of the "N" game until the communication is restored, and "N+1". When the communication is restored in the middle of the game game, the continuation of the production output as the “N” game game is output based on the command received in the “N+1” game game. Therefore, for example, in pattern 1, in the "N+1" game, when a command to stop left is received after communication is restored, the correct answer is given regardless of whether the stop switch 42 is actually operated in the correct push order. A push order effect will be output.

On the other hand, in pattern 1, for example, in the "N+1" game, when the command of the middle stop is received after the communication is restored, the pressing order of the production output at that time, that is, the "N" game Since the incorrect middle press order is applied to the middle left display, the press order failure effect is output regardless of whether the stop switch 42 is actually operated in the correct correct press order. However, even if the pressing order failure effect is output in the "N+1" game, if the player operates the stop switch 42 in the correct pressing order of the "N+1" game, a symbol that is advantageous to the player Since the combination is stopped and displayed, there is no disadvantage to the player.

As described above, when the communication is restored in the "N+1" game, the "N+1" game outputs the effect that inherits the effect before the disconnection ("N" game) and outputs the "N+2" game. Reset the effect at the start (return to the correct effect). As a result, it is possible to minimize the output of unnatural effects in both the game in which the disconnection has occurred and the game in which the communication has been restored, and to prevent the player from misunderstanding as much as possible.

Further, in the example of FIG. 11, an example is shown in which the communication is restored to the "N+1" game after the disconnection occurs in the "N" game, but the communication is restored when two or more games have passed after the disconnection occurred. However, it is similar to FIG.
For example, if a disconnection occurs in the "N" game and communication is restored to the "N+a" game (a="2" or more), the "N" game disconnects until the "N+a-1" game. The production just before is continued to be output. Then, in the "N+a" game in which the communication is restored, the continuation of the "N"game's effect, which has been continuously output, is executed based on the command received after the communication is restored. Next, at the start of the “N+a+1” game, the effect (correct effect) at the start of the “N+a+1” game is updated.

<Fourth Embodiment>
The motor 32 performs acceleration, constant speed, deceleration, and stop processing when rotating and stopping the reel 31, but these are all in the excited state. Then, when the rotation of the motor 32 is stopped, a predetermined time (time T11 described later) and four phases are simultaneously excited (hereinafter referred to as “four-phase excitation state”).
The fourth embodiment relates to the time relationship between the operation of the stop button 42a of the stop switch 42 and the four-phase excitation state when the motor 32 is stopped.
FIG. 12 is a cross-sectional view showing the relationship between the operation of the stop button 42a and the detection sensor 42e in the fourth embodiment. Note that hatching is omitted in FIG. 12 from the viewpoint of viewability of the drawing. Further, FIG. 12 is a schematic diagram for explaining the fourth embodiment, and does not mean that an actual product has a structure as shown in FIG. In FIG. 12, the process from pressing the stop button 42a to returning to the original state is illustrated in the order of (a)→(b)→(c)→(d). In the figure, the upper side is the player side, and the lower side is the inside of the slot machine 10. In the figure, the side above the front door 12 is the side visible to the player.
Furthermore, the line where the detection sensor 42e detects the moving piece 42d is indicated by a dotted line. The moment when the tip of the moving piece 42d contacts the dotted line is the moment when the detection sensor 42e detects the moving piece 42d.

In FIG. 12A, the stop button 42a is an operating body of the stop switch 42, and is operated (pushed inside the slot machine 10) when the player turns on the stop switch 42. The player side of the stop button 42a is arranged so as to protrude from the front door 12 provided on the front surface of the housing of the slot machine 10 by about several millimeters. When viewed from the front of the player, this portion has a substantially cylindrical shape. In the unloaded state, the stop button 42a is urged in the F3 direction (outward direction, player direction) in the figure (a) by the spring force of the (compression) coil spring 42c, and the urging force causes the stop button 42a. An end of the player 42 a on the player side projects from the front door 12. In this state, the lower surface portion (hereinafter referred to as “flange-shaped portion”) of the stop button 42a in the figure is in contact with the front door 12.
On the other hand, the stopper 42b is provided inside the front door 12 (inside the housing), and comes into contact with the stop button 42a when the stop button 42a is pushed in, and prohibits further movement of the stop button 42a. Is.

On the lower surface side of the stop button 42a in the drawing, a movable piece 42d that is movable integrally with the stop button 42a is provided. Further, a detection sensor 42e for detecting the movement of the moving piece 42d is arranged immediately below the moving piece 42d. In the unloaded state shown in (a) of the figure, when the stop button 42a is biased toward the front door 12 by the biasing force of the coil spring 42c, the tip (lower end in the figure) of the moving piece 42d is It is arranged at a position away from the detection sensor 42e. Therefore, in the state of (a) in the figure, the detection sensor 42e is not detecting the moving piece 42d and is in the off state.

Next, as shown in (b) in the figure, when stopping the rotation of the reel 31, the player pushes the stop button 42a in the F4 direction. As a result, the stop button 42a moves downward in the figure against the biasing force of the coil spring 42c. When the stop button 42a moves downward in the figure, the moving piece 42d integrated with the stop button 42a also moves downward in the figure. As a result, the tip of the moving piece 42d enters the detection sensor 42e. Then, when the tip of the moving piece 42d contacts the dotted line of the detection sensor 42e, the detection sensor 42e changes from the off state to the on state. FIG. 12B shows the position of each member at the moment when the detection sensor 42e changes from the off state to the on state. At the moment when the detection sensor 42e is turned on, the flange-shaped portion of the stop button 42a is not yet in contact with the stopper 42b, and there is a gap between the stop button 42a and the stopper 42b.

When the stop button 42a is further pushed in from the state of FIG. 12B, the flange-shaped portion of the stop button 42a contacts the stopper 42c, as shown in FIG. 12C. This position is the deepest part when the stop button 42a is pushed. Further, in the state of FIG. 12C, since the state in which the tip of the moving piece 42d is detected by the detection sensor 42e is maintained, the detection sensor 42e is in the ON state.

When the player releases the pushing of the stop button 42a from the state of FIG. 12C (excluding the force in the F4 direction in FIG. 12C), the stop button 42a is pushed by the biasing force F3 of the coil spring 42c. The force to return to the initial position acts. As a result, the stop button 42a and the moving piece 42d that is integral with the stop button 42a move upward in the drawing. As a result, the tip of the moving piece 42d does not come into contact with the dotted line of the detection sensor 42e, and the detection sensor 42e changes from the on state to the off state (FIG. 12(d)).

FIG. 12D shows the arrangement of each member at the moment when the detection sensor 42e changes from the ON state to the OFF state. In the state of FIG. 12D, the stop button 42a has not returned to the final position. When the stop button 42a is further returned from the state of FIG. 12(d), the stop button 42a comes into contact with the flange-shaped front door 12 and the stop button 42a stops at this position. This state is the state shown in FIG. 12A, and the stop button 42a is in the no-load state.
The state of FIG. 12(b) showing the timing when the detection sensor 42e changes from the off state to the on state and the state of FIG. 12(d) showing the timing when the detection sensor 42e changes from the on state to the off state are generally Although the same, there is no particular problem even if a slight deviation occurs.

FIG. 13 is a time chart showing the relationship between the operation of the stop button 42a and the excitation state of the motor 32 in the fourth embodiment. (a) shows Example 1 and (b) shows Example 2. Show.
In FIG. 13A, the stop button 42a is at the initial position in the unloaded state (FIG. 12A), and the time when the pressing of the stop button 42a is started is S41. The time when the stop button 42a is pushed and the detection sensor 42e is turned from off to on, that is, when the state shown in FIG. 12B is set is S42. Further, the time when the stop button 42a is pushed in from that position and the stop button 42a reaches the deepest part (when the state shown in FIG. 12C is reached) is S43. The above times S41, S42, and S43 depend on the player's pushing speed, and are not constant. If the stop button 42a is pushed in slowly, the time from time S41 to S43 becomes long, and if the stop button 42a is pushed quickly, the time from time S41 to S43 becomes short.

Next, at time S44, the stop button 42a is released from being pushed. At the time of time S44, the stop button 42a is assumed to be located at the deepest part.
When the stop button 42a is released from being pushed, as described above, the spring force of the coil spring 42c exerts a force for returning the stop button 42a to the initial position. The operator of the stop button 42a does not touch the stop button 42a from the moment the stop button 42a is released.
Then, the time when the detection sensor 42e is switched from on to off, that is, when the state of FIG. Here, the time from time S44 to S45 is set to T11.

The time T11 is a variable determined by the spring force (spring constant) of the coil spring 42c and the stroke (moving distance) of the stop button 42a from the deepest position to the position where the detection sensor 42e is turned off. In Example 1 of (a), the spring force (spring constant) of the coil spring 42c and the stroke of the stop button 42a are designed such that the time T11 is 100 ms.

On the other hand, when the stop switch 42 is turned on (specifically, the detection sensor 42e is turned on) (in the state of FIG. 12B), the reel control means 65 causes the reel control unit 65 to correspond to the stop switch 42. The stop control of 31 is executed, and the reel 31 is stopped at the position corresponding to the winning combination lottery result by the winning combination lottery means (the result determined by the internal drawing means). The time from the start of the stop control of the reel 31 to the stop of the reel 31 (after the detection of the detection sensor 42e is turned on) is as described above (except for the predetermined reel 31 during the MB game). Within 190 ms (when the number of symbols on the reel 31 is 21 symbols, the number of moving frames is within 5 frames, when it is 20 symbols, the number of moving frames is within 4 frames). Therefore, the time from the start of deceleration of the reel 31 to the stop of the reel 31 is not constant because it depends on the result of the lottery and the position of the reel 31 at the moment the stop switch 42 is operated.

Further, after the reel control means 65 has moved the reel 31 to a predetermined position, the motor 32 is simultaneously excited (braked) for four phases for a predetermined time (the above-mentioned four-phase excitation state). ).
Here, the motor 32 in the present embodiment is a four-phase stepping motor, and performs, for example, 1 and 2 phase excitation while the motor 32 (reel 31) is rotating (note that the motor 32 is not limited to 1 and 2 phase excitation. Absent). Therefore, even when the motor 32 is rotating, it is in one excited state. Then, when the rotational driving of the motor 32 is stopped, the four-phase excitation state is set.
When the bouncing stop is performed after the reel 31 is moved to the predetermined position (when the reel 31 appears to vibrate at the stop position), the three-phase excitation state is set instead of the four-phase excitation state. Is also possible.

At the moment when the rotation driving of the motor 32 is stopped, the motor 32 or the reel 31 may be over the desired position due to inertia during rotation, so the motor 32 is stopped at the moment when the reel 31 is stopped at a predetermined position. A four-phase excitation state is set and static torque is generated so that inertia does not occur from the stop position. When the motor 32 is in the four-phase excitation state, the next operation acceptance of the stop switch 42 is not permitted. During the first or second stop, the next operation acceptance of the stop switch 42 is permitted because the detection sensor 42e of the operated stop switch 42 is changed from the on state to the off state (returning to the state of FIG. 12D). ), and when the four-phase excitation state of the motor 32, which has stopped the rotation drive, ends.

The reason for controlling in this way is as follows.
In order to maintain the stop position of the reel 31, the motor 32 is controlled to the four-phase excitation state. However, when such control is performed, more load is applied than in the normal time, and thus the load of the entire slot machine 10 is reduced. It will grow. Therefore, in order to reduce the load, it is possible to accept the operation of the next stop button 42a after ending the four-phase excitation state of one motor 32.

In Example 1 of FIG. 13A, when the hand lottery result by the hand lottery means (the result determined by the internal lottery means) is a predetermined result (for example, when the push order bell is won), the four-phase excitation state is set. The excitation time T12 from the start to the end is set to 90 interrupts (2.235×90=201.15 ms). Here, when the role lottery result is a predetermined result, the excitation time T12 in the four-phase excitation state is set to "90 interrupt" because the excitation time T12 is always constant regardless of which role lottery result. Does not mean that.

Therefore, in Example 1 of the fourth embodiment, the setting is made so that “T11<T12”.
Here, when the stop control of the reel 31 is started from the time of time S42, the reel 31 is stopped within 190 ms. As described above, when the number of symbols on the reel 31 is “21”, the number of moving frames during stop control is within 5 (minimum 1 frame), or when the number of symbols on the reel 31 is “20”. Since the number of moving frames during stop control is within 4 frames (minimum of 1 frame), the reel 31 stops within about “40” to “190” ms from the time of time S42.
On the other hand, the time from the time when the detection sensor 42e is turned on to the time when the stop button 42e reaches the deepest portion and the pushing force of the stop button 42e is released (time from time S42 to S44) , “40” to “180” ms. Therefore, the time when the four-phase excitation state of the motor 32 is started and the time S44 when the stop button 42a is released from pressing are close to each other (approximately the same time).

Therefore, in Example 1, the four-phase excitation state is started at the timing (time S44) when the pressing of the stop button 42a is released, and the detection sensor 42e is changed from the on state to the off state (time S45). The motor 32 is designed so that the four-phase excitation state ends (time T12 elapses). Therefore, when the four-phase excitation state of the motor 32 is finished, the operation of the next stop button 42a can be set to be accepted.
In this way, if the detection sensor 42e is designed to be turned off before the end of the four-phase excitation state, it is possible to allow the next stop button 42a to be operated upon completion of the four-phase excitation state. .. This enables the game to proceed at high speed.

On the other hand, in the example 2 of FIG. 13B, from the moment when the stop button 42a reaching the deepest portion is released (time S44) to when the detection sensor 42e is turned on (time S45). In this example, the time T11 (until the arrival) is set to 300 ms. Therefore, the return time of the stop button 42a is three times longer than in Example 1. As described above, the return time of the stop button 42a can be set (adjusted) by the spring force (spring constant) of the coil spring 42c and the stroke of the stop button 42a.

On the other hand, in Example 2, the time T12 from the start of the four-phase excitation state to the end thereof is set to 45 interrupts (100.575 ms).
Then, in Example 2, as in Example 1, it is assumed that the 4-phase excitation state is started from the moment when the stop button 42a reaching the deepest portion is released (time S44), and the 4-phase excitation of the motor 32 is started. The design is such that the detection sensor 42e is turned off after the excitation state ends. Therefore, when the detection sensor 42e is turned off, the operation of the next stop button 42a can be accepted.

By designing the four-phase excitation state to end when the detection sensor 42e is turned off in this manner, the operation acceptance of the next stop button 42a is permitted when the detection sensor 42e is turned off. can do. This enables the game to proceed at high speed.
As described above, both Example 1 and Example 2 have advantages in control.
In addition, in the example 1 and the example 2 of FIG. 13, the example in which the time T12 from the start to the end of the four-phase excitation state is different is shown. However, if the four-phase excitation time T12 is a constant value, for example, if "T11<T12", then the next stop button 42a can be accepted when the four-phase excitation state ends. Therefore, when the four-phase excitation time T12 is a constant value, the game of Example 1 can be played at a higher speed.

<Fifth Embodiment>
The fifth embodiment relates to the relationship between on/off of a power source and activation of a program.
FIG. 14 is a time chart showing an outline of the control in the fifth embodiment.
In FIG. 14, (a) is a diagram showing a state when the power is cut off after the main program (the program of the main control board 50) is started. The power supply is turned on at time S51 and then turned off at time S55.
When the power is turned on at time S51 (the power switch 11 is turned on in FIG. 1), the supply of power to both the main control board 50 and the sub control board 80 is started, and the main control board 50 and The voltage level of the sub control plate 80 gradually increases and reaches the supply level V0 (the level when the power is on). Note that, in FIG. 14, the voltage supply level V0, the power supply cutoff detection level V1, and the drive voltage limit V2 are the same as those in FIG. 3 (first embodiment (A)).

The time when the voltage level of the main control board 50 and the sub control board 80 reaches the supply level V0 after the power is turned on at time S51 is defined as S52. After that, the sub program by the sub control board 80 is started from time S53 when time T22 has elapsed from time S52. Thereafter, the main program by the main control board 50 is started from time S54 when time T23 (T23>T22) has elapsed from time S52. In this way, the sub program is activated first and then the main program is activated when the main control board 50 transmits the first command after power-on to the sub control board 80. This is for keeping the command receivable on the sub-control board 80 side.

Next, at the time of time S55, when the power is cut off (the power switch 11 is turned off, a power failure or the like) occurs, the voltage levels of the main control board 50 and the sub control board 80 gradually decrease. Even if the voltage level is lowered, if the voltage is equal to or higher than the drive voltage limit V2, the main control board 50 and the sub control board 80 can execute the power-off processing.
Further, when the power failure occurs at time S55, the voltage becomes the power failure detection level V1 at time T0 (20 interrupts) as in FIG. 3, and the power failure is detected (time S56). Furthermore, after the power-off is detected, the power-off processing is executed, for example, after one interruption, as in FIG. It is assumed that the power-off process ends at time S57.
After that, when time S58 is reached, the voltage falls below the drive voltage limit V2, and the program (process) cannot be executed. For this reason, the power-off process is controlled to be completed before the time S58 is reached.

When the main program is started at time S54, the setting of the main CPU 55, the check of the RWM 53, the confirmation of whether or not the previous power-off was normal, the confirmation of the state of the setting key switch, etc. are executed, and then the interrupt processing is activated. .. When the setting key switch is off, power interruption recovery processing (initialization of a predetermined range of the RWM 53, etc.) is executed after the interruption processing is activated. On the other hand, when the setting key switch is on, the process proceeds to the setting change process after the interrupt process is activated.
Then, as shown in FIG. 14A, in the case where the power cutoff occurs after the main program is started, when the setting key switch is off, the power cutoff process is executed after the power cutoff recovery process is completed. To do. As a result, the program can be terminated normally.
On the other hand, when the power is cut off after the main program is activated, if the setting key switch is on, the power cutoff process is executed without starting the setting change process. This is because if the setting change process is executed after the power is cut off, a problem may occur.

Further, in order to execute the main program normally, the setting of the main CPU 55 and the check of the RWM 53 are always executed even when the power failure is detected at the same time when the main program is started.
Furthermore, after the main program is started, even if the power is cut off thereafter, it is always executed until the interrupt is started. This is to detect a power failure in interrupt processing. As in the first embodiment (A), for example, at the “N” interrupt, a voltage drop (power cut detection level V1) that is determined to have occurred a power cut is detected, and the next “N+1” game is executed. However, when the voltage drop is detected, the power failure is detected at the "N+1" interrupt (judging power failure). Then, the power-off process is executed from the "N+2" interrupt.

In the example of FIG. 14A, the main program is activated at time S54, and the power is cut off at time S55 thereafter. However, even if the power is cut off at the same time as the time S54 (start of the main program), the power cut processing can be completed before the voltage reaches the drive voltage limit V2.
In FIG. 14A, the time T21 from when the power is turned on (time S51) until the voltage reaches the supply level V0 (time S52) is the time when the power supply is cut off (time S55) and the voltage is changed to the low level. The time is set to be shorter than T24.
The time T23 (the time from when the voltage reaches the supply level V0 to when the main program is started) is set to be shorter than the time T24.

FIG. 14B is an example when the power is cut off before the main program is started by the main control board 50. In the example of FIG. 14B, the power is turned on at time S51 and the power is turned off at time S59. Here, the time S59 is before the time S54 in FIG. That is, after the power (supply level V0) necessary for starting the main program is supplied, the power is cut off before the predetermined time (time T23) elapses (before the time S54 is reached), and the voltage drops. Here is an example. In such a case, the main program will not start. Therefore, thereafter, the voltage gradually decreases, and finally the power source becomes the Low level.
In addition, in the example of FIG. 14B, when the power is turned on again, it can be normally started.
Although not shown in FIG. 14, the power cut may occur immediately after the subprogram is activated (after time S53) and before the time S54 (before the main program is activated). To be
When the power is cut off at the above timing, the subprogram executes the power cut processing of the subprogram. The power-off process of the sub-program can be completed before the voltage supplied to the sub-control board 80 reaches the drive voltage limit V2.
Further, since the power-off at the above timing is the power-off before the start of the main program, the main program does not start as described above.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described contents, and various modifications such as the following are possible.
(1) In this embodiment, the passage sensor 46 is provided. This is because the passage sensor 46 improves the accuracy of the medal insertion determination and is effective as a countermeasure against fraud. However, the passage sensor 46 may not be provided, and only the pair of input sensors 44a and 44b may be provided.

(2) In FIG. 2, the insertion sensors 44a and 44b are configured to detect the medal M moving in a substantially horizontal direction, but the invention is not limited to this. For example, when the medal M is falling substantially vertically downward, the medal M may be detected by the insertion sensors 44a and 44b.
(3) In FIG. 2, the blocker 45 is arranged on the lower surface side of the medal passage, but it is not limited to this. Any device having a function of sending the medal M out of the medal passage before the medal M is detected by the insertion sensor 44a may be used.
Further, as shown in FIG. 2, the insertion sensors 44a and 44b are illustrated so as to detect an area slightly above the center position of the medal M when viewed from the front, but the actual product has such a configuration. Does not mean. The insertion sensors 44a and 44b may be arranged in any manner as long as they are arranged so as to reliably detect the passing medal M.

(4) In FIG. 3, the time T2 is the time from the moment when the medal M is positioned at M2 to the moment when it is positioned at M4, but is not limited to this. For example, when the medal M is at the position M1 in FIG. 2 and the time from the moment the hand is released to the time M4 is reached, T2 may be set, and “T2>T1” may be set. Alternatively, the time taken for the medal M to reach M4 from any predetermined position between M1 and M2 may be set to T2, and “T2>T1” may be set.

(5) In the first embodiment (A), when the power cutoff occurs at the moment when the medal M is located at M2, the power cutoff process is executed before the medal M reaches M4. However, the present invention is not limited to this, and for example, when the power is cut off at the moment when the medal M is located at M2, the power cut processing may be executed before the medal M reaches M3. That is, in this case, due to the power-off process, the medal M is not detected by the insertion sensor 44a.
Alternatively, when the power is cut off at the moment when the medal M is located at M2, the power off process may be executed before the medal M reaches the insertion sensor 44b. In this case, the medal M is detected by the insertion sensor 44a, but is not detected by the insertion sensor 44b, and the power-off process is executed.

(6) Furthermore, in the first embodiment (A), the power is cut off at the moment when the medal M is located at M2, the time T1 until the power cut is detected and the power cut processing (blocker off) is executed. Can be set to be shorter than the time required for the medal M to reach the position where the blocker 45 is installed from the position of M2 (this time is referred to as “T2′”). With this setting, when the power is cut off at the moment when the medal M is located at M2, when the medal M reaches the position of the blocker 45 from the position of M2, the blocker 45 is already turned off. Therefore, the medal can be prevented from passing through the insertion sensors 44a and 44b.
In the above, the position of the medal M2 may be the moment when the hand is released at the position of M1 or a predetermined position between M1 and M2.

(7) As shown in FIG. 3, in the first embodiment (A), the power-off process (blocker off) is executed in the interrupt process next to the interrupt process in which the power-off is detected. However, the present invention is not limited to this, and it may be set such that the power interruption processing (blocker off) is executed after the interruption processing of “2” to “5”, for example, counting from the interruption processing that detects the power interruption. Alternatively, the power-off process (blocker off) may be executed by the interrupt process that detects the power-off.
(8) In the first embodiment (A) of FIG. 3, the time T0 required for the voltage to reach the sustain level V1 from the supply level V0 is set to 20 interrupts when the power is cut off, but the present invention is not limited to this. It is possible to make various settings without depending on the performance of the power supply.

(9) In the first embodiment (C) of FIG. 7, when the medal M is paid out by the medal payout device, the payout sensors 37a and 37b detect the movable piece 39a. However, the present invention is not limited to this, and the payout sensors 37a and 37b may detect the payout medal M itself. For example, the payout sensors 37a and 37 may be arranged like the insertion sensors 44a and 44b shown in FIG. 4 to detect passage of the (payout) medal M.

Further, when the payout sensors 37a and 37b are arranged in such a manner, when the medal M passes through the payout sensors 37a and 37b,
Dispensing sensor 37a is on, dispensing sensor 37b is off (time S31')
Dispensing sensor 37a on, dispensing sensor 37b on (time S32')
Dispensing sensor 37a off, dispensing sensor 37b on (time S33')
Dispensing sensor 37a off, dispensing sensor 37b off (time S34')
Follow the course of.
Then, the time from time S31' to S34' is set to be shorter than time T1 (the time from the occurrence of the power cut to the execution of the power cut processing).

(10) In the second embodiment, the gate trace 57b is formed so that the projection 57d and the recess 57c are on the outer side. Conversely, the gate mark 57b is formed so that the projection 57d and the recess 57c are on the inner side. It is also possible. The same applies to the gate mark 58b of the lower cover 58. In this case, if the gate trace 57b has the shape shown in FIG. 10B, the outer surface of the upper cover 57 or the lower cover 58 becomes a smooth surface. On the other hand, in the case of the shape shown in FIG. 10C, the protrusion 57e is formed outside the upper cover 57 or the lower cover 58.

(11) In the second embodiment, an example in which the main control board 50 is housed is given as an example of the board case 56. However, the second embodiment can be applied not only to the main control board 50 but also to other control boards for which fraud is desired to be prevented, for example, the board case of the sub control board 80. As shown in FIG. 1, the sub-control board 80 also includes the RWM 83, the ROM 54, the sub-CPU 85, etc., but at least in the direction perpendicular to the gate mark (directly below) on the upper surface of the upper cover of the board case of the sub-control board 80. The CPU 85 may not be arranged, and the RWM 83 and the ROM 54 may not be arranged. Similarly, it is possible to prevent the model number display areas of the sub-control board 80 from overlapping in the vertical direction (immediately below) of the gate trace.

(12) In the third embodiment, the pressing order effect during AT and the display of the operated stop switch 42 (stopped reel 31) and the number of remaining games during AT have been described as an example. The third embodiment can be applied even in the case of displaying the acquired number of games (BB game, etc.) and the remaining available number of games.
For example, the number of acquisitions at the start of the "N" game is "200", the number of acquisitions at the start of the "N+1" game is "209", and the number of acquisitions at the start of the "N+2" game is " Suppose it was 218". Further, the main control board 50 is assumed to transmit a command regarding the acquired number to the sub control board 80 at the start of each game.
Then, as in the example shown in FIG. 11, it is assumed that a disconnection occurs in the middle of the “N” game and communication is restored in the middle of the “N+1” game.

In this case, the sub-control board 80 displays "200" as the number to be acquired in the "N" game. Further, at the start of the “N+1” game, since the command regarding the acquired number is not received (due to the disconnection), the “N+1” game also maintains the display of the acquired number of “200”. Next, when the sub-control board 80 receives a command regarding the acquired number at the start of the “N+2” game, it updates the display of the acquired number “218” based on the command.

(13) In FIG. 11 of the third embodiment, an example is shown in which the image display is normally restored at the start of the “N+2” game. However, the present invention is not limited to this, and the image display may be returned to the normal state after the entire stop of the “N+1” game or when the bet operation is performed thereafter. Alternatively, it is also possible to restore the image display to normal at a predetermined timing based on a command transmitted to the sub-control board 80 during or after the complete stop.

(14) In the third embodiment, for example, in the middle of an open "N+1" game, there is a case where the player wins the addition (addition) lottery of the number of available games and the number of games in AT. In this case, since the "N+1" game is disconnected, the sub control board 80 cannot receive a command based on winning the additional lottery. Therefore, in this case, for example, at the start of the “N+2” game, the main control board 50 transmits a command indicating the result after the addition (addition) lottery, and at the start of the “N+2” game, the sub control board 80. It is possible to display the game information (the number of obtainable games and the number of games) after being added.

(15) In the third embodiment (FIG. 11), for example, when the communication is restored before the first stop switch 42 of the “N+1” game is operated, the wire is disconnected after the right first stop of the “N” game. Is possible. Then, in the "N+1" game, it is assumed that the player has made a right first stop. In this case, when the sub-control board 80 receives the command of the right first stop at the "N+1" game, it means that the stop command of the stop switch 42 that has already been operated has been received, so the press order failure effect is produced. Output. Then, at the time of bet operation after the entire stop of the "N+1" game or at the start of the "N+2" game, the image display may be returned to a normal one.

(16) In the third embodiment (FIG. 11), in the case of displaying the acquired number of images during AT, the following method may be used as the update processing of the image display of the acquired number before and after the disconnection.
When the payout processing is performed, the main control board 50 sends a command indicating the number of acquired sheets to the sub control board 80. Here, when a disconnection occurs in the middle of the "N" game, the sub control board 80 cannot receive the number of wins of the "N" game. Immediately before the disconnection of the "N" game, the sub-control board 80 is supposed to display "100" as the acquired number in AT. Further, both the “N” game item and the “N+1” game item in AT are supposed to win 10 cards.
In this case, the number of coins acquired in the AT at the end of the "N" game is supposed to be "110" originally, but remains "100" (because of disconnection). Then, it is assumed that communication is restored in the middle of the "N+1" game. As a result, the sub-control board 80 can return the acquired number in AT to a normal value based on the acquired number command received during the payout processing of the "N+1" game. Here, it may be returned to a normal value at the time of payout processing of the "N+1" game, or may be returned to a normal value at the start of the "N+2" game, as in the example of FIG. Further, it may be updated to "110" at the time of payout processing of the "N+1" game and updated to "120" at the start of the "N+2" game.

(17) In the present embodiment, the slot machine 10 is illustrated as an example of a gaming machine, but the present invention can also be applied to, for example, a pachinko gaming machine. In pachinko gaming machines, starting mouth (starting the symbol fluctuation by the symbol fluctuation display device and winning a random number for jackpot lottery), Den Chu winning mouth (when a game ball wins, the next winning For the sake of ease, a prize hole is provided with a character that opens for a certain period of time and then closes. The electric chew is not limited to the tulip shape.) It is provided. Then, the first embodiment (B) can be applied to these winning openings.

Specifically, for example, a winning sensor (a sensor that first detects a game ball that has won the starting port) and a discharge sensor (a sensor that detects a game ball after being detected by the winning sensor) are provided at the starting port. It is provided. Further, the attacker is provided with a V winning sensor (a sensor that first detects the game ball that has won the attacker) and an ejection sensor (a sensor that detects the game ball after being detected by the V winning sensor). ..
For example, in the case of the starting opening, when the power is cut off at the moment when the game ball is detected by the winning sensor, the discharge sensor is set to be able to detect the game ball before the power-off process is executed. Thereby, even if the power is cut off at the moment when the game ball is detected by the winning sensor, the prize ball can be correctly counted. Therefore, it is possible to prevent the prize ball from not being paid out, even though the game ball has won in the winning opening. The same applies to the V winning sensor and the discharge sensor of the attacker.

(18) In the present embodiment, the slot machine 10 is taken as an example of one of the gaming machines, but the slot machine 10 is a “revolving-type gaming machine” installed in the fourth branch office to which the wind management law is applied. The present invention is not limited to (so-called “pachi-slot gaming machine”), and can be applied to, for example, a casino machine or an enclosed gaming machine (medalless gaming machine) that does not use medals used for playing as a gaming medium.

Here, the enclosed game machine (medalless game machine) can eliminate the medal payout device (a unit including the hopper 35, the hopper motor 36, and the payout sensor 37) in FIG. 1, for example. Further, the medal insertion slot 47 and the medal selector can be dispensed with. Then, all the electronic medals (electronic game media) given by winning the winning combination are stored in the credit number display LED 76. In this case, it is conceivable that the credit number display LED 76 is composed of, for example, five digits (it is possible to store up to "99,999" electronic medals).
Even in such a casino machine or an enclosed game machine (medalless game machine), the present invention can be applied to all of the above-described embodiments and the following embodiments except the first embodiment.

<Sixth Embodiment>
The sixth embodiment relates to control of the medal payout device 15 by the main control board 50.
Here, FIGS. 15 to 17 are diagrams for explaining the relationship between the position of the hopper disk 101, the position of the medal, and the drive control of the hopper motor 36 in the sixth embodiment.
Further, FIG. 15A is a plan view of the medal payout device 15 showing a state before the last ejected medal contacts the fixed shaft 38a and the movable shaft 38b, and FIG. 15B shows the last ejected medal. FIG. 7 is a plan view of the medal payout device 15 showing a state in which the rotation of the hopper disk 101 has proceeded to a state before (a) before contacting the fixed shaft 38a and the movable shaft 38b.

Furthermore, FIG. 16(a) is a plan view of the medal payout device 15 showing a state where the last ejected medal is in contact with the fixed shaft 38a and the movable shaft 38b, and FIG. 16(b) shows the last ejected medal. FIG. 6 is a plan view of the medal payout device 15 showing a state where the movable shaft 38b is pushed and moved.
Further, FIG. 17A is a plan view of the medal payout device 15 showing a state at the moment when the last ejected medal is ejected from the ejecting portion, and FIG. 17B is a plan view of the medal payout device 15 after ejecting the last ejected medal. FIG. 7 is a plan view of the medal payout device 15 showing a state where the rotation of the disc is stopped.

In the sixth embodiment, the medal payout device 15 includes a hopper 35 that stores medals, a hopper disc 101 provided at the bottom of the hopper 35, and a hopper motor 36 that rotates the hopper disc 101. Further, the medal payout device 15 is electrically connected to the main control board 50, as in the first embodiment. Then, the main control board 50 controls driving of the hopper motor 36.

Further, as shown in FIGS. 15 to 17, the hopper disc 101 is formed in a disc shape, and the hopper disc 101 has a holding portion which is an opening portion capable of holding the medals stored in the hopper. Eight 102 are provided along the outer circumference of the hopper disk 101.
Furthermore, each holding portion 102 is formed in a circular hole shape that penetrates from the upper surface to the lower surface of the hopper disk 101. The medals stored in the hopper 35 are formed so as to enter the holding portions 102 through the upper openings of the holding portions 102 and be held by the holding portions 102, respectively.

Further, in the sixth embodiment, when the hopper motor 36 is driven during the medal payout process, the hopper disc 101 shown in FIGS. 15 to 17 rotates clockwise. Then, when the hopper disc 101 rotates clockwise, the medals held by the respective holding portions 102 move in a clockwise arc along with the hopper disc 101 and are sequentially ejected from the ejection portion 103.
When a medal is ejected from the ejecting unit 103, the holding unit 102 that holds the medal becomes empty. Then, other medals stored in the hopper 35 newly enter the empty holding unit 102.

Further, as described in the first embodiment (C), the medal payout device 15 includes the fixed shaft 38a and the movable shaft 38b. Further, in the sixth embodiment, a space between the fixed shaft 38a and the movable shaft 38b is a discharging unit 103 for discharging medals.
As shown in FIG. 16B, when the medal pushes the movable shaft 38b to move the movable shaft 38b and the distance between the fixed shaft 38a and the movable shaft 38b becomes larger than the diameter of the medal, the medal moves to the fixed shaft 38a. And the movable shaft 38b. At this time, the medals are ejected from the ejecting unit 103.
Further, at the moment when the medal passes between the fixed shaft 38a and the movable shaft 38b and the movable shaft 38b returns to the original position (the position shown by the solid line in FIG. 6), the medal is ejected from the ejection unit 103. It is a moment. When the movable shaft 38b returns to the original position, the payout sensor 37 detects that the medal has been ejected from the ejection unit 103.

In one payout process, the medal ejected last from the ejecting unit 103 is referred to as a “last eject medal”, and the medal ejected first from the ejecting unit 103 in the next payout process is referred to as “first ejecting medal”. It is referred to as a “discharge medal”.
In FIGS. 15 to 17, the medals are indicated by a two-dot chain line. The medal with the letter "A" is the last ejected medal in the one payout process, and the medal with the letter "B" is the first ejected medal in the next payout process.

In addition, the position of the holding unit 102 that held the last ejected medal at the moment when the last ejected medal was ejected from the ejecting unit 103 in one payout process is referred to as a “first position”, and one payout is performed. The position of the holding unit 102 that holds the first discharged medal in the next payout process at the moment when the final discharged medal is discharged from the discharging unit 103 in the process is referred to as a “second position”.
FIG. 17A shows the state at the moment when the last ejected medal is ejected from the ejecting unit 103 (the hopper disc 101, each holding unit 102, each medal with the letters “A” to “D”, the fixed shaft 38a). , And the positional relationship between the movable shaft 38b). Then, in FIG. 17A, the position of the holding unit 102 where the medal with the letter “A” was held is the first position, and the medal with the letter “B” is held. The position of the holding portion 102 is the second position.

Then, in the sixth embodiment, the main control board 50, when ending one payout process, the holding unit 102 that holds the first discharged medal in the next payout process has the first position and the second position. The drive of the hopper motor 36 is controlled so that the rotation of the hopper disk 101 is stopped in the state where it is located between and.
FIG. 17B shows a state in which the rotation of the hopper disc 101 is stopped after the last ejected medal is ejected from the ejecting unit 103. In FIG. 17B, the first position and the second position are indicated by broken lines. Further, in FIG. 17B, the medal with the character “B” is the first ejected medal in the next payout process. Then, as shown in FIG. 17( b ), the hopper disc 101 is held in a state in which the holding unit 102 holding the medals with the letter “B” is located between the first position and the second position. Rotation has stopped.

Here, in the sixth embodiment, a DC motor (direct current motor) is used as the hopper motor 36.
Therefore, at the end of the payout process, the main control board 50 causes the hopper motor 36 to flow a current in a direction opposite to the direction in which the medals are discharged, so that the drive of the hopper motor 36 is suddenly stopped and the hopper disk 101 is released. The rotation of can be stopped suddenly.

Further, as described above, when the medal is ejected from the ejecting unit 103 and the movable shaft 38b returns to the original position, the payout sensor 37 detects that fact.
Therefore, when the payout sensor 37 detects that the last ejected medal has been ejected from the ejecting unit 103, an electric current in a direction opposite to that when ejecting the medal is applied to the hopper motor 36 to rotate the hopper disk 101. By making a sudden stop, the holding unit 102, which holds the first discharged medal in the next payout process, can be stopped at the second position.

Further, by supplying an electric current to the hopper motor 36 in the direction opposite to that when ejecting medals, the hopper motor 36 can be driven in the opposite direction and the hopper disk 101 can be rotated in the reverse direction (counterclockwise). ..
Therefore, at the end of the payout process, even if the holding unit 102 that holds the first ejected medal in the next payout process passes the second position, a current in the direction opposite to that when ejecting the medal is applied to the hopper. By flowing the current through the motor 36, the hopper disk 101 can be reversely rotated and returned to the second position.
Then, by returning the holding unit 102 holding the first ejected medal to the second position, the first ejected medal can start moving from the same second position every time. As a result, the same operation can be performed for each payout process, so that the first ejected medal can be stably ejected.

Here, when a constant current is supplied, the DC motor as the hopper motor 36 gradually accelerates from the state in which the rotation of the drive shaft is stopped, and then reaches a constant speed (constant speed).
FIG. 18 is a diagram showing a time chart showing the relationship between the drive signal of the hopper motor 36, the drive state of the hopper motor 36, and the ejection status of medals from the ejection portion 103 in the sixth embodiment.
In FIG. 18, the upper line shows the drive signal of the hopper motor 36, the middle line shows the drive state of the hopper motor 36, and the lower line shows the ejection status of medals from the ejection unit 103.

Further, the drive signal of the hopper motor 36 is a digital signal output from a predetermined output port provided in the main control board 50, and when the drive signal of the hopper motor 36 is changed from OFF to ON, a constant current is supplied to the hopper motor 36. When the drive signal of the hopper motor 36 flows from the ON state to the OFF state, the current flowing through the hopper motor 36 becomes "0".
Furthermore, in FIG. 18, "stop" of the driving state of the hopper motor 36 indicates a state in which the rotation of the drive shaft is stopped, and "constant speed" of the driving state of the hopper motor 36 indicates that the rotation of the drive shaft is constant speed. Shows the state of reaching (constant speed).

As shown in FIG. 18, when the drive signal of the hopper motor 36 changes from OFF to ON, the drive state of the hopper motor 36 gradually increases from “stop” and then reaches “constant speed”.
Further, a portion in which the line indicating the driving state of the hopper motor 36 is obliquely rising to the right indicates that the rotation of the drive shaft of the hopper motor 36 is gradually accelerated.

In this way, in the hopper motor 36 using the DC motor, the rotation of the drive shaft gradually accelerates when the drive signal changes from OFF to ON.
Therefore, if the holding unit 102 that holds the first ejected medal stops at the second position, the rotation of the drive shaft of the hopper motor 36 gradually accelerates by the time the holding unit 102 reaches the first position. Therefore, it takes a longer time than the medal ejection interval at the constant speed.
That is, when the holding unit 102 that holds the first ejected medal is stopped at the second position, the time required from the start of driving the hopper motor 36 until the first ejected medal is ejected from the ejector 103 is the same. It becomes longer than the medal ejection interval when the drive shaft of 36 rotates at a constant speed.
This may give the player a feeling that the ejection of the first (first) medal has been delayed.

Therefore, in the sixth embodiment, at the end of one payout process, in the main control board 50, the holding unit 102 that holds the first discharged medal in the next payout process is located between the first position and the second position. The drive of the hopper motor 36 is controlled so that the rotation of the hopper disk 101 is stopped in the state where it is located.
When the holding unit 102 that holds the first ejected medal stops between the first position and the second position, the distance to reach the first position becomes shorter than when it stops at the second position. .. As a result, the time required to reach the first position is shorter than when the vehicle stops at the second position. Therefore, even if the rotation of the drive shaft of the hopper motor 36 is gradually accelerated, the first (first) medal It is possible to prevent the player from feeling that the discharge of is delayed.

Further, when the holding unit 102 holding the first ejected medal is stopped between the first position and the second position, as shown in FIG. 17B, two adjacent holding units 102 in the hopper disc 101. The part corresponding to the space between the two is located in front of the discharge part 103.
As a result, a fraudulent instrument such as a wire is inserted from the medal payout opening provided on the lower front portion of the front door 12, and the fraudulent instrument attempts to access the holding portion 102 of the hopper disk 101 with this fraudulent instrument. Even if it is broken, the portion of the hopper disc 101 corresponding to the space between two adjacent holding portions 102 serves as a barrier, and it is possible to prevent access to the holding portion 102 by an unauthorized device.

Further, when the driving state of the hopper motor 36 is “constant speed”, the hopper disk 101 rotates clockwise at a constant speed. At this time, the medals held in the respective holding portions 102 are sequentially discharged from the discharging portion 103 at equal intervals.
Further, as shown in FIG. 18, when the drive signal of the hopper motor 36 changes from on to off, the drive state of the hopper motor 36 gradually decreases from "constant speed" and then "stops".
In FIG. 18, a portion where the line indicating the driving state of the hopper motor 36 is diagonally downward to the right indicates that the rotation of the drive shaft of the hopper motor 36 is gradually decelerated.

As described above, in the hopper motor 36 using the DC motor, the rotation of the drive shaft is gradually decelerated when the drive signal changes from on to off.
Then, the last ejected medal is ejected from the ejector 103 by passing between the fixed shaft 38a and the movable shaft 38b (the ejector 103) and returning the movable shaft 38b to the original position. When this is detected by the payout sensor 37, the main control board 50 turns the drive signal of the hopper motor 36 from ON to OFF.
As a result, the rotation of the drive shaft of the hopper motor 36 is gradually decelerated, and the holding unit 102 that holds the first ejected medal in the next payout process is located between the first position and the second position. Then, the rotation of the hopper disc 101 is stopped.

Further, as shown in FIG. 18, when the drive signal of the hopper motor 36 is turned from ON to OFF, the main control board 50 sends a payout start command to the sub control board 80. This payout start command is a command indicating that the main control board 50 has started the payout process.
On the other hand, when the sub-control board 80 receives the payout start command, the sub-control board 80 starts the process related to the output of the payout sound. After that, the output of the payout sound from the speaker 22 is started.

Further, as shown in FIG. 18, when the main control board 50 turns the drive signal of the hopper motor 36 from ON to OFF, thereafter, the main control board 50 transmits a payout end command to the sub control board 80. This payout end command is a command indicating that the main control board 50 has finished the payout process.
On the other hand, when the sub control board 80 receives the payout end command, the sub control board 80 ends the process related to the output of the payout sound. This ends the output of the payout sound from the speaker 22.

Here, the "payout sound" means a sound output from the sub-control board 80 side in accordance with the payout of medals. As the payout sound, for example, a sound such as “plururu” can be output from the speaker 22.
Further, the “process related to output of payout sound” includes a series of processes such as a process of selecting a sound to be output, a process of selecting a channel to output the selected sound, and a process of outputting the selected sound from the speaker 22. It is meant. By executing this series of processing, the payout sound is actually output from the speaker 22.

When the main control board 50 turns on the drive signal of the hopper motor 36, the main control board 50 transmits a payout start command to the sub control board 80, and when the sub control board 80 receives the payout start command, the sub control board 80 performs a process related to the output of the payout sound. By starting, the output of the payout sound from the speaker 22 can be started before the first ejected medal is ejected from the ejecting unit 103.

Further, when the main control board 50 turns off the drive signal of the hopper motor 36, the main control board 50 sends a payout end command to the sub control board 80, and when the sub control board 80 receives the payout end command, the sub control board 80 performs processing related to output of payout sound. When the discharging of the medals from the discharging unit 103 is stopped by ending the above, the output of the payout sound from the speaker 22 can be ended.
As a result, it is possible to give the player the impression that the payout of the medal and the payout sound are synchronized.

FIG. 19 is a diagram showing the relationship between the operation of the main control board 50, the driving state of the hopper motor 36, the detection states of the payout sensors 37 a and 37 b, and the timing of ejecting medals from the ejecting unit 103.
When a winning combination with a payout is won, the main control board 50 sets the payout number data in a predetermined storage area of the RWM 53 and turns on the drive signal of the hopper motor 36.
For example, when a winning combination of 10 coins is paid out and 10 medals are paid out, "10" is set as payout amount data in a predetermined storage area of the RWM 53.
That is, when paying out “N” medals (N≧1), “N” is set as payout number data in a predetermined storage area of the RWM 53.

Further, when the drive signal of the hopper motor 36 is turned on, the hopper motor 36 "starts" (starts driving) from the "stopped" state, goes through "acceleration", and reaches "constant speed".
At the end of one payout process, the holding unit 102 that holds the first ejected medal in the next payout process is stopped between the first position and the second position. At the start of, the hopper motor 36 reaches the "constant speed" by the time the holding unit 102 holding the first ejected medal reaches the first position.
That is, the stop position of the holding unit 102 holding the first ejected medal is set so that the hopper motor 36 reaches the “constant speed” by the time the holding unit 102 holding the first ejected medal reaches the first position. doing.

Then, after the hopper motor 36 reaches “constant speed” from “stop” through “acceleration”, the holding unit 102 that holds the first ejected medal reaches the first position, so that the first ejected The medals are surely ejected from the ejecting unit 103.
Furthermore, at the timing of (a) in FIG. 19, both the payout sensors 37a and 37b are off.
The timing (a) in FIG. 19 corresponds to the state (a) in FIG. 7 in the first embodiment (C).

Further, in the sixth embodiment, unlike the first embodiment (C), the payout sensor 37a is set to low active. That is, the payout sensor 37a is set so that the state where the movable piece 39a is detected is turned off and the state where the movable piece 39a is not detected is turned on.
On the other hand, the payout sensor 37b is set to high active as in the first embodiment (C). That is, the payout sensor 37b is set to be turned off when the movable piece 39a is not detected and turned on when the movable piece 39a is detected.
Therefore, in the sixth embodiment, at the timing of (a) in FIG. 19, both the payout sensors 37a and 37b are turned off.
Note that, in the sixth embodiment, the payout sensor 37a is set to low active and the payout sensor 37b is set to high active. The waveform of turns on and off.

Further, at the timing of (b) in FIG. 19, the medal pushes the movable shaft 38b to move the movable shaft 38b, so that the payout sensor 37a is turned on and the payout sensor 37b is turned off.
The state (b) in FIG. 19 corresponds to the state (b) in FIG. 7 in the first embodiment (C).
Furthermore, at the timing of (c) in FIG. 19, the distance between the fixed shaft 38a and the movable shaft 38b becomes larger than the diameter of the medal, and the payout sensor 37a is in the on state and the payout sensor 37b is in the on state. Become. At this time, medals are ejected from between the fixed shaft 38a and the movable shaft 38b (the ejection portion 103).
The state (c) in FIG. 19 corresponds to the state (c) in FIG. 7 in the first embodiment (C).

Further, at the timing of (d) in FIG. 19, the movable shaft 38b is being urged by the spring 39b to return to the original position, the payout sensor 37a is in the on state, and the payout sensor 37b is in the off state. Becomes
The state (d) in FIG. 19 corresponds to the state (d) in FIG. 7 in the first embodiment (C).
Further, at the timing (e) in FIG. 19, the movable shaft 38b is biased by the spring 39b to return to the original position, and the payout sensors 37a and 37b are both turned off. At this time, the main control board 50 determines that one medal has been ejected, and updates the payout number data.
The state (e) in FIG. 19 corresponds to the state (a) in FIG. 7 in the first embodiment (C).

When paying out “N” medals, (a) to (e) in FIG. 19 are repeated until it is determined that the “N” medal has been ejected.
When determining that the “N”th medal has been ejected, the main control board 50 turns off the drive signal of the hopper motor 36.
When the drive signal for the hopper motor 36 is turned off, the hopper motor 36 goes through "deceleration" and then "stops".
As a result, the payout process of “N” medals is completed.

FIG. 20 is a flowchart showing the flow of payout processing in the sixth embodiment.
In the payout process by the main control board 50, first, in step S101, payout amount data is set. This process is a process of storing payout amount data in a predetermined storage area of the RWM 53 of the main control board 50. For example, when paying out “N” medals (N≧1), “N” is stored as the payout amount data. Then, the process proceeds to the next step S102.

In step S102, the main control board 50 turns on the drive signal of the hopper motor 36. When the drive signal of the hopper motor 36 is turned on, the hopper motor 36 is started. Then, the process proceeds to the next step S103.
In step S103, the main control board 50 determines whether or not the payout sensor 37a is on. As described above, in the sixth embodiment, the payout sensor 37a is set to low active, and the state in which the movable piece 39a is not detected (the state in which the movable shaft 38b is pushed by the medal and moved) is turned on. Is set to be.

If “Yes” in the step S103, the process proceeds to the next step S104, and the main control board 50 determines whether or not the payout sensor 37b is off. If "Yes" in the step S104, the process proceeds to the next step S105. On the other hand, if “No” in the step S104, an error occurs.
Here, if the payout sensor 37a is already turned on when the payout sensor 37a is turned on, the result is "No" in step S104. In this case, it is possible that the ejection unit 103 is clogged with medals (medal clogging error). Further, when a medal jam error occurs, the error continues until the jammed medal is removed (the cause of the error is eliminated) and the reset switch is operated. Then, if the clogged medal is removed and the reset switch is operated, the error is released.

Although not shown in the flowchart of FIG. 20, if “No” continues for a predetermined time in step S103 (the predetermined time has passed with “No”), an error occurs. In this case, it is possible that the medals in the hopper 35 are empty (hopper empty error). When a hopper empty error occurs, the error continues until the hopper 35 is replenished with medals (the cause of the error is removed) and the reset switch is operated. When the hopper 35 is replenished with medals and the reset switch is operated, the error is released.
In step S105, the main control board 50 again determines whether or not the payout sensor 37a is on. Here, if "Yes" in the step S105, the process proceeds to the next step S106. On the other hand, if "No" in step S105, an error occurs, as in the case of "No" in step S104.

In step S106, the main control board 50 determines whether or not the payout sensor 37b is turned on. Then, if “Yes” in the step S106, the process proceeds to the next step S107, and the main control board 50 determines again whether or not the payout sensor 37a is turned on. Here, if “Yes” in the step S107, the process proceeds to the next step S108. On the other hand, if “No” in step S107, an error occurs, as in the case of “No” in step S104 or S105.

When the processing proceeds to step S108, the main control board 50 determines whether or not the payout sensor 37b is off. Then, if “Yes” in the step S108, the process proceeds to the next step S109, and the main control board 50 determines whether or not the payout sensor 37a is off. If “Yes” in the step S109, the process proceeds to a step S110, and the main control board 50 determines whether or not the payout sensor 37b is off.
If “Yes” in the step S110, the process proceeds to the next step S111. On the other hand, if “No” in step S110, an error occurs, as in the case of “No” in step S104, S105, or S107.

In step S111, the main control board 50 updates the payout amount data. This process is a process of subtracting “1” from the payout amount data stored in the predetermined storage area of the RWM 53 and storing the subtracted data as new payout amount data.
In the next step S112, the main control board 50 determines whether or not the payout amount data is "0". Here, if “Yes” in the step S112, the process proceeds to the next step S113, and the main control board 50 turns off the drive signal of the hopper motor 36. When the drive signal for the hopper motor 36 is turned off, the hopper motor 36 stops. Then, the payout process according to this flowchart is completed. On the other hand, if “No” in the step S112, the process returns to the step S103. As a result, the next medal will be paid out. Then, the process of returning from step S112 to S103 is repeated until the payout amount data becomes "0".

Here, the medals ejected from the ejecting unit 103 are normally guided to a medal tray through a passage called a medal chute.
However, rarely, the medals ejected from the ejection unit 103 may hit the inner wall of the medal chute and bounce back to return to the ejection unit 103. At this time, the bounced medal may hit the medal that is about to be ejected next from the ejecting unit 103, and may push back the medal that is about to be ejected.

Therefore, in the sixth embodiment, as in steps S103 to S110 in the flow chart of the payout process in FIG. 20, it is determined whether the payout sensors 37a and 37b are turned on/off repeatedly in the order of “payout sensor 37a”→“payout sensor 37b”. To do.
This makes it possible to detect an error such that the medal being ejected from the ejecting unit 103 is pushed back.

For example, it is assumed that one medal is about to be ejected, the movable shaft 38b moves by pushing the movable shaft 38b, and the payout sensor 37a is in the on state and the payout sensor 37b is in the off state. (Timing (b) in FIG. 19). At this time, it is assumed that the medal paid out before this medal bounces and hits the medal, the medal is pushed back, and the payout sensor 37a is turned off. In this case, the result of step S105 in FIG. 20 is "No", which is an error.
Further, for example, it is assumed that the medal is pushed back at the timing of (c) in FIG. 19 and the payout sensor 37a is turned off. In this case, “No” is obtained in step S107 of FIG. 20, and an error occurs.

<Modification of Sixth Embodiment>
Although the sixth embodiment of the present invention has been described above, the present invention is not limited to the contents described above, and various modifications such as the following are possible.
(1) In the sixth embodiment, eight holding portions 102 are provided on the hopper disc 101, but the number of holding portions is not limited to eight, and the size of the hopper disc 101 may be, for example, five, six, or ten. It can be set appropriately according to the size.
(2) In the sixth embodiment, the hopper disc 101 is formed in a disc shape, but the present invention is not limited to this, and the hopper disc 101 may be formed in a sprocket shape, for example. That is, the holding unit 102 is not limited to the circular hole shape as long as it can hold medals.

(3) In the sixth embodiment, the rotation direction of the hopper disc 101 during the medal payout process is clockwise. However, the present invention is not limited to this. For example, the hopper disc 101 rotates counterclockwise and the holder 102 The medals held at may be sequentially ejected from the ejecting unit 103.
(4) In the sixth embodiment, a DC motor (direct current motor) is used as the hopper motor 36, but the present invention is not limited to this, and a stepping motor may be used as the hopper motor 36, for example.

(5) The flow of the payout process in the sixth embodiment is not limited to the flow shown in the flowchart of FIG. 20, and may be the flow shown in the flowchart of FIG. 21, for example. Even with such a payout processing flow, medal discharge can be detected. However, in such a payout process flow, it is not possible to detect an error in which the medal that is about to be ejected next is pushed back by the medal that has rebounded from the inner wall of the medal shoot.
20 and 21, the same step numbers are assigned to the processes having the same contents.
(6) The various modifications shown in the first to sixth embodiments and the first to sixth embodiments are not limited to being carried out alone, but may be carried out in an appropriate combination.

<Seventh Embodiment>
The present invention relates to the arrangement of the main control board 50 mounted inside the cabinet 13 and the sub-control board 80 mounted on the back surface of the front door 12.
FIG. 22 is a side sectional view of the slot machine 10 with the front door 12 closed, and is a diagram for explaining the positional relationship between the main control board 50 and the sub control board 80.

The housing of the slot machine 10 includes a box-shaped cabinet 13 having an opening on the front side, and a front door 12 attached so that the opening of the cabinet 13 can be opened and closed.
Further, the cabinet 13 is configured in a box shape having an opening on the front side by assembling a bottom plate 13a, a back plate 13b, a right side plate, a left side plate, a top plate, and the like.
Furthermore, a medal payout device 15 is arranged below the inside of the cabinet 13 (on the bottom plate 13a). The medal payout device 15 is for paying out medals, and includes a hopper 35 for storing medals, a hopper disk 101 provided at the bottom of the hopper 35, and a hopper motor 36 for rotating the hopper disk 101. I have it.

Further, inside the cabinet 13, above the medal payout device 15, a plate-shaped reel base 110 supported by the back plate 13b, the right side plate, and the left side plate is provided. A display device 14 is arranged.
Further, the symbol display device 14 includes a square frame-shaped reel frame 14a, and three reels 31 are arranged in parallel inside the reel frame 14a.

Furthermore, a motor 32 is connected to the center of rotation of each reel 31, each motor 32 is fixed to a reel bracket, and each reel bracket is supported by a reel frame 14a.
Further, a transparent reel board case 121 is arranged on the reel frame 14a, and the reel control board 120 is accommodated in the reel board case 121. The reel control board 120 controls driving of the three motors 32.

A transparent main board case 56 is arranged above the symbol display device 14 inside the cabinet 13. More specifically, the main board case 56 is fixed to the front side of the back plate 13b of the cabinet 13 (the inner side of the housing) at a position above the symbol display device 14. The main control board 50 is housed in the main board case 56.
The main control board 50 controls the progress of the game and includes an input port 51, an output port 52, a RWM 53, a ROM 54, a main CPU 55, and the like. Further, on the main control board 50, via the input port 51 or the output port 52, the bet switch 40, the start switch 41, the stop switch 42, the symbol display device 14, the medal payout device 15, the reel control board 120, the sub control board. 80 and the like are electrically connected.

Further, the front door 12 is attached so as to open and close the opening of the cabinet 13 so as to cover the opening on the front side of the cabinet 13. More specifically, the left side portion of the front door 12 is attached to the front side of the left side plate of the cabinet 13 via a hinge. Then, by rotating the front door 12 about this hinge, the front side opening of the cabinet 13 can be opened and closed.

A transparent display window is provided at the center of the front door 12. This display window is arranged at a position corresponding to the front of the symbol display device 14. Then, the player can visually recognize each of the three symbols attached to each reel 31 of the symbol display device 14 through the display window.
On the front side (player side) of the front door 12 and below the display window, a bet switch 40, a start switch 41, a stop switch 42, a settlement switch 43, a medal slot 47, etc. are arranged. ..

Furthermore, in the lower part of the front side (player side) of the front door 12, a medal payout opening through which medals paid out from the medal payout device 15 pass, and a medal paid out from the medal payout opening are received. The medal tray is arranged.
Further, an effect lamp 21, a speaker 22, an image display device 23, and the like are arranged above the front side (player side) of the front door 12.

A transparent sub-board case 87 is arranged above the back surface of the front door 12. More specifically, the sub-board case 87 is fixed to the back side of the front door 12 (the inner side of the housing), above the symbol display device 14, and at the position corresponding to the back side of the image display device 23. ing. The sub control board 80 is housed in the sub board case 87.
The sub-control board 80 controls the effect, and includes an input port 81, an output port 82, a RWM 83, a ROM 84, a sub CPU 85, an electrolytic capacitor 86, and the like. Further, the effect lamp 21, the speaker 22, the image display device 23, the main control board 50, and the like are electrically connected to the sub control board 80 via the input port 81 or the output port 82. Then, the sub-control board 80 determines, based on the control command received from the main control board 50, what kind of effect should be output at what timing, and according to the decision, the effect lamp 21, the speaker 22, and the like. The output of the image display device 23 is controlled.

As described above, the main board case 56 is arranged in the cabinet 13 above the symbol display device 14, and the main control board 50 is housed in the main board case 56.
Further, on the back surface of the front door 12, above the symbol display device 14, a sub-board case 87 is arranged, and in this sub-board case 87, a sub-control board 80 is housed.
Then, as shown in FIG. 22, when the front door 12 is closed, the main control board 50 and the sub control board 80 are arranged to face each other.
Further, the distance between the main control board 50 and the sub control board 80 when the front door 12 is closed is set to be wider than the width of the reel control board 120 in the depth direction.

Here, an electrolytic capacitor 86 for storing electricity is arranged on the sub control board 80. The electrolytic capacitor 86 is filled with an electrolytic solution. If the electrolytic capacitor 86 on the sub-control board 80 bursts due to a problem, the filled electrolytic solution may be scattered. At this time, if the electrolytic capacitor 86 on the sub control board 80 is arranged at a position facing the main CPU 55 on the main control board 50, when the electrolytic capacitor 86 bursts due to a malfunction, the scattered electrolytic solution is It may adhere to the main CPU 55 and cause the main CPU 55 to malfunction. Further, the main CPU 55 may be damaged by the shock when the electrolytic capacitor 86 bursts.

Therefore, in the seventh embodiment, the electrolytic capacitor 86 is arranged on the sub-control board 80 at a position other than the position facing the main CPU 55.
As a result, even if the electrolytic capacitor 86 bursts due to a malfunction and the electrolytic solution scatters, the scattered electrolytic solution can be prevented from adhering to the main CPU 55, and thus the main CPU 55 does not malfunction. be able to. Further, it is possible to prevent the main CPU 55 from being damaged by the impact when the electrolytic capacitor 86 bursts.
Further, when the electrolytic capacitor 86 on the sub control board 80 is arranged at a position facing the main CPU 55 on the main control board 50, noise from the electrolytic capacitor 86 may cause the main CPU 55 to malfunction. By disposing the electrolytic capacitor 86 on the control board 80 at a position other than the position facing the main CPU 55 on the main control board 50, it is possible to prevent the main CPU 55 from malfunctioning due to noise from the electrolytic capacitor 86. You can

FIG. 23A shows the positional relationship between the main CPU 55 on the main control board 50 and the electrolytic capacitor 86 on the sub control board 80 when the slot machine 10 is viewed from the front with the front door 12 closed. It is a figure which shows Example 1.
In FIG. 23A, a circle indicated by a broken line is a projection of the electrolytic capacitor 86 on the sub control board 80 on the main control board 50.

In the example 1 shown in FIG. 23A, the number of the electrolytic capacitors 86 on the sub control board 80 is one, and the electrolytic capacitors 86 are arranged above the main CPU 55 on the main control board 50 in the vertical direction and in the horizontal direction. It is arranged on the left side of the main CPU 55 on the control board 50.
In this way, by disposing the electrolytic capacitors 86 on the sub control board 80 at different positions in the vertical direction and the horizontal direction with respect to the main CPU 55 on the main control board 50, The position of the electrolytic capacitor 86 may be a position other than the position facing the main CPU 55 on the main control board 50.

<Modification of Seventh Embodiment>
Although the seventh embodiment of the present invention has been described above, the present invention is not limited to the contents described above, and various modifications such as the following are possible.
(1) The number of electrolytic capacitors 86 on the sub-control board 80 is not limited to one, and may be two as shown in FIG. 23(b), for example.
FIG. 23B shows the positional relationship between the main CPU 55 on the main control board 50 and the electrolytic capacitor 86 on the sub control board 80 when the slot machine 10 is viewed from the front with the front door 12 closed. It is a figure which shows the example 2.

In FIG. 23B as well, similar to FIG. 23A, the projection of the electrolytic capacitor 86 on the sub control board 80 onto the main control board 50 is indicated by a broken line.
In FIG. 23B, the upper left electrolytic capacitor 86 and the lower right electrolytic capacitor 86 are both arranged at different positions in the vertical and horizontal directions with respect to the main CPU 55 on the main control board 50.
Thus, also in the example 2 of FIG. 23B, the two electrolytic capacitors 86 on the sub control board 80 are arranged at positions other than the positions facing the main CPU 55 on the main control board 50.

(2) The number of electrolytic capacitors 86 on the sub-control board 80 may be four, for example, as shown in FIG.
FIG. 24C shows the positional relationship between the main CPU 55 on the main control board 50 and the electrolytic capacitor 86 on the sub control board 80 when the slot machine 10 is viewed from the front with the front door 12 closed. It is a figure which shows the example 3.
The electrolytic capacitor 86 on the sub control board 80 is projected on the main control board 50 and is shown by a broken line circle, as in FIGS. 23(a) and 23(b).

In FIG. 24C, the sub-control board 80 includes four electrolytic capacitors 86, three of which are located at different positions in the vertical and horizontal directions with respect to the main CPU 55 on the main control board 50. It is arranged. Further, the remaining one electrolytic capacitor 86 is arranged at the same position in the vertical direction as the main CPU 55 on the main control board 50, although the horizontal direction is different.
Even with such an arrangement, the four electrolytic capacitors 86 on the sub control board 80 are located at positions other than the positions facing the main CPU 55 on the main control board 50.

(3) The electrolytic capacitor 86 on the sub control board 80 may be arranged, for example, at a position separated from the main control board 50.
FIG. 24D shows the positional relationship between the main CPU 55 on the main control board 50 and the electrolytic capacitor 86 on the sub control board 80 when the slot machine 10 is viewed from the front with the front door 12 closed. It is a figure which shows the example 4.
The projection of the electrolytic capacitor 86 on the sub-control board 80, which is shown by a broken line circle, is the same as in FIGS. 23(a), (b), and 24(c).

In FIG. 24D, the number of electrolytic capacitors 86 on the sub-control board 80 is one as in FIG. 23A, but unlike FIG. 23A, the electrolytic capacitors on the sub-control board 80 are different. 86 is arranged at a position separated from the main control board 50.
As described above, even when the electrolytic capacitor 86 on the sub control board 80 is arranged at a position separated from the main control board 50, it is arranged at a position other than the position facing the main CPU 55 on the main control board 50. Will be there.

Then, as shown in FIGS. 23(a), (b), 24(c) and (d), the electrolytic capacitor 86 on the sub control board 80 is placed at a position other than the position facing the main CPU 55 on the main control board 50. When the electrolytic capacitor 86 is ruptured due to a malfunction and the electrolytic solution is scattered, the scattered electrolytic solution can be prevented from adhering to the main CPU 55, and the main CPU 55 malfunctions. You can prevent it from happening.

(4) As shown in FIGS. 9 and 10 of the second embodiment, a management information display LED 74 (also referred to as “role ratio monitor”) is arranged on the main control board 50. The management information display LED 74 displays management information such as an advantageous section ratio, a continuous character ratio, and a character ratio.
Further, the "advantageous section ratio" means a ratio of the advantageous section to all the game sections (normal section+standby section+advantageous section), and the "continuous character ratio" is the first to the total number of medals acquired. It means the ratio of the number of medals acquired when the special special accessory (RB) is activated, and the "character ratio" means the ratio of the number of medals acquired when the accessory is operated to the total number of medals acquired.

Then, the electrolytic capacitor 86 on the sub-control board 80 may be arranged at a position other than the position facing the main CPU 55 on the main control board 50 and a position other than the position facing the management information display LED 74. Good.
As a result, even if the electrolytic capacitor 86 ruptures due to a malfunction and the electrolytic solution scatters, the scattered electrolytic solution can be prevented from adhering to the management information display LED 74, and thus the management information displayed on the management information display LED 74 can be managed. You can ensure that the information is not invisible.
Further, it is possible to prevent the management information display LED 74 from being damaged by the impact when the electrolytic capacitor 86 bursts.
(5) The various modifications shown in the first to seventh embodiments and the first to seventh embodiments are not limited to be performed alone, but may be appropriately combined and implemented.

<Eighth Embodiment>
The eighth embodiment relates to a gap between the cabinet 13 and the front door 12 in the lower part of the housing of the slot machine 10.
FIG. 25 is an enlarged side cross-sectional view of the lower front portion of the housing (A portion in FIG. 22) of the slot machine 10 with the front door 12 closed, and the gap between the cabinet 13 and the front door 12 will be described. It is a figure.

As shown in FIG. 25, a lower portion of the cabinet 13 is provided with a first closing portion 13c which projects toward the front door 12 when the front door 12 is closed.
That is, the first closing portion 13c is a plate-like protruding portion that protrudes forward from the front end portion of the bottom plate 13a of the cabinet 13, and when the front door 12 is closed, the protruding direction of the first closing portion 13c. Is in the direction of the front door 12.
The first closing portion 13c is formed in a horizontally long shape from the right end to the left end of the front end portion of the bottom plate 13a of the cabinet 13.
Furthermore, the first closing portion 13c is formed of sheet metal, and is fixed to the front end portion of the bottom plate 13a of the cabinet 13 by screws.

Further, as shown in FIG. 25, at a position below the first closing portion 13c in the lower portion of the front door 12, the second closing portion 12a protruding toward the cabinet 13 when the front door 12 is closed. Is provided.
That is, the second closing portion 12a is a plate-like protruding portion that protrudes rearward from the lower rear surface of the front door 12, and when the front door 12 is closed, the protruding direction of the second closing portion 12a is It is the direction toward the cabinet 13.

Further, the second closing portion 12a is arranged at a position below the first closing portion 13c.
Furthermore, the second closing portion 12a is formed in a horizontally long shape from the right end to the left end of the lower portion of the back surface of the front door 12.
Further, the second closing portion 12a is also formed of sheet metal like the first closing portion 13c, and is fixed to the lower rear surface of the front door 12 by screws.

Further, as shown in FIG. 25, at a position above the first closing portion 13c in the lower portion of the front door 12, the third closing portion 12b protruding toward the cabinet 13 when the front door 12 is closed. Is provided.
That is, like the second closing portion 12a, the third closing portion 12b is a plate-like protruding portion that protrudes rearward from the lower rear surface of the front door 12, and when the front door 12 is closed, The protruding direction of the 3-blocking portion 12b is the cabinet 13 direction.

Further, the third closing portion 12b is formed in a laterally long shape from the right end to the left end of the lower rear surface of the front door 12, similarly to the second closing portion 12a.
Furthermore, unlike the second closing portion 12a, the third closing portion 12b is arranged at a position above the first closing portion 13c.
Further, the third closing portion 12b is also formed of sheet metal like the first closing portion 13c and the second closing portion 12a, and is fixed to the lower rear surface of the front door 12 by screws.

Then, when the front door 12 is closed, the first closing portion 13c is formed between the second closing portion 12a and the third closing portion 12b.
Therefore, when the front door 12 is closed, the gap between the cabinet 13 and the front door 12 in the lower part of the housing is bent as shown in FIG. It becomes the shape. Accordingly, it is possible to prevent an illegal act (got action) of accessing the medal payout device 15 or the like by passing a wire through the gap between the cabinet 13 and the front door 12 into the housing.

A door sensor that detects the opening of the front door 12 is provided on the front side of the left side plate of the cabinet 13. This door sensor is configured by using an optical sensor having a light emitting/receiving unit, and is electrically connected to the main control board 50.
Furthermore, on the front surface side of the left side plate of the cabinet 13, there is provided a detection piece that is movable in the front-rear direction by opening and closing the front door 12. The detection piece is pushed rearward by the front door 12 when the front door 12 is closed, and is pushed forward by being biased by the spring when the front door 12 is opened.

Further, when the front door 12 is closed, the detection piece is pushed rearward by the front door 12 and enters the door sensor. At this time, the door sensor is in the state of detecting the detection piece and is in the off state. That is, the door sensor is set to low active.
On the other hand, when the front door 12 is opened, the detection piece is urged by the spring and pops out forward to come out from the inside of the door sensor. At this time, the door sensor is in a state of not detecting the detection piece and is in an on state.

Then, the main control board 50 determines that the front door 12 is closed when the door sensor is off, and determines that the front door 12 is open when the door sensor is on.
In this way, the opening and closing of the front door 12 detects the opening and closing of the front door 12 by moving the detection piece in the front-rear direction and turning on and off the door sensor.

Further, when the front door 12 is opened from the closed state, the detection piece moves forward from the pushed state, goes out from the state in which it enters the door sensor, and changes the door sensor from the off state to the on state.
The position of the front door 12 when the door sensor first detects the opening of the front door 12 is referred to as a "detection start position".
Further, the time when the door sensor first detects the opening of the front door 12 means the moment when the door sensor changes from the off state to the on state.

In addition, in the eighth embodiment, the first closing portion is provided between the second closing portion 12a and the third closing portion 12b not only when the front door 12 is closed but also when the front door 12 is at the detection start position. 13c is formed.
That is, even at the moment when the front door 12 is opened from the closed state and the door sensor is turned from the off state to the on state, the first closing portion 13c is arranged between the second closing portion 12a and the third closing portion 12b. Is formed.

Therefore, when the front door 12 is opened from the closed state, first, the door sensor is changed from the off state to the on state, and then the first closing portion 13c is removed from between the second closing portion 12a and the third closing portion 12b. It will be.
Then, when the door sensor is turned on, the main control board 50 determines that the front door 12 is open, and transmits a door opening command to the sub control board 80, and the sub control board 80 causes the door opening command. When it receives, the speaker 22 and the image display device 23 and the like inform that the front door 12 is open. As a result, it is possible to notify the clerk of the hall that the front door 12 is open.

Therefore, before the notification that the front door 12 is open is started, the first closing part 13c does not come out between the second closing part 12a and the third closing part 12b, and the front door 12 opens. Even at the position where the notification of the effect is started, since the gap between the cabinet 13 and the front door 12 has a bent shape, the wire is inserted into the housing from the gap between the cabinet 13 and the front door 12. It is possible to prevent an illegal act (gotting act) of accessing the medal payout device 15 or the like by passing it.

In the sixth embodiment, the holding unit 102 that holds the first ejected medal is stopped between the first position and the second position so that the two holding units 102 adjacent to each other in the hopper disc 101 are positioned between the two holding units 102. A corresponding portion can be located in front of the ejection portion 103, whereby it is possible to prevent an illegal act of inserting a wire or the like from the medal payout opening to access the holding portion 102 of the hopper disc 101. As described above, by providing both the configurations of the sixth and eighth embodiments, it is possible to more firmly prevent an illegal act of inserting a wire or the like and accessing the medal payout device 15.

Here, the distance between the first closing portion 13c and the second closing portion 12a is "h1", the distance between the first closing portion 13c and the third closing portion 12b is "h2", and the distance between the second closing portion 12a and the second closing portion 12a. The distance from the third blocking portion 12b is "h3", and the protruding width (depth) of the second blocking portion 12a is "w".
In addition, the diameter of the medal is “d” and the thickness of the medal is “t”.
The general medal size has a diameter of 24.5 to 25.5 mm and a thickness of 1.5 to 2.0 mm.
In the eighth embodiment, the relationship between the distance “h2” between the first closing portion 13c and the third closing portion 12b and the medal thickness “t” is set to satisfy “h2>t”. ing.

Here, when the clerk in the hall opens the front door 12 and replenishes the hopper 35 with medals, there is a case where the medals are dropped on the bottom plate 13a of the cabinet 13.
In particular, since the hopper 35 is replenished with medals through the opening on the front side of the cabinet 13, the medals may be dropped near the front end of the bottom plate 13a of the cabinet 13, that is, near the first closed portion 13c.

At this time, if the setting is made so as to satisfy “h2>t”, even if the front door 12 is closed while the medals have fallen near the first closed portion 13c, the medals dropped near the first closed portion 13c will remain. , Between the first closing portion 13c and the third closing portion 12b. Thereby, the front door 12 can be closed without damaging the front door 12 or the cabinet 13. Further, there is no possibility that the front door 12 cannot be closed because a medal is sandwiched between the first closing portion 13c and the third closing portion 12b.

In the eighth embodiment, the relationship between the protruding width (depth) “w” of the second closing portion 12a and the medal diameter “d” is set to satisfy “w<(d/2)”. Has been done.
By setting so as to satisfy “w<(d/2)”, it is possible to prevent the medal from being placed on the second closing portion 12a.
As a result, it is possible to prevent the front door 12 from being closed while the medals are placed on the second closing portion 12a, and thus the front door is closed by the medals placed on the second closing portion 12a. It is possible to prevent damage to the cabinet 12 and the cabinet 13.

<Modification of Eighth Embodiment>
The eighth embodiment of the present invention has been described above, but the present invention is not limited to the contents described above, and various modifications such as the following are possible.
(1) In the eighth embodiment, the door sensor is configured by using an optical sensor having a light emitting/receiving unit, but is not limited to this, and may be configured by using a proximity sensor, for example.
Even when the proximity sensor is used to form the door sensor, the second closing portion 12a and the third closing portion 12b are not only closed when the front door 12 is closed but also when the front door 12 is at the detection start position. It is configured such that the first closing portion 13c is arranged between the two.

(2) In the eighth embodiment, on the front surface side of the left side plate of the cabinet 13, a detection piece movable in the front-rear direction by opening and closing the front door 12 is provided. When the front door 12 is closed, the detection piece is pushed rearward by the front door 12 and enters the door sensor, and when the front door 12 is opened, the detection piece is urged by a spring to jump forward. So that it goes out from inside the door sensor. However, it is not limited to this.
For example, a door sensor that detects the opening of the front door 12 may be provided on the front side of the left side plate of the cabinet 13, and a detection piece may be provided at a position corresponding to the door sensor on the front door 12. Then, when the front door 12 is closed, the detection piece provided on the front door 12 enters the door sensor, and when the front door 12 is opened, the detection piece provided on the front door 12 goes out from inside the door sensor. You may

(3) In the eighth embodiment, the door sensor is provided on the cabinet 13 side, but not limited to this, it may be provided on the front door 12 side, for example.
(4) In the eighth embodiment, the door sensor is turned off when the detection piece is being detected and is on when the detection piece is not being detected. That is, the door sensor was set to low active. However, it is not limited to this.
For example, contrary to the eighth embodiment, the door sensor may be turned on when the detection piece is being detected and may be off when the detection piece is not being detected. That is, the door sensor may be set to high active.
In this case, the main control board 50 determines that the front door 12 is closed when the door sensor is on, and determines that the front door 12 is open when the door sensor is off. To configure.

(5) In the eighth embodiment, the first closing portion 13c is formed in a horizontally long shape from the right end to the left end of the front end portion of the bottom plate 13a of the cabinet 13. Further, the second closing portion 12a and the third closing portion 12b are formed horizontally long from the right end to the left end of the lower rear surface of the front door 12. However, it is not limited to this.
For example, the first closing portion 13c may be composed of two members, that is, a first member that extends from the right end to the center of the bottom plate 13a and a second member that extends from the center to the left end of the bottom plate 13a. You may comprise from the three members mentioned above.
Similarly to the first closing portion 13c, the second closing portion 12a and the third closing portion 12b may be formed of two members or may be formed of three members.
As described above, the first closing portion 13c, the second closing portion 12a, and the third closing portion 12b are not limited to being configured by one member, and may be configured by a plurality of members.

The first closing portion 13c does not extend from the right end to the left end of the front end portion of the bottom plate 13a of the cabinet 13, and the first closing portion 13c is provided near the right end or the left end of the front end portion of the bottom plate 13a of the cabinet 13, for example. You may have a part which does not have.
Similarly, the lower part of the back surface of the front door 12 may have a part where the second closing part 12a and the third closing part 12b are not provided.
As described above, even if the first closing portion 13c, the second closing portion 12a, and the third closing portion 12b are partly provided, the inside of the housing is emptied from the gap between the cabinet 13 and the front door 12. It is possible to prevent an illegal act of accessing the medal payout device 15 or the like through a wire.
The first closed portion 13c may be a part of the bottom plate 13a of the cabinet 13 or may be a member different from the bottom plate 13a of the cabinet 13.
Similarly, the second closing portion 12a and the third closing portion 12b may be part of the front door 12 or may be separate members from the front door 12.

(6) In the eighth embodiment, when the front door 12 is closed, the first closing portion 13c is formed between the second closing portion 12a and the third closing portion 12b.
At this time, a gap may be formed between the first closing portion 13c and the second closing portion 12a, or the first closing portion 13c and the second closing portion 12a may be in contact with each other.
Similarly, a gap may be formed between the first closing portion 13c and the third closing portion 12b, or the first closing portion 13c and the third closing portion 12b may be in contact with each other.
Further, the entire first blocking portion 13c may be arranged between the second closing portion 12a and the third closing portion 12b, or a part of the first closing portion 13c may be arranged. Good.

Furthermore, in the state where the front door 12 is closed, the first closing portion 13c may be in contact with the back surface of the front door 12 at a position between the second closing portion 12a and the third closing portion 12b. ..
Further, contrary to the eighth embodiment, the first closing portion 13c may be provided on the front door 12 side, and the second closing portion 12a and the third closing portion 12b may be provided on the cabinet 13 side.
That is, the first closing portion 13c protruding from the lower rear surface of the front door 12 toward the cabinet 13 is provided, and the first closing portion 13c at the front end portion of the bottom plate 13a of the cabinet 13 is directed toward the front door 12 from a position below the first closing portion 13c. The protruding second closing portion 12a may be provided, and the third closing portion 12b protruding toward the front door 12 from a position above the first closing portion 13c at the front end of the bottom plate 13a of the cabinet 13 may be provided.

(7) In the eighth embodiment, the relationship between the distance “h2” between the first closing portion 13c and the third closing portion 12b and the medal thickness “t” is set to satisfy “h2>t”. ..
However, the present invention is not limited to this, and may be set so as to satisfy “h2<t”, for example.
If the setting is made so as to satisfy “h2>t”, when the front door 12 is closed in a state where the medals fall near the first closing portion 13c, the medals falling near the first closing portion 13c become the third closing portion. It hits the rear end of 12b and is pushed into the cabinet 13. Thereby, the front door 12 can be closed without damaging the front door 12 or the cabinet 13. Further, there is no possibility that the front door 12 cannot be closed because a medal is sandwiched between the first closing portion 13c and the third closing portion 12b.

(8) In the eighth embodiment, the relationship between the protruding width (depth) “w” of the second closing portion 12a and the medal diameter “d” is set to satisfy “w<(d/2)”. did.
However, the present invention is not limited to this, and may be set to satisfy, for example, “(d/2)<w<d”.
By satisfying “(d/2)<w”, it becomes possible to place a medal on the second closed portion 12a. Further, by satisfying “w<d”, even if the front door 12 is closed while a medal is placed on the second closing portion 12a, the front closing door 12a is closed before the front door 12 is closed. Since the placed medals hit the front end of the cabinet 13, the front door 12 does not close.
As a result, it is possible for the clerk in the hall to know that the medals are placed on the second closing portion 12a, and in turn, the medals placed on the second closing portion 12a are sent to the clerk in the hole. The front door 12 can be closed by removing it.

(9) The relationship between the protruding width (depth) "w" of the second closing portion 12a and the medal diameter "d", and the distance "h1" between the first closing portion 13c and the second closing portion 12a and the medal The relationship with the thickness “t” may be set so as to satisfy “(d/2)<w” and “h1<t”.
As described above, by satisfying “(d/2)<w”, the medal can be placed on the second closing portion 12a. Further, by satisfying “h1<t”, even if the front door 12 is closed while a medal is placed on the second closing portion 12a, the front closing door 12a is closed before the front door 12 is closed. Since the placed medals hit the front end of the first closing portion 13c, the front door 12 does not close.
As a result, it is possible for the clerk in the hall to know that the medals are placed on the second closing portion 12a, and in turn, the medals placed on the second closing portion 12a are sent to the clerk in the hole. The front door 12 can be closed by removing it.

(10) The relationship between the protruding width (depth) "w" of the second closing portion 12a and the diameter of the medal "d", and the distance "h1" between the first closing portion 13c and the second closing portion 12a and the medal The relationship with the thickness “t” may be set so as to satisfy “d<w” and “h1>t”.
By satisfying “d<w”, the entire medal can be placed on the second closing portion 12a. That is, the medal can be placed on the second closed portion 12a without a part of the medal protruding from the second closed portion 12a. Further, by satisfying “h1>t”, the medal can be inserted between the first closing portion 13c and the second closing portion 12a.

Therefore, when the front door 12 is closed with the medal placed on the second closing portion 12a, the front door 12 is closed with the medal being housed between the first closing portion 13c and the second closing portion 12a. It will be. Thereby, the front door 12 can be closed without damaging the front door 12 or the cabinet 13. Further, the medal placed on the second closing portion 12a does not hit the first closing portion 13c or the front end portion of the cabinet 13 to prevent the front door 12 from closing.
(11) The various modifications described in the first to eighth embodiments and the first to eighth embodiments are not limited to be performed alone, but may be appropriately combined and performed.

<Ninth Embodiment>
The ninth embodiment relates to stop control of the reels 31 on the main control board 50 side and control of output of effects on the sub control board 80 side.
FIG. 26(a) is a diagram showing types of special roles (features) and ending conditions, and FIG. 26(b) is a diagram showing types of gaming states and a prescribed number of each gaming state. (C) is a diagram showing a table of numbers of internal drawing and advantageous section drawing in setting 1.

As shown in FIG. 26(a), in the ninth embodiment, BB (first-class accessory continuous operation device; first-class big bonus) and RB (first-class special accessory) as special roles (features). It has three features: a regular bonus) and an MB (second class accessory continuous operation device; second class big bonus).
Here, BB is a device capable of continuously operating RB. That is, during the BB game, the RB game is continuously executed. In addition, during the RB game, the winning probability of the small winning combination becomes high. Furthermore, when the payout number of medals during the RB game exceeds 100, the RB game is finished. Further, when the number of paid-out medals during the BB game exceeds 250, the BB game ends.

The MB is a device that can continuously operate CBs (second-class special effects). That is, during the MB game, the CB game is continuously executed. Furthermore, during the CB game, regardless of the result of the lottery by the role lottery means 61, all the small wins are won, and the stop switch 42 is operated for a specific reel 31 (for example, the left reel 31). The time from when the reel 31 is stopped until the reel 31 is stopped is within 75 ms (the maximum number of moving frames is 1 frame). Further, the CB game is finished in one game, and when the payout number of medals in the MB game exceeds 14, the MB game is finished.

Further, as shown in FIG. 26B, in the ninth embodiment, seven gaming states are provided: non-RT, RT, inside RB, inside BB, RB game, BB game, and MB game. There is. Then, the main control board 50 controls the transition of these gaming states.
Here, the "specified number" means the number of inserted medals for which the start switch 41 can be operated (a game can be started). In the ninth embodiment, the prescribed number in MB is set to "1", and the prescribed number in the game state other than in MB is set to "3".

Further, "RT" means that the type (number) of the condition device (accessory, replay, small win) to be selected by lottery and the winning probability thereof are unique lottery states.
Furthermore, “non-RT” does not mean that it is not included in the concept of RT, but means that the type of condition device that is a lottery target and its winning probability are different from RT.
In any one of the game states, if the RT start condition is satisfied, the next game moves to RT, and if the RT end condition is satisfied at RT, the next game moves to non-RT.

When the special combination is won, the winning information of the special combination is carried over to the next game until the symbol combination corresponding to the selected special combination stops on the activated line.
And, the game which is not won the special part is called "non-inside", and the special part was won, but when the symbol combination corresponding to the special part won is not stopped on the activated line, that is, the special part is won. Games that carry over information are called "inside."

In addition, from the moment the stop switch 42 is operated until the reel 31 stops (maximum number of moving frames), the probability that a desired symbol to be stopped and displayed on the active line can be stopped on the active line is Rate (PB)”.
If the stop switch 42 is not operated at an appropriate reel 31 position (at an operation timing at which the target symbol can be stopped on the effective line within the range of the maximum number of moving frames), the target symbol is stopped on the effective line (effective). The fact that the line cannot be pulled in) is called “PB≠1”.
On the other hand, regardless of the position of the reel 31 at the moment when the stop switch 42 is operated (regardless of the operation timing of the stop switch 42), the target symbol can always be stopped (pulled in) on the activated line. It is called “PB=1”.

Also, when the BB is won and the symbol combination corresponding to the BB is stopped on the activated line (BB wins), no medals are paid out in the current game, but the BB game is started from the next game. During the BB game, the RB game is continuously executed, so that the winning probability of the small winning combination becomes high. When the payout number of medals during the BB game exceeds 250, the BB game is ended, and the game state before the shift to the BB game is returned from the next game.
Furthermore, if the BB is won, but the symbol combination corresponding to BB does not stop on the effective line, the winning information of BB is carried over to the next game until the symbol combination corresponding to BB stops on the effective line. A game state in which the winning information of the BB is carried over is referred to as "inside the BB".
The timing of transition to the inside of the BB can be set appropriately. For example, in the game in which the BB is won, after all reels 31 have stopped, the game may be moved to the inside of the BB. In the game in which the BB is won, the game is not moved to the inside of the BB and the inside of the BB is played in the next game. You may move in.

Also, when the RB is won and the symbol combination corresponding to the RB is stopped on the activated line (RB wins), no medals are paid out in the current game, but the RB game is started from the next game. During the RB game, the chance of winning a small winning combination increases. When the payout number of medals during the RB game exceeds 100, the RB game is ended, and the game state before the shift to the RB game is returned from the next game.
Furthermore, if the RB is won, but the symbol combination corresponding to the RB does not stop on the activated line, the winning information of the RB is carried over to the next game until the symbol combination corresponding to the RB stops on the activated line. A game state in which the winning information of the RB is carried over is called "inside RB".
The transition timing to the inside of the RB can be appropriately set in the same manner as the transition timing to the inside of the BB. For example, in the game which is won the RB, after all reels 31 are stopped, the game may be moved to the inside of the RB, and in the game which is won the RB, the game is not moved to the inside of the RB, and the inside of the RB is played in the next game. You may move in.

If MB is won and the symbol combination corresponding to MB is stopped on the activated line (MB wins), no medals are paid out in the current game, but the MB game is started from the next game. During the MB game, the CB game is continuously executed. Then, when the payout number of medals during the MB game exceeds 14, the MB game is ended, and the game state before the shift to the MB game is returned from the next game.

Furthermore, if the MB is won, but the symbol combination corresponding to the MB does not stop on the activated line, the winning information of the MB is carried over to the next game until the symbol combination corresponding to the MB stops on the activated line. A game state in which the MB winning information is carried over is referred to as "MB inside".
In the ninth embodiment, since the symbol combination corresponding to MB is set to "PB=1", if the MB is won, the symbol combination corresponding to MB in the game this time always stops on the activated line. , It is never inside the MB.

In addition, the condition device (role) of the ninth embodiment is roughly classified into a special role (role), a replay (replay role), and a small role.
Furthermore, as special roles, there are three types of BB, RB, and MB, as replays, there are two types of replay 1 and replay 2, and as minor roles, common bell, left correct answer bell, and middle correct answer bell. , Right correct bell, watermelon, cherry 1 and cherry 2 are included.
In addition, the left correct answer bell, the middle correct answer bell, and the right correct answer bell are collectively referred to as “push order bell”.
Furthermore, the “condition device” operates in correspondence with the winning number determined by the lottery by the combination lottery means 61. When one winning number is determined, one or more condition devices corresponding to the winning number are activated, and the winning flag corresponding to the activated condition device is turned on.

As shown in FIG. 26C, in the ninth embodiment, any one of the winning numbers “0” to “16” is determined by the lottery by the combination lottery means 61 and corresponds to the determined winning number. Any condition device from non-winning to MB is activated.
Each of the two types of replays wins independently and never wins multiple wins with other condition devices (roles).
Further, there are four types of bells: common bell, left correct answer bell, middle correct answer bell, and right correct answer bell, but all of them are won individually and are not won twice with other roles.

Furthermore, the watermelon has a single win and a double win with the BB.
Further, cherry 1 has a single win and a double win with BB, and cherry 2 has a single win, a double win with RB, and a double win with BB. ..
The BB has a single win and a double win with the watermelon, the cherry 1 or the cherry 2, but the RB does not win the single and only wins the cherry 2 redundantly. Only wins a single role and does not win multiple wins with other roles.

The "payout" means the number of medals to be paid out when the symbol combination corresponding to each condition device is stopped (the winning combination is won).
In the ninth embodiment, regarding the left correct answer bell, the middle correct answer bell, and the right correct answer bell, the payouts differ between the prescribed number 3 (game state other than in MB) and the prescribed number 1 (in MB), but other than that, The dividend is the same for the prescribed number 3 and the prescribed number 1.

In addition, the left correct answer bell is a push order bell in which the left first stop is the correct answer push order and the other than the left first stop is the incorrect answer push order. , One medal is paid out in the wrong pressing order, and with the prescribed number 1, 14 medals are paid out in the correct pressing order, and 15 medals are paid out in the wrong pressing order.
Similarly, the middle correct answer bell is a push order bell in which the middle first stop is the correct push order and the other than the middle first stop is the incorrect push order, and the right correct bell is the right first stop is the correct push order. , Pushing bells that are the wrong pushing order except the first stop on the right.
The common bell is a bell that pays out eight medals regardless of the pressing order.

In addition, as described in the first embodiment, the main CPU 55 of the main control board 50 includes a combination lottery means 61 (internal lottery means 61). The winning combination lottery means 61 is for performing lottery of winning numbers. Then, when the winning number is determined by the lottery by the combination lottery means 61, the condition device corresponding to the determined winning number operates.
Further, the lottery of the winning number by the role lottery means 61 (internal lottery means 61) may be referred to as “internal lottery”.
As shown in FIG. 26C, in the ninth embodiment, any one of the winning numbers “0” to “15” is determined by the lottery by the combination lottery means 61. The winning numbers “0” to “15” correspond to the condition devices of “non-winning” to “MB”, respectively. When the winning number is determined, the condition device corresponding to the determined winning number operates.

For example, when the winning number "1" is determined, the condition device of "replay 1" corresponding to the winning number "1" operates. When the winning number “8” is determined, the condition device of “watermelon+BB” corresponding to the winning number “8” operates.
As described in the first embodiment, the role lottery means 61 is based on the random number generating means, the random number extracting means for extracting the random numbers generated by the random number generating means, and the random number value extracted by the random number extracting means. The winning number determining means for determining the winning number is provided, and when the winning number is determined, the condition device corresponding to the determined winning number operates.
Then, for example, in the non-inside and the inside, the random number values extracted by the random number extracting means may be the same, the condition devices that operate may be the same, or even if the random number values extracted by the random number extracting means are the same. The condition device to be used may be different.

Further, as described in the first embodiment, the main CPU 55 of the main control board 50 includes the winning flag control means 62. The winning flag control means 62 controls ON/OFF of the winning flag corresponding to each winning combination, based on the lottery result of the winning numbers by the winning combination lottery means 61.
In the ninth embodiment, a winning flag is provided for each winning combination for all winning combinations. When the winning number is determined by lottery by the winning combination lottery means 61, the winning flag control means 62 turns on the winning flag of the winning combination included in the condition device corresponding to the determined winning number (sets the winning flag). ..

For example, in the non-RT, when the winning number “1” is determined by the lottery by the combination lottery means 61, the winning flag of “Replay 1” included in the condition device of “Replay 1” corresponding to the winning number “1” is set. It is turned on and the other winning flags are turned off.
Similarly, in the non-RT, when the winning number “10” is determined by the lottery by the winning role lottery means 61, “cherry 1” and “BB” included in the condition device of “cherry 1+BB” corresponding to the winning number “10”. The two winning flags “” are turned on, and the other winning flags are turned off.

Also, since the winning information of the winning combinations other than the special winning combinations (BB, RB, MB) is not carried over, even if the winning flag of the winning combination is turned on and the winning flag of the winning combination is turned on, that winning combination is won. The winning flag is turned off at the end of the current game, regardless of whether or not the player wins.
On the other hand, since the winning information of the special roles (BB, RB, MB) is carried over, if the winning combination of the special role is won in the game this time The winning flag is kept on until a prize is won, and when the special part is won, the winning flag is turned off.

For example, in the non-RT, when the winning number "10" is determined by the lottery by the winning role lottery means 61, "cherry 1" and "BB" included in the condition device of "cherry 1+BB" corresponding to the winning number "10". Two winning flags are turned on, but if "BB" is not won in the game this time, regardless of whether "Cherry 1" is won in the game this time, at the end of the game "cherry" The winning flag of "1" is turned off, and the winning flag of "BB" is kept on. In this case, the game is transferred from the next game to the inside of the BB.

Further, for example, in the inside of the BB, when the winning number “9” is determined by a lottery by the role lottery means 61, in addition to the winning flag of the carried-over “BB”, “cherry” corresponding to the winning number “9” is added. The winning flag of "cherry 1" included in the condition device of "1" is turned on. That is, the two winning flags "cherry 1" and "BB" are turned on.
Therefore, in the non-RT, when the winning number “10” is determined in the lottery means 61 by lottery (double winning of “Cherry 1+BB”), and when the winning number is “9” in the BB, the winning number “9” is drawn. The status of the winning flag is the same as when the winning flag is determined (single winning of "cherry 1").

Further, during the MB game, the winning flag control means 62 sets the winning flags of all the small wins (common bell, left correct answer bell, middle correct answer bell, right correct answer bell, watermelon, cherry 1 and cherry 2). turn on. For this reason, although not won by the lottery by the role lottery means 61, the state is the same as when all small wins are won.
For example, in the MB game, when the winning number "0" is determined by the lottery by the role lottery means 61, none of the winning hands is included in the "non-winning" corresponding to the winning number "0". The winning flags of the small wins (7 small wins above) are turned on.
Also, for example, during the MB game, when the winning number "1" is determined by the lottery by the role lottery means 61, the "replay 1" included in the condition device of "replay 1" corresponding to the winning number "1" In addition to the winning flags, the winning flags of all small wins (the above seven small wins) are turned on.

Further, as described in the first embodiment, the main CPU 55 of the main control board 50 includes the reel control means 65, and the reel control means 65 includes a plurality of stop position determination tables corresponding to ON/OFF of the winning flag. Equipped with. Each stop position determination table defines the stop position of the reel 31 with respect to the position of the reel 31 at the moment when the stop switch 42 is operated.
When the winning number is determined by lottery by the winning combination lottery means 61 and the winning flag control means 62 controls the winning flag of the winning combination included in the condition device corresponding to the determined winning number, the reel control means 62. 65 selects the stop position determination table corresponding to ON/OFF of the winning flag.

Then, when the stop switch 42 is operated, the stop position of the reel 31 corresponding to the stop switch 42 is determined based on the selected stop position determination table and the position of the reel 31 at the moment when the stop switch 42 is operated. The reel 31 is determined and controlled so that the reel 31 is stopped at the determined position.
Further, the stop position determination table selected when the winning flag of Replay 1 is on and the winning flags other than Replay 1 are off are such that the symbol combination corresponding to Replay 1 stops on the activated line, and The stop position of each reel 31 is set so that the symbol combination corresponding to the winning combination other than Replay 1 does not stop on the activated line.

Furthermore, the stop position determination table selected when the winning flag of the left correct answer bell is on and the winning flag other than the left correct answer bell is off is when the stop switch 42 is operated at the first left stop. , The symbol combination for paying out 8 medals is stopped on the activated line, and when the stop switch 42 is operated except for the first left stop, the symbol combination for paying out 1 medal is stopped on the activated line. Thus, the stop position of each reel 31 is determined.

In addition, the column of “internal lottery storage number” in FIG. 26C shows the number of each winning number in each gaming state. Dividing the number of internal lottery units by “65536” gives the winning probability.
For example, since the number of the winning number “4” in the non-RT is “3000”, the winning number “4” is determined by the lottery means 61 in the non-RT, and the “left” corresponding to the winning number “4”. The probability that the condition device of "correct answer bell" will operate is "3000/65536".

In addition, in the column of "number of internal lottery units" of FIG. 26C, "*" mark indicates that the advantageous section lottery can be executed.
Here, the “advantageous section” means a game section having a performance related to the instruction function (the instruction function may be activated).
The "instruction function" means a function of displaying (notifying) the "advantageous operation mode" to the player.
Furthermore, the “operation of the instruction function” includes displaying the correct pressing order when the pressing order bell is won.

Furthermore, the “advantageous zone drawing” means a lottery for deciding whether or not to shift to the advantageous zone.
Then, if the player wins the advantageous section and shifts to the advantageous section, it becomes possible to activate the instruction function, and it becomes possible to notify the correct pressing order when the pressing order bell is won.
For example, the number "8000" of the winning number "3"("commonbell") in the non-RT is marked with "*", which is the role lottery means 61 (internal lottery means 61) in the non-RT. When the winning number “3” (“common bell”) is determined in the lottery by, it means that the advantageous section lottery can be executed.

Further, as shown in FIG. 26C, in the non-RT, when the winning number “0” (non-winning) is determined, and the winning numbers “4” to “6” (“left correct answer bell”, “ When it is determined to be “medium correct answer bell” or “right correct answer bell”), the advantageous section drawing is not executed, but in other cases, the advantageous section drawing can be executed.
Furthermore, when the winning numbers “4” to “6” (“right correct answer bell”, “medium correct answer bell”, or “right correct answer bell”) are determined in the RT, RB, and BB. Except for this, when the winning number with the same number as the non-RT is determined, the advantageous section drawing can be executed.

In addition, since the winning information of the BB is carried over inside the BB, when the winning number "9" (independent winning of "Cherry 1") is decided inside the BB, and when the non-RT (non-internal) When the winning number is determined to be “10” (duplicate winning of “Cherry 1+BB”), the on/off state of the winning flag is the same.
In addition, the number of winning numbers "10" (double winning of "Cherry 1 + BB") in non-RT (non-internal) and the number of winning numbers "9" (single winning of "Cherry 1") inside BB And are set to the same "200".
Therefore, when the winning number “9” (independent winning of “Cherry 1”) is determined inside the BB, the advantageous section drawing can be executed.

Further, when the winning number "9" (independent winning of "Cherry 1") is determined inside the RB, the winning flag of "Cherry 1" and the winning flag of "RB" carried over are turned on. ..
In addition, “BB” and “RB” both match in that they are special roles (features), and the winning number “10” (non-internal middle) winning number (double winning of “cherry 1+BB”) The register number and the register number of the winning number "9" (independent winning of "Cherry 1") inside the RB are set to the same "200".
Therefore, even when the winning number "9" (independent winning of "Cherry 1") is determined in the RB, the advantageous section drawing can be executed.

In addition, when the winning number is “12” (double winning of “Cherry 2+RB”) or the winning number “13” (double winning of “Cherry 2+BB”) in non-RT, and when the winning is inside the RB or inside the BB. When the number "11" (single winning of "cherry 2") is determined, the winning flag of "cherry 2" and the winning flag of the special character (feat) are turned on.
Furthermore, the total number of winning numbers "12" (double winning of "Cherry 2 + RB") and winning number "13" (double winning of "Cherry 2 + BB") in non-RT is "300", which is in the RB and BB. This matches the number "300" of the number of the winning number "11" (independent winning of "Cherry 2") in the inside.
Therefore, even when the winning number “11” (independent winning of “Cherry 2”) is determined inside the RB and inside the BB, the advantageous section drawing can be executed.

In addition, the column of the “advantageous section drawing number” of FIG. 26C shows the number of each winning number. If the number of advantageous section lottery units is divided by “16384”, the winning probability is obtained.
For example, in the non-RT, inside the RB or inside the BB, when the winning number “1” (the single winning of “Replay 1”) is determined by the lottery means 61, the probability of winning in the advantageous section lottery is It becomes "20/16384".
In addition, for example, in the non-RT or RT, when the winning number “8” (double winning of “Watermelon+BB”) is determined by the lottery means 61, the probability of winning in the advantageous section lottery is “10000/16384”. It will be.

As described above, in the ninth embodiment, the symbol combination corresponding to MB is set to "PB=1".
Further, as shown in FIG. 26C, in non-RT and RT, MB lottery is performed, but when MB is won, the symbol combination corresponding to MB in the game this time is always stopped on the effective line, so MB From the next game to the MB game without going into the inside.
Further, as shown in FIG. 26(c), during the MB game, a lottery of Replay 1 or Replay 2 is performed, and regardless of the lottery result by the role lottery means 61, all the small wins are duly won. Become.

Therefore, when the winning number "1" (independent winning of "Replay 1") is decided during the MB game, the winning flag of "Replay 1" and all small wins (common bell, right answer bell, middle) The correct answer bell, right correct bell, watermelon, cherry 1, and cherry 2) and the winning flags are turned on.
Similarly, when the winning number "2" (independent winning of "Replay 2") is determined during the MB game, the winning flag of "Replay 2" and the winning flags of all small wins are turned on.

When the winning number "1" (independent winning of "Replay 1") is decided during the MB game, that is, when the winning flag of "Replay 1" and the winning flags of all small wins are turned on. For, the same stop position determination table as when only the winning flag of the left correct answer bell is on is selected. However, during the MB game, the stipulated number is 1 (one piece is inserted), and the payout is different from the non-RT and the like, and 14 or 15 pieces are paid out.
As a result, in the case where the winning number "1" (independent winning of "Replay 1") is determined during the MB game, when the stop switch 42 is operated by the first stop on the left (at the time of a correct pushing order), 14 The symbol combination that is the payout of 15 medals is stopped on the activated line, and when the stop switch 42 is operated other than the left first stop (when the pushing order is incorrect), the symbol combination that is the payout of 15 medals is Stop at the active line.

Similarly, when the winning number "2" (independent winning of "Replay 2") is decided during the MB game, the same stop position determination table as when only the right correct bell winning flag is turned on is selected, and the right At the first stop (when the push order is correct), 14 cards are paid out, and at the time other than the right first stop (when the push order is incorrect), 15 cards are paid out.
Then, in the first game during the MB game, the push order for paying out 14 cards is notified, and in the second game during the MB game, the push order for paying out 15 cards is notified.
As described above, since the ending condition of the MB game is set so that the number of paid-out medals exceeds 14, 29 such medals are paid out during the MB game. You can Further, since the prescribed number is set to "1" during the MB game, the player can obtain 27 medals obtained by subtracting the inserted number "2" from the payout number "29".

Also, in order to inform the player of the pushing order that is advantageous during the MB game, it is necessary to shift to the advantageous section.
Therefore, as shown in FIG. 26(c), in non-RT or RT, the winning of the advantageous section lottery when the winning number "15" (independent winning of "MB") is determined in the lottery by the role lottery means 61 The probability is set to "16384/16384", that is, "100%".

Further, as described in the first embodiment, the main CPU 55 of the main control board 50 includes the effect group number selection means 64. The effect group number selection means 64 is for selecting an effect group number corresponding to the winning number, which number is to be transmitted to the sub-control board 80.
As shown in FIG. 26C, the effect group number corresponding to the winning number is predetermined. Specifically, the production group numbers “0” to “3” are determined corresponding to the winning numbers “0” to “3”, and the production group numbers “4” are corresponding to the winning numbers “4” to “6”. ", and the effect group numbers "5" to "13" are determined corresponding to the winning numbers "7" to "15".
When the winning number is determined by the lottery by the combination lottery means 61, the effect group number selecting means 64 selects the effect group number corresponding to the determined winning number.

Further, as described in the first embodiment, the main CPU 55 of the main control board 50 includes the pushing order instruction number selecting means 63. The pushing order instruction number selecting means 63 is a winning number determined when the winning number corresponding to the pushing order bell (left correct answer bell, middle correct answer bell, right correct answer bell) is determined in the lottery by the role drawing means 61. This is for selecting a pressing order instruction number corresponding to (a number corresponding to the correct pressing order).

Further, as described in the first embodiment, the main CPU 55 of the main control board 50 includes the control command transmitting unit 71. The control command transmitting means 71 transmits to the sub control board 80 information (control command) necessary for an effect output by the sub control board 80.
In the ninth embodiment, the control command transmission means 71 uses the control command as information when the bet switch 40 is operated, information when the start switch 41 is operated, and a push order instruction number (during AT and correct answer press). In addition to the winning number corresponding to the condition device having the order, the production group number, the information when the stop switch 42 is operated, the information of the winning combination, and the like, the gaming state (non-RT, RT) , Inside the RB, inside the BB, inside the RB, inside the BB, inside the MB), the production group number, etc. are transmitted to the sub control board 80.

Thereby, on the side of the sub control board 80, the game state on the side of the main control board 50 and the condition device (excluding the left correct answer bell, the middle correct answer bell, and the right correct answer bell) operating in the hand lottery means 61 are determined. be able to.
On the side of the sub-control board 80, it is possible to determine that the left correct answer bell, the middle correct answer bell, or the right correct answer bell is won depending on the effect group number, but the left correct answer bell, the middle correct answer bell, or the right correct answer bell. It is not possible to determine which of the above was won (the order in which the correct answer was pushed).
Further, during AT, it is possible to notify the correct pressing order by the pressing order instruction number.

In addition, the sub-control board 80 controls the selection and output of effects during the game and the game standby.
The main control board 50 and the sub-control board 80 are electrically connected to each other, and the main control board 50 (control command transmitting means 71) is unidirectional to the sub-control board 80, and information necessary for output of the effect ( Control command).
Like the main control board 50, the sub control board 80 includes an input port 81, an output port 82, a RWM 83, a ROM 84, a sub CPU 85, and the like.
In addition, the effect lamp 21, the speaker 22, the image display device 23, and the like are electrically connected to the sub-control board 80 via the input port 81 or the output port 82.

Furthermore, the sub CPU 85 of the sub control board 80 includes an effect output control unit 91 and the like, and the ROM 84 of the sub control board 80 includes an effect determination table and the like.
Further, the effect determination table is provided with a plurality of effects to be output, and the effect output control unit 91 determines the effect to be output using any of the effect determination tables, and the determined effect. Control to output.
That is, the effect output control means 91 determines what kind of effect is output at what timing based on the control command received from the main control board 50 and any effect determination table, and the determination is made. In accordance with this, the output of the effect lamp 21, the speaker 22, and the image display device 23 is controlled.

FIG. 27 is a diagram showing an effect determination table commonly used for non-RT (non-internal) and RT (non-AT and non-internal), and FIG. 28 is an effect determination table commonly used in RB and BB. FIG.
As shown in FIG. 27, in the ninth embodiment, 18 types of effect patterns from “no effect” to “continuous effect” are provided. In addition, each of the effect patterns from "character effect (lively)" to "continuous effect" defines effects with different contents.
For example, the "confirmed effect" is an effect in which the player can know that the special role has been won, and the "notification effect after the first stop" is after the first stop (after the first stop switch 42 is operated). It is an effect that is output at a timing, the "left first stop effect" is an effect that instructs the left stop switch 42 to be operated first, and the "continuous effect" is continuous over a plurality of games. It is a production that is output.

In addition, the column of "effect pattern distribution unit number" in FIG. 27 shows the distribution unit number of each effect pattern when each effect group number is received. When the number of assigned production patterns is divided by “256”, the selection probability of each production pattern is obtained. In FIG. 27, the name of the corresponding condition device is described below each effect group number.
For example, in the non-RT, when the winning number “1” (single winning of “Replay 1”) is determined by lottery by the role lottery means 61 and the production group number “1” is transmitted, the selection probability of “No production” is It is "128/256", the selection probability of "Character production (lively)" is "20/256", the selection probability of "Conversation production (lively)" is also "20/256", and "Cut-in production" The selection probability of "(strong effect)" is "0/256".

As described above, the control command transmitting unit 71 informs the sub control board 80 of the game state (non-RT, RT, inside RB, inside BB, inside RB, inside BB, inside MB), and Send the production group number.
Then, the effect output control means 91 of the sub control board 80 selects the effect determination table according to the game state based on the information indicating the game status received from the main control board 50, and the selected effect determination table and the main Based on the effect group number received from the control board 50, it is determined which effect pattern the effect is to be output, and the output of the effect lamp 21, the speaker 22 and the image display device 23 is controlled according to the determination.

Here, in the non-RT (non-inside), when the winning number “14” (independent winning of “BB”) is determined by lottery by the role lottery means 61 and the production group number “12” is transmitted, production output The control means 91 selects the production determination table commonly used for non-RT and RT (non-AT) shown in FIG. 27, and places the production group number “12” (single winning of “BB”) in this production determination table. The number is used to determine which production pattern the production is to be output. As shown in FIG. 27, when "BB" alone is won in non-RT, for example, "continuous effect" is selected with a probability of "40/256".

On the other hand, when the winning number “0” (“non-win”) is determined by the lottery means 61 in the inside of the BB and the production group number “0” is transmitted, the production output control means 91, By selecting the effect determination table commonly used in the inside of the RB and the inside of the BB shown in FIG. 28, and using the number in the column of the effect group number “0” (“non-win”) in this effect determination table, which effect is selected Decide whether to output the effect of the pattern. As shown in FIG. 28, at the time of "non-winning" inside the BB, for example, "fixed effect" is selected with a probability of "80/256".
In this way, the production output control means 91 is a non-RT (non-inside) game in which the "BB" is independently won by the role lottery means 61 and the role lottery means 61 is "non-winning" while the BB is inside. An effect to be output is determined using different effect determination tables depending on the game. Therefore, the selection probability of each effect pattern is different.

Further, in the non-RT, when the winning number “14” (independent winning of “BB”) is determined by the lottery by the combination lottery means 61, the winning flag control means 62 causes the winning number “14” on the main control board 50 side. The winning flags of “BB” included in the condition device of “BB” corresponding to “” are turned on, and the other winning flags are turned off. Further, the reel control means 65 selects the corresponding stop position determination table when the winning flag of "BB" is on and the other winning flags are off. This stop position determination table is referred to as a "BB independent stop position determination table".

The "BB independent stop position determination table" is to stop each reel 31 so that the symbol combination corresponding to BB stops on the activated line, and the symbol combination corresponding to the winning combination other than BB does not stop on the activated line. The position is set.
When the stop switch 42 is operated, the reel control means 65 determines the stop switch 42 based on the "BB independent stop position determination table" and the position of the reel 31 at the moment when the stop switch 42 is operated. The stop position of the reel 31 corresponding to is determined, and the reel 31 is controlled to be stopped at the determined position.

Further, when the winning number “0” (“non-win”) is obtained in the lottery means 61 inside the BB, the winning flag control means 62 on the main control board 50 side is carried over to “BB”. The winning flags of are kept on, and the other winning flags are turned off. Further, the reel control means 65 selects the corresponding stop position determination table when the winning flag of “BB” is on and the other winning flags are off. That is, in the non-RT, the same “BB independent stop position determination table” as when the winning combination lottery means 61 alone wins “BB” is selected.
Therefore, when the winning combination lottery means 61 is "non-winning" in the inside of the BB, the same stop control of the reels 31 as when the winning combination lottery means 61 is independently winning "BB" is performed in the non-RT. Further, "the stop control of the same reel 31 is performed" means that when each stop switch 42 is operated in the same manner (pushing order and operation timing), each reel 31 stops at the same position and the same. Means that a stop result is displayed.

In this way, in the non-RT, when the winning combination lottery means 61 alone wins the "BB", and when the winning combination lottery means 61 becomes "non-winning" inside the BB, the main control board 50 side is the same. The stop position of the reel 31 is determined by using the stop position determination table of 1., but on the side of the sub-control board 80, the effect to be output is determined by using a different effect determination table. Therefore, the selection probability of each effect pattern is different.
Thereby, even if the stop control of the reel 31 on the main control board 50 side is the same, different effects can be output on the sub control board 80 side, and the effects can be diversified.
Even if the same control for stopping the reels 31 is performed on the main control board 50 side and the same stop result is displayed, different effects are output on the sub control board 80 side, so that the special winning combination is won. It is possible for the player to guess that the player is playing (inside).

Furthermore, by selecting different production determination tables on the side of the sub control board 80 for the non-RT "BB" single win and the "non-win" inside the BB, the "BB" single non-RT is selected. At the time of winning, an effect determination table having a low probability of selecting a finalized effect (an effect that allows the player to know that the BB has been won) is selected, and at the time of "non-winning" inside the BB, a high probability of selecting a finalized effect is selected. A decision table can be selected.
As a result, it is possible to make it difficult for the player to understand that the player wins "BB" in the game that has won "BB", and the fact that the player has won "BB" in the BB. By making it easy for the player to understand, it is possible to prevent the player from aiming for the winning of "BB", preventing the inside of the BB from continuing forever, and not being disadvantageous to the player.

Further, in the non-RT, when the winning number “8” (duplicate winning of “Watermelon+BB”) is determined by the lottery by the combination lottery means 61 and the production group number “6” is transmitted, the production output control means 91, Select the effect determination table used in both non-RT (non-internal) and RT (non-AT and non-internal) shown in FIG. 27, and the effect group number “6” (“watermelon+BB” duplicate winning) in this effect determination table. ), the number of characters in the column is used to determine which effect pattern the effect is to be output. As shown in FIG. 27, when the “Watermelon+BB” overlap wins in non-RT, for example, the probability of “50/256” is “character effect (lively)”, “conversation effect (lively)”, or “cut-in effect ( "Strong production)" is selected, and "continuous production" is selected with a probability of "30/256".

On the other hand, in the inside of the BB, when the winning number “7” (independent winning of “watermelon”) is determined by the lottery by the combination lottery means 61 and the production group number “5” is transmitted, the production output control means 91. Selects the effect determination table commonly used in the inside of the RB and the inside of the BB shown in FIG. 28, and uses the number in the column of the effect group number “5” (single win of “watermelon”) in this effect determination table. , Which of the effect patterns is to be output is determined. As shown in FIG. 28, when “Watermelon” alone in the BB is elected, for example, with the probability of “73/256”, “Character production (lively)” or “Conversation production (lively)” is selected, and “20” is selected. Continuous production is selected with a probability of "/256".
In this way, the production output control means 91, in the non-RT (non-internal), the game in which the winning combination lottery means 61 wins the "Watermelon + BB" multiple times, and the winning combination lottery means 61 wins the "watermelon" independently in the BB. The effect to be output is determined by using a different effect determination table depending on the played game. Therefore, the selection probability of each effect pattern is different.

In addition, in the non-internal, in order to keep the player's expectation for "BB" winning long by showing the player continuous effects over multiple games, selection of continuous effects at the time of "watermelon + BB" double winning The probability is set high.
On the other hand, inside the BB, if you show the player continuous production over multiple games, the "BB" prize will be delayed and the medal of the player will decrease accordingly. The selection probability of the continuous effect is set to be low, and the selection probability of the fixed effect at the time of "non-win" is set to be high in order to prompt the player to win the "BB" prize at an early stage.
In the BB, the winning probability of each winning combination and the number of coins to be paid out at the time of winning may be set to prevent the number of medals of the player from decreasing, and then the probability of selecting continuous production may be set high.

Further, in the non-RT (non-internal), when the winning number “8” (double win of “Watermelon+BB”) is determined by the lottery means 61, on the main control board 50 side, the winning flag control means 62 is , The two winning flags of “watermelon” and “BB” included in the condition device of “watermelon+BB” corresponding to the winning number “8” are turned on, and the other winning flags are turned off. Further, the reel control means 65 selects the corresponding stop position determination table when the two winning flags of “watermelon” and “BB” are on and the other winning flags are off. This stop position determination table is referred to as a “watermelon+BB overlapping stop position determination table”.

"Watermelon + BB overlapping stop position determination table", each symbol combination corresponding to watermelon or BB can be stopped in the activated line, and the symbol combination corresponding to the combination other than watermelon and BB is not stopped in the activated line, The stop position of the reel 31 is determined.
Then, when the stop switch 42 is operated, the reel control means 65 determines the stop switch based on the “watermelon+BB overlapping stop position determination table” and the position of the reel 31 at the moment when the stop switch 42 is operated. The stop position of the reel 31 corresponding to 42 is determined, and the reel 31 is controlled to stop at the determined position.

Further, when the winning number “7” (single win of “watermelon”) is determined by the lottery means 61 inside the BB, the winning flag control means 62 is carried over on the main control board 50 side. While keeping the winning flag of "BB" on, in addition to that, the winning flag of "watermelon" included in the condition device of "watermelon" corresponding to the winning number "7" is turned on, and "watermelon" and "BB" The winning flags other than "are turned off. As a result, two winning flags of "watermelon" and "BB" are turned on. Further, the reel control means 65 selects the corresponding stop position determination table when the two winning flags of “watermelon” and “BB” are on and the other winning flags are off. That is, in the non-RT, the same "watermelon + BB duplication stop position determination table" as when the winning combination lottery means 61 wins "Watermelon + BB" is selected.

Therefore, when the winning combination lottery means 61 alone wins the "watermelon" in the inside of the BB, the same stop control of the reel 31 as when the winning combination lottery means 61 wins the "watermelon + BB" multiple times in the non-RT is performed. ..
As described above, in the non-RT, when the winning combination lottery means 61 wins the "Watermelon + BB" multiple times and when the winning combination lottery means 61 individually wins the "watermelon" in the BB, the main control board 50 side Although the stop position of the reel 31 is determined using the same stop position determination table, the sub-control board 80 side determines the effect to be output using a different effect determination table. Therefore, the selection probability of each effect pattern is different.

In addition, when you win multiple wins for "Cherry 1 + BB" in non-RT, and when you win single win for "Cherry 1" while inside BB, when you win multiple wins for "Watermelon + BB" in non-RT, Similar to the case where the “watermelon” is independently won, the main control board 50 side determines the stop position of the reel 31 using the same stop position determination table, but the sub control board 80 side sets a different effect determination table. Determine the output to be used. Therefore, the selection probability of each effect pattern is different.

Furthermore, even if you double win "Cherry 2 + BB" or "Cherry 2 + RB" in non-RT, and if you alone win "Cherry 2" in BB or RB, you will get "Watermelon + BB" in non-RT. As in the case of multiple wins and the single win of "watermelon" in the BB, the main control board 50 determines the stop position of the reel 31 using the same stop position determination table. On the board 80 side, a different effect determination table is used to determine the effect to be output. Therefore, the selection probability of each effect pattern is different.
Thereby, even if the stop control of the reels 31 on the main control board 50 side is the same, different effects can be output on the sub control board 80 side, so that the effects can be diversified.

Note that, as shown in FIGS. 27 and 28, the number of assigned allocations of each effect pattern is the same when the “watermelon” is individually won in the non-RT and when the “watermelon” is individually won in the BB. Therefore, the selection probabilities of the effect patterns are the same.
However, when the "Watermelon" is independently won in the non-RT, the corresponding stop position determination table is selected when the "Watermelon" winning flag is on and the other winning flags are off. When a single "watermelon" is won inside the BB, when the two winning flags of "watermelon" and "BB" are on and the other winning flags are off, the corresponding stop position determination table is selected. To do. For this reason, the stop control of the reel 31 is different when the "watermelon" is independently won in the non-RT and when the "watermelon" is individually won in the BB.
In this way, the selection probability of each effect pattern is the same on the sub-control board 80 side when the "watermelon" is independently won in the non-RT and when the "watermelon" is individually won in the BB. The stop control of the reel 31 is different on the main control board 50 side.

As described above, in a plurality of gaming states, the random number values extracted by the random number extraction means of the winning combination lottery means 61 are the same, and the winning numbers determined by the winning number determining means of the winning combination lottery means 61 are the same. Therefore, when the same condition device operates, the stop control of the reel 31 (stop position determination table selected) for each game state is the same, but the selection probability of each effect pattern (selected effect determination table) ) May be different.

Further, in a plurality of game states, the random number values extracted by the random number extraction means of the role lottery means 61 are different, and the winning numbers determined by the winning number determination means of the role lottery means 61 are the same, and the same condition is satisfied. When the device is operated, the stop control of the reel 31 (selected stop position determination table) for each game state is the same, but the selection probability of each effect pattern (selected effect determination table) may be different. ..

Furthermore, in a plurality of game states, the random number values extracted by the random number extraction means of the winning combination lottery means 61 are different, and the winning numbers determined by the winning number determining means of the winning combination lottery means 61 are different, and the same condition device is used. When is operated, the stop control of the reel 31 (selected stop position determination table) for each game state is the same, but the selection probability of each effect pattern (selected effect determination table) may be different.

<Modification of the ninth embodiment>
Although the ninth embodiment of the present invention has been described above, the present invention is not limited to the above-described contents, and various modifications such as the following are possible.
(1) The types of winning combinations, the types of condition devices, the types of gaming states, the prescribed numbers in each gaming state, the payout at the time of winning each winning, the allocation of the internal lottery numbers, and the advantageous section lottery shown in the ninth embodiment. The allocation of numbers, the types of effect patterns, and the allocation of the allocation numbers for each effect pattern are merely examples, and can be appropriately set according to the game content.

(2) In the ninth embodiment, only the table of the number of internal lottery and advantageous zone lottery in setting 1 is shown. However, as setting values, 6 stages from setting 1 to setting 6 are provided, and each setting value has a different internal value. It is possible to provide a table of the numbers of lottery and advantage zone lottery.
(3) In the ninth embodiment, the control command transmission means 71 transmits information indicating the game state and the effect group number to the sub control board 80. As a result, the sub control board 80 determines the game state and the condition device on the main control board 50 side, and selects the effect pattern with a probability according to the game state and the condition device. However, it is not limited to this.
For example, the control command transmitting unit 71 may transmit the winning number determined by the internal drawing to the sub-control board 80, or transmit the information indicating the condition device corresponding to the winning number determined by the internal drawing. Good. Then, on the side of the sub control board 80, the condition device on the side of the main control board 50 may be determined based on the received information indicating the winning number or the condition device.

Further, for example, the control command transmitting unit 71 transmits information indicating the condition device determined by the internal drawing and information on the winning combination to the sub-control board 80. Then, on the side of the sub control board 80, the game state on the side of the main control board 50 may be determined based on the information indicating the condition device and the information on the winning combination.
Furthermore, for example, the sub control board 80 receives information indicating that "BB" is won, but if the information indicating that "BB" is won is not received, the game state on the main control board 50 side is It can be determined that the inside of the BB is in progress.
Then, on the side of the sub control board 80, based on the game state on the side of the main control board 50 judged on the side of the sub control board 80 and the information indicating the production group number, the winning number, and the condition device received from the main control board 50. An effect pattern may be selected.

(4) For example, the control command transmitting means 71 transmits to the sub-control board 80, information indicating ON/OFF of a winning flag corresponding to each winning combination and information of a winning combination. Then, on the side of the sub control board 80, the game state and the condition device on the side of the main control board 50 may be determined based on the information indicating the on/off state of the winning flag and the information on the winning combination.
For example, if the information indicating that the winning flag of "BB" is turned on is received, but the information indicating that "BB" is won is not received, the game state on the main control board 50 side is inside BB. Can be determined.

Further, since the "BB" lottery is not performed inside the BB, when the information indicating that only the "BB" winning flag is turned on is received inside the BB, the internal lottery on the main control board 50 side is performed. Therefore, it can be determined that the winning number "0"("non-winning") has been decided.
Then, based on the game state on the main control board 50 side judged on the sub control board 80 side and the condition device on the main control board 50 side also judged on the sub control board 80 side, the effect pattern on the sub control board 80 side May be selected.

(5) In the ninth embodiment, the "single win" is used to mean that only the non-special wins are won, and the special wins are not won at the same time. The "double win" is used. , It is used in the sense that the special role and other roles other than the special role are simultaneously elected.
For example, the winning of “Watermelon+Controlling role 1” in the BB is a double winning in the sense that multiple types of winning combinations are won at the same time. Since they are not won at the same time, they are individually won in the sense of the ninth embodiment.

On the main control board 50 side, when the “watermelon+control role 1+BB” in the non-internal win (double win) and the “watermelon+control role 1” in the BB (independent win), Since the ON/OFF states of the winning flags are the same, the stop position of the reel 31 is determined using the same stop position determination table, but since the winning number and the production group number are different, the sub control board 80 side An effect to be output is determined using a different effect determination table.
The "control role" is a role for changing the stop position determination table to be selected by changing the on/off state of the winning flag, thereby making the stop control of the reel 31 different, and winning the prize. It's not for me.

(6) In the ninth embodiment, when the winning number “11” (independent winning of “Cherry 2”) is determined inside the RB and the inside of the BB, the advantageous section lottery can be executed. The advantageous zone drawing may not be executed when a special winning combination and a winning combination are won.
(7) The various modifications shown in the first to ninth embodiments and the first to ninth embodiments are not limited to be performed alone, but may be appropriately combined and implemented.

<Tenth Embodiment>
The tenth embodiment relates to control of display of the management information display LED 74.
The main CPU 55 has a setting change state (setting change mode, setting change), setting confirmation state for 5 seconds from a predetermined timing based on power-on (for example, at power-on, first interrupt processing start, program start, etc.). (Setting confirmation mode, setting confirmation in progress), in the RWM abnormal error state, control is performed so that all the LEDs of the management information display LED 74 are turned on.
As described in the second embodiment, the management information display LED 74 is composed of four-digit LEDs, so that "8888" is displayed when all the LEDs are turned on. Accordingly, it is possible to confirm whether the LED of the management information display LED 74 has a defect.

If the setting key switch is turned on when the power is turned on, the state changes to the setting change state where the set value can be changed. Further, when the setting change state is entered, all the LEDs of the management information display LED 74 are turned on.
Then, 5 seconds from the predetermined timing based on the power-on is set to a time longer than the time required from the power-on to the setting change state when the setting key switch is turned on when the power is turned on. There is.

Here, for example, it is assumed that the lighting period of all the LEDs of the management information display LED 74 from a predetermined timing based on power-on is set to a time shorter than the time required from the power-on to the setting change state. In this case, first, all the LEDs of the management information display LED 74 are turned on, then the management information is once displayed on the management information display LED 74, and then all the LEDs of the management information display LED 74 are turned on again. Therefore, there is a possibility that the manager (clerk in the hall) may suspect that the gaming machine has some trouble.

Therefore, the lighting period of all the LEDs of the management information display LED 74 from a predetermined timing when the power is turned on is set to 5 seconds.
The lighting period of all the LEDs of the management information display LED 74 from the predetermined timing based on the power-on is not limited to 5 seconds, and any time longer than the time required from the power-on to the setting change state can be set. It may be set to.

Hereinafter, the test pattern display of the management information display LED 74 will be described.
In the tenth embodiment, the 4-digit LED included in the management information display LED 74 is referred to as "digit 6", "digit 7", "digit 8", and "digit 9" in order from the left side.
Further, of the four-digit LED included in the management information display LED 74, the left two LEDs (digits 6 and 7) are referred to as “identification segment”, and the right two LEDs (digits 8 and 9) are referred to as “ratio”. Seg”.

Furthermore,
Digit 6: Identification segment high-order digit Digit 7: Identification segment low-order digit Digit 8: Ratio segment high-order digit Digit 9: Ratio segment low-order digit
Further, in the tenth embodiment, each LED (digit) of the management information display LED 74 is an 8-segment LED including segments A to G and a segment DP.

The display of the test pattern of the management information display LED 74 is performed to confirm whether all the segments (segments A to G and DP) are turned on and off properly. Therefore, during the period (time) during which the test pattern is displayed, all segments are set to have a lighting state and a non-lighting state.
When the test pattern is displayed on the management information display LED 74, it is displayed at any of the following timings.
(1) Within 5 seconds from the predetermined timing when the power is turned on (2) Within 5 seconds from the setting change start process (3) During setting change (mode) (4) During setting confirmation (mode) (5) During RWM error

As a test pattern, firstly, a predetermined display is switched every 1 second and displayed for 5 seconds. Note that the time for maintaining one display is not limited to 1 second, and the display time of the test pattern is not limited to 5 seconds (other than 5 seconds is sufficient).
Then, the test pattern is set so that all the segments of all the LEDs have a lighted state and a non-lighted state during the test pattern display time of 5 seconds.
Secondly, as a test pattern, blinking all segments of all LEDs can be mentioned. Even with this setting, all the segments of all LEDs can be turned on and off with one blink (lighting and extinguishing).

FIG. 29 is a diagram showing a first example of the test pattern display of the management information display LED 74.
In the test pattern display of FIG. 29 and FIG. 30, which will be described later, illuminated segments are indicated by solid lines and extinguished segments are indicated by dotted lines. Further, in the segment DP, a lighting state is indicated by a black circle, and an extinction response is indicated by a white circle.
In addition, in the following description, “.” indicates that the segment DP is in a lighting state, and “.” indicates that the segment DP is in a non-lighting state.

In Example 1 shown in FIG. 29, two types of display of each LED of the test pattern are provided.
One of them is a pattern displayed as "0.". More specifically, it is a pattern in which the segments A to F and DP are turned on and the segment G is turned off.
The other is a pattern displaying "-.". More specifically, it is a pattern in which the segment G is turned on and the segments A to F and DP are turned off.
Therefore, "0." and "-." have the opposite relationship in the segments that are turned on and off, respectively.

Further, in the state shown in FIG. 29A, “0.” is displayed in the identification segment high-order digit and the ratio segment high-order digit, and “-.” is displayed in the identification segment low-order digit and the ratio segment low-order digit.
Further, in the example 1 shown in FIG. 29, the display state shown in FIG. 29(a) is maintained for 1 second. Note that the count for one second may be measured by the number of interrupt processes. For example, when the display of FIG. 29(a) is started, "447(D)" is set in the counter, "1" is subtracted for each interrupt process, and when "0" is reached, the counter of FIG. An example is to end the display of a). As a result, the display of FIG. 29A can be maintained for “2.235×447=999.045 ms”.

When the display for about 1 second in FIG. 29A is completed, the display then shifts to that in FIG. 29B.
The display of FIG. 29(b) is obtained by replacing the display of FIG. 29(a) with an LED for displaying “0.” and an LED for displaying “−.”. That is, the display of FIG. 29(b) is opposite to the display of FIG. 29(a), "-." is displayed in the upper digit of the identification segment and the upper digit of the ratio segment, and the lower digit of the identification segment and the lower digit of the ratio segment are displayed. Is displayed as “0.”.
Further, as in the case of FIG. 29A, the display state shown in FIG. 29B is continued for 1 second (447 interrupts).

The display contents of FIGS. 29(a) and 29(b) above are switched and displayed every second, and this is executed for 5 seconds. Therefore, in FIG. 29, (c) and (e) have the same display content as (a), and (d) has the same display content as (b).
Then, when the display of the test pattern (for 5 seconds) is completed, the display shifts to the normal ratio display.
In FIG. 29, (f) shows an example in which the advantageous section ratio is displayed as “7.U.5.0.”. Further, instead of the advantageous section ratio, the accessory ratio may be displayed.

As described above, when "0." and "-." are displayed on the LED, it is possible to create a lighting state and a non-lighting state for all the segments (A to G and DP). Cannot be performed or cannot be turned off) can be easily visually determined.
Further, when displaying the ratio, neither the identification segment nor the ratio segment is displayed as "0.-." or "-.0.". Therefore, there is no risk of confusing the test pattern with the original ratio display.

FIG. 30 is a diagram showing a second example of the test pattern display of the management information display LED 74.
In Example 1 of FIG. 29, the display content is changed every 1 second and the test pattern is displayed for 5 seconds. As described above, such a test pattern is suitable for displaying within 5 seconds from a predetermined timing based on power-on or within 5 seconds from the setting change start process.
On the other hand, the example 2 of the test pattern display shown in FIG. 30 is suitable for displaying the test pattern until a predetermined end condition is satisfied, such as during setting change, setting confirmation, or RWM abnormal error. ..
Of course, the test pattern display of FIG. 29 may be used when displaying until the predetermined end condition is satisfied.
Similarly, it goes without saying that the test pattern display of FIG. 30 may be used when the test pattern display is displayed within a predetermined period after the start condition of the test pattern display is satisfied.

In Example 2 of FIG. 30, "8.8.8.8." is a state in which all the segments of all the LEDs are turned on and "*." is a state in which all the segments of all the LEDs are turned off. *.*.*."("*" indicates that segments A to G are off). In other words, it is a pattern in which "8.8.8.8." is displayed in blinking.
In Example 2 of FIG. 30, the lighting state of all the segments shown in FIG. 30A is maintained for 0.3 seconds, and then the extinguished state of all the segments shown in FIG. 30B is maintained for 0.3 seconds. Then, the lighting state shown in FIG. 30(a) and the extinguished state shown in FIG. 30(b) are repeated to make a blinking state.

In the tenth embodiment, the blinking interval is set to 0.3 seconds. For example, "134(D)" is set as the initial value of the timer, the timer value is decremented by "1" for each 2.235 ms interrupt process, and when the timer value becomes "0", the lighting time or It is determined that the turn-off time has elapsed. As a result, by counting the number of interruptions “134”, it is possible to count “299.49” ms.

Also in the example 2 of the test pattern display of FIG. 30, it is possible to create the turned-on state and the turned-off state for all the segments by "8." and "*.". Therefore, a segment defect (cannot be turned on or turned off) can be easily visually determined.
When displaying the ratio, neither the identification segment nor the ratio segment is displayed as “8.8.”. For example, when the ratio reaches 88%, the display blinks regardless of the ratio, but in that case, "8.8." is displayed and the segment DP is not lit. On the other hand, the display of "8.8." does not confuse both because the segment DP is also lit.

Each ratio displayed on the management information display LED 74 is updated (calculated) at the end of the game (after all reels 31 are stopped and the payout process is completed). Then, in the subsequent interrupt processing, the updated ratio is displayed. When a power failure occurs immediately before the ratio is updated and the test pattern is displayed for 5 seconds after the power is restored, the ratio update (calculation) processing is performed during the 5 seconds during which the test pattern is displayed. To execute. Then, when the display of the test pattern is ended and the ratio display is started, the updated ratio is displayed after the recovery from the power failure.

<Eleventh Embodiment>
FIG. 31A is a diagram showing various LEDs on the display substrate 75 in the eleventh embodiment, and FIG. 31B is a diagram showing the management information display LED 74 in the eleventh embodiment. Further, FIG. 11C is a diagram showing the set value display LED 73 in the eleventh embodiment.
As shown in FIG. 31(A), the credit display LED 76 includes a digit 1a (upper digit) and a digit 2a (lower digit). The acquired number display LED 78 includes a digit 3a (upper digit) and a digit 4a (lower digit).
Here, the "digit" means a display unit (display), and in particular, in the present embodiment, it is composed of a seven-segment LED (so-called 7-segment).
Each of these digits 1a to 4a is a 7-segment display including dot segments (segment P). In particular, the segment P of the digit 4a (lower digit of the acquired number display LED 78) functions as the advantageous section display LED 77.

The digit 5a is composed of 6 dot LEDs, and these 6 dot LEDs are collectively referred to as a status display LED 79. In FIG. 1, the credit number display LED 76 and the acquired number display LED 78 are shown, but the state display LED 79 is not shown. However, actually, as shown in FIG. 31A, the credit number display LED 76, the acquired number display LED 78, and the status display LED 79 are mounted on the display substrate 75.
In the status display LED 79, the 1-bet display LED 79a to the 3-bet display LED 79c are LEDs that display the number of medals bet at that time. When one medal is bet, only the one-bet display LED 79a lights up. When two medals are bet, the 1 bet display LED 79a and the 2 bet display LED 79b are turned on. When three medals are bet, all of the 1-bet display LED 79a, the 2-bet display LED 79b, and the 3-bet display LED 79c are lighted.

The game start display LED 79d is an LED that lights up when a medal is inserted and the start switch 41 becomes operable. Therefore, the medal is not turned on when the bet is not bet (or the replay is not automatically inserted).
The insertion display LED 79e is an LED that lights up when a medal can be inserted. That is, the game is over, and lights up before a medal for shifting to the next game is thrown in, indicating a so-called bet waiting state. Even after the replay is activated, it lights up when the bet can be made according to the number of credits. Then, when the bet number is the maximum (when more bets cannot be made), the insertion display LED 79e is turned off.

The replay display LED 79f is an LED that is turned on when the replay is won, and when an automatic bet is made based on the replay win, the replay display LED 79f is turned on to inform the player that the bet is in the automatic bet state.
Note that, as the status display LED 79 not shown in FIG. 31A, for example, a settlement display LED (LED that lights up during settlement processing) can be cited, but the illustration is omitted in FIG. 31A.

Further, in FIG. 31(B), the management information display LED 74 is the same as that shown in FIGS. 10, 29 and 30, and is composed of four digits 1b to 4b. These digits 1b to 4b are 7-segment displays including dot segments (segments P) like the above-mentioned digits 1a to 4a. The digits 1b to 4b display the information type upper level, the information type lower level, the numerical upper level and the numerical lower level, respectively.
The segment P of the digit 2b (lower information type) functions as a digit group display LED. The digit separation display LED is used to clarify the separation between the information type and the numerical value.

Further, the segment P of the digits 1b to 4b can be turned on when the test pattern is displayed, as shown in FIGS. 29 and 30.
Furthermore, in FIG. 31(C), the set value display LED 73 is the same as that shown in FIG. 10, and is an LED that displays the current set value during the setting change and the setting confirmation. ) Digit 5b.
Further, as shown in FIG. 10, the management information display LED 74 (digits 1b to 4b) and the set value display LED 73 (digit 5b) are mounted on the main control board 50.

FIG. 32 is a diagram showing a relationship between the digits 1a to 5a and the digits 1b to 5b and the segments A to G and P in the present embodiment.
The 7-segment digit is a 7-segment segment composed of seven rod-shaped segments A to G and one dot-shaped segment P. It should be noted that the LED including the segments A to G having no segment P may be referred to as "7 segment", and the LED including the eight segments including the segment P may be referred to as "8 segment". In the book, the LED including 8 segments is also referred to as "7-segment".

As shown in FIG. 32, for example, in the digit 1a, the segments A to G constitute the 7th segment of the upper digit of the credit number display LED 76, and the segment P is unused. Similarly, each of the segments A to G of the digits 2a and 3a constitutes 7 segments of the lower digit of the credit number display LED and the upper digit of the acquired number display LED 78, respectively, and the segment DP is unused.
Further, the segments A to G of the digit 4a constitute 7-segments of the lower digit of the acquired number display LED 78, and the segment P constitutes the advantageous section display LED 77.

The digit 5a is an LED that constitutes the status display LED 79. As shown in FIG. 32, the segment A of the digit 5a corresponds to the 1-bet display LED 79a, the segment B corresponds to the 2-bet display LED 79b,..., The segment F corresponds to the replay display LED 79f. Further, the segments G and P of the digit 5a are not provided.

The digits 1b to 4b form a management information display LED 74, and the segments 1b and 2b display the information type of the management information. Further, the segments 3b and 4b display numerical values corresponding to the information types displayed in the segments 1b and 2b of the management information. The segments P of the digits 1b, 3b, and 4b are normally turned off, but are turned on when the test pattern is displayed, as shown in FIGS. 29 and 30. Further, the segment P of the digit 2b functions as a digit separation display LED for clarifying the boundary between the digits 1b and 2b indicating the information type and the digits 3b and 4b indicating the numerical value and facilitating the confirmation. The digit separation display LED may be repeatedly turned on and off like the other digit segments P while the test pattern is being displayed, or may be kept on all the time.

Further, among the digits 5b, the segments A to G compose 7-segments of the set value display LED 73, and the segment P is an LED that lights up during the setting change. That is, among the set value display LEDs 73, when the segment P is off, the setting is being confirmed, and when the segment P is on, the setting is being changed. The segment P of the set value display LED 73 is not necessarily limited to such usage. For example, the segment P of the set value display LED 73 may be a segment that lights up when the set value is confirmed during the setting change.

Further, FIG. 32 illustrates the structure of segment data. The segment data is 1-byte data, the D0 bit corresponds to the segment A, the D1 bit corresponds to the segment B,..., And the D7 bit corresponds to the segment P.
For example, when "0" is displayed on the digit 1a, the segments A to F are turned on and the segments G and P are turned off, so that the segment data is "00111111(B)".

When the digit 4a is displayed as "1" and the advantageous zone display LED 77 is turned on, the segments B, C, and P are turned on, so that the segment data is "10000110 (B)".
Furthermore, when three medals are betted before the game starts and the game can be started, the 1 bet display LED 79a, the 2 bet display LED 79b, the 3 bet display LED 79c, and the game start display LED 79d are turned on. The segment data of 5a is “00001111(B)”.

FIG. 33 is a diagram showing the output port 52 in the eleventh embodiment. The types of output ports are not limited to those shown in FIG.
As the output port 52 of the eleventh embodiment, one output port for transmitting a digit signal (output port 2) and two output ports for transmitting a segment signal (output ports 3 and 4) are provided. ..
The output port 3 is an output port for transmitting segment signals of the credit number display LED 76, the acquired number display LED 78, and the status display LED 79 (digits 1a to 5a).
The output port 4 is an output port for transmitting the segment signals of the management information display LED 74 (digits 1b to 4b) and the set value display LED 73.

In the output port 2, digits 1 to 5 signals are assigned to bits D0 to D4, respectively. Here, the digit 1 signal includes both the digit 1a signal and the digit 1b signal, and the same applies to the digit 2 to 5 signals. Therefore, for example, when a signal of "1" is output from the D0 bit of the output port 2, both the digit 1a (credit number display LED 76 (upper digit)) and the digit 1b (management information display LED 74 (upper information type)) are output. A drive signal is supplied.

Further, in the output port 2, the D5 to D7 bits are unused.
The output port 3 is an output port for the segments A to P signals of the digits 1a to 5a, and the segments A to P signals are allocated to bits D0 to D7.
Similarly, the output port 4 is an output port for the segments A to P signals of the digits 1b to 5b, and the segments A to P signals are allocated to the bits D0 to D7.
Furthermore, the output port 5 outputs external signals 1 to 5, a data strobe signal, a medal insertion signal, and a medal payout signal.

Here, the “external signal” is a signal to be output to the outside of the slot machine 10 (the hall computer 200, a data counter installed in the hall, etc.) via the external centralized terminal board 100. Specifically, for example, an advantageous section, an AT, a specific RT, external signals 1 to 3 indicating that the accessory is operating, an external signal 4 indicating that an error occurred in the slot machine 10 or a power failure has occurred. An external signal 5 indicating the opening of the front door of the slot machine 10 is provided.

The data strobe signal is a signal transmitted to the sub control board 80. Upon receiving the data strobe signal, the sub control board 80 controls the sub control data signal to be acquired from the buffer provided in the sub control board 80 based on the rising edge of the data strobe signal.
In addition, from output ports (not shown) other than the output ports 2 to 5 shown in FIG. 33, for example, a signal of the motor 32, a signal of the blocker 45, a drive signal of the hopper motor 36, a condition device signal (so-called winning number). , Sub-control data signal, test signal, etc. are output.

FIG. 34A is a diagram showing a relationship among an interrupt, an LED display counter value, a digit signal and a segment signal in the eleventh embodiment. Further, FIG. 3B is a diagram showing an LED display request flag.
In the present embodiment, as the processing of the main control board 50, a main processing (M_MAIN) performed for each game (FIG. 41 described later) and, in parallel with this main processing, once every 2.235 ms, interrupt processing ( I_INTR) (FIG. 53 described later) is executed.

The LED display counter is 1-byte data and is a counter that is continuously updated for each interrupt. The LED display counter is a counter for determining which of the digits 1 (1a and 1b) to 5 (5a and 5b) is to be turned on. For each bit of the LED display counter, D0 bit is assigned to the digit 1 signal, D1 bit is assigned to the digit 2 signal,..., D4 bit is assigned to the digit 5 signal. Then, in the one interruption process, the dynamic lighting of the digits 1 (1a and 1b) to 5 (5a and 5b) is performed so as to light the digit corresponding to the bit which is "1" in the LED display counter.

The LED display counter of the present embodiment has a value of "00010000 (B)" as an initial value. Then, the LED display counter updates the bit "1" of the LED display counter value so that it shifts to the right by one digit as the interrupt progresses from "1" to "2" →... (for each interrupt). Further, in FIG. 34, the LED display counter becomes “00000000 (B)” by shifting the digit by one digit to the right at the interrupt next to the interrupt “5”, but at the time of the interrupt, initialization processing of the LED display counter is performed. The LED display counter is set to "00010000 (B)". As a result, the LED display counter repeats the values of “5”→“4”→...→“1”→“5”→“4”→... For each interrupt process. That is, one cycle consists of 5 interrupts.

From the above, the LED display counter value is
"N" interrupt line: 00010000 (B)
"N+1" interrupt line: 00001000 (B)
"N+2" interrupt line: 00000100 (B)
"N+3" interrupt line: 00000010 (B)
"N+4" interrupt line: 00000001 (B)
"N+5" interrupt line: 00000000 (B) → 00010000 (B) (initialization; same value as "N" interrupt line)
"N+6" interrupt line: 00001000 (B)
:
Becomes

In the eleventh embodiment, five interrupts form one cycle, and the digits 1a to 5a and the digits 1b to 5b are turned on. Specifically, in FIG. 34(A), for example, when the interrupt is "1", that is, when the LED display counter value is "00010000(B)", the digit 5 signal is output. By outputting the digit 5 signal, the digits 5a and 5b can be turned on. Therefore, the status display LED 79 and the set value display LED 73 can be turned on. At the next interruption "2", the LED display counter becomes "00001000 (B)", the digit 4 signal is output, and the lower digit of the acquired number display LED D78 and the numerical lower digit of the management information display LED 74 can be turned on. ..

Further, FIG. 34B is a diagram showing the data structure of the LED display request flag. The LED display request flag is data indicating a digit whose lighting is permitted. As shown in FIG. 34(B), the LED display request flag is 8-bit data corresponding to the digit 1 signal at the D0 bit, the digit 2 signal at the D1 bit,..., And the digit 5 signal at the D4 bit. is there. Each bit of the LED display request flag is matched with the bit of the output port 2.
As shown in FIG. 34B, the digits 1 to 5 can be turned on during normal operation, the digits 3 to 5 can be turned on during setting change, and the digits 1 to 5 can be turned on during setting confirmation. is there. Incidentally. "In normal operation" refers to a game waiting state and a game in progress.

Then, in the interrupt process, the LED display counter and the LED display request flag are AND-operated, and the digit corresponding to the bit that has become "1" becomes the digit that is turned on in the interrupt process this time.
For example, if the LED display counter is “00010000 (B)” and the LED display request flag is “00011111 (B) (normal)”, the AND operation of the both results in “00010000 (B)” and the digit 5 Only the signal becomes "1". However, during normal operation (during game standby and during game), the segment signal is output from the output port 3 and the status display LED 79 can be turned on, but the segment signal is not output from the output port 4 and the set value display LED 73 is output. Control is performed so that (digit 5b) is not turned on.

On the other hand, during the setting change, for example, at the interrupt timing when the digit 5 signal is turned on (the LED display counter is "00010000 (B)"), the segment signal is output from the output port 4 and the set value display LED 73 (digit 5b) is displayed. It can be turned on.
Also, during the setting change, for example, at the interrupt timing when the digit 3 or 4 signal is turned on (the LED display counter is “00000100 (B)” or “00001000 (B)”), the digit 3 signal (the number-of-acquisition display LED 78 is displayed) is changed. The upper digit) and the digit 4 signal (lower digit of the acquired number display LED 78) are output to display "88" (content indicating that the setting is being changed) on the acquired number display LED 78.

Furthermore, when the segment signal of the output port 3 is generated at the interrupt timing of the LED display counter "00001000 (B)" (interrupt "2" in FIG. 34), the value of the advantageous section display LED flag is referred to. By doing. When the advantageous section display LED flag is ON, the value obtained by ORing the generated segment signal and "10000000(B)" is output from the output port 3 as a segment signal. Accordingly, the segment P (advantageous section display LED 77) of the digit 4a can be turned on.

FIG. 35 is a diagram showing addresses, label names, the number of bytes, and names and contents of data stored in the RWM 53.
Note that the data shown in FIG. 35 is for use in the description of the eleventh embodiment, and the data stored in the RWM 53 is not limited to these.

The address “F000(H)” is a storage area for setting value data (_NB_RANK). When the set value is "N", "N-1" is stored as the set value data. In the present embodiment, the set values are “1” to “6”. Therefore, any value of "0 (H)" to "5 (H)" is stored as the set value data.
Then, the set value display LED 73 displays “N” obtained by adding “1” to the set value data as the set value.

The address “F010(H)” is a storage area for credit amount data (_NB_CREDIT). The credit amount data is data to be displayed on the credit amount display LED 76. In the present embodiment, any value from “0” to “50(D)” is stored as the credit amount data.
Here, in the present embodiment, a value obtained by converting the credit amount into a decimal number is stored as the credit amount data. For example, when the number of credits to be displayed is "29", the value "29(H)" is stored. In other words, "00101001(B)" is stored in the address "F010(H)". As a result, the lower 4 bits of D0 to D3 of the address “F010(H)” are data for displaying the lower digit (“9” in this example) of the credit number, and the upper 4 bits of D4 to D7 are , Data for displaying the upper digit of the number of credits (“2” in this example). In the present embodiment, the upper limit value of the number of credits is “50(D)”, so the stored data value is in the range of “0” to “50”.
Further, in the present embodiment, the address of the RWM 53 for storing the credit amount data itself is not provided, but the credit amount data is provided as the display data of the credit amount display LED 76.

The address “F011(H)” is a storage area for the acquired number data (_NB_PAYOUT). The acquired number data is data to be displayed on the acquired number display LED 78. In the acquired number data, like the credit number data described above, the lower 4 bits of D0 to D3 are data for displaying the lower digit, and the upper 4 bits of D4 to D7 are for displaying the upper digit. The data.
In the present embodiment, at the time of winning a small winning combination, the number of payouts corresponding to the winning small winning combination is displayed on the acquired number display LED 78, so that the payout amount data corresponding to the winning small winning combination is stored as the acquired number data. Specifically, when a small winning combination is won and medals are paid out, the acquired number data is added with the payout of the medals, and the display of the acquired number display LED 78 is updated. For example, when “1 (H)” is stored as the acquired number data, “01” is displayed on the acquired number display LED 78.

Here, in the payout amount data (_NB_PAY_MEDAL) of the address “F040(H)” which will be described later, for example, “8(H)” is stored when eight winning combinations are won, and the payout amount data is (8) (Including addition to credits), "1" is decremented by 1 according to the number of payouts, such as "8" → "7" → ... → "0".
On the other hand, the acquired number data stored in the address “F011(H)” is, for example, “0”→“1”→“2”→... As described above, “1” is incremented each time one medal is paid out. Therefore, the display of the acquired number display LED 78 also counts up as “0”→“1”→“2”→...→“8”.

Further, in the present embodiment, “88” is displayed on the acquired number display LED 78 during the setting change. Therefore, during the setting change, the setting change display data for displaying "88" is stored as the acquired number data. By displaying "88" on the acquired number display LED 78, the fact that the setting is being changed can be identified from the front side of the gaming machine. Furthermore, by lighting "88" and all the segments, it is possible to confirm that there is no segment defect (that there is no segment that cannot be lit). Since the upper limit of the number of payouts of medals is 15, it can be understood that the number of payouts is not displayed when “88” is displayed on the acquired number display LED 78.

Furthermore, in a twelfth embodiment to be described later, when the condition for instructing a prescribed number (the number of medals to be bet in the game this time) is satisfied, before the start of the game (before the bet is possible or the start switch 41 is operated. (Before being displayed), the specified number is instructed (displayed and notified) to the acquired number display LED 78. In the present embodiment, in order to instruct the specified number "2", "0A" is displayed on the acquired number display LED 78. Therefore, when the specified number is specified, the specified specified number display data for displaying "0A" is stored as the acquired number data. Although the details will be described later, the specified prescribed number display data for displaying "0A" is "0B(H)".

Further, when the push order bell or the like in AT is won, the push order instruction information is displayed on the acquired number display LED 78. Pushing order instruction information corresponding to winning numbers “3” to “8” shown in FIG. 58 described later are “=1” to “=6”, respectively. Therefore, when the push order instruction information is displayed on the acquired number display LED 78, the push order instruction number is stored as the acquired number data. Although details will be described later, the push order instruction numbers corresponding to the push order instruction information “=1” to “=6” are “A1(H)” to “A6(H)”, respectively. For example, in the game in which the winning number "3" is won, when the pushing order instruction information is displayed, the pushing order instruction number "A1(H)" is stored as the acquired number data. As a result, the push order instruction information “=1” corresponding to the push order instruction number “A1(H)” is displayed on the acquired number display LED 78.

When a predetermined error occurs, an error number is displayed on the acquired number display LED 78. Therefore, when a predetermined error occurs, error number display data for displaying the error number is stored as the acquired number data. For example, when the error number to be displayed is "HP", the error number display data for displaying "HP" is stored as the acquired number data.

The address “F030(H)” is a storage area for the operation state flag (_FL_ACTION). The operation state flag (_FL_ACTION) is a flag for determining whether or not the replay and the accessory have been operated. For example, when operating 1BB, the D2 bit of the operating state flag is set to "1".
This operation state flag is updated in the game start set process described later (step S317 in FIG. 42). For example, in step S313 of FIG. 42, when the D0 bit of the later-described symbol combination display flag is read and it is determined that the D0 bit is "1", it is determined that the symbol combination corresponding to the replay is stopped and displayed, and the operating state The D0 bit of the flag is set to "1".
The replay operation status flag (D0 bit) is cleared in step S413 of FIG. 50 (game end check processing) described later.
Further, the operating state flag of the accessory is also cleared in the game end check processing (not shown in FIG. 50).

The address "F031(H)" is a storage area for the symbol combination display flag (_FL_WIN). The symbol combination flag is a flag for determining the symbol combination that is stopped and displayed, and in the present embodiment, D0 bit is assigned to replay and D2 bit is assigned to 1BB. Therefore, the replay and 1BB bits of the symbol combination display flag are respectively assigned to the same bits as the replay and 1BB bits assigned by the operation state flag.
During the main processing of FIG. 41, in step S291, the winning determination unit 66 determines whether or not the symbol combination corresponding to the winning combination is stopped and displayed. Then, the symbol combination display flag is updated according to the symbol combination stopped and displayed. For example, when it is determined that the replay symbol combination is stopped and displayed, the D0 bit of the symbol combination flag is set to "1".
The symbol combination display flag is cleared in step S279 (start switch acceptance processing) at the start of the next game, specifically during the main processing of FIG.

The address “F040(H)” is a storage area for the payout amount data (_NB_PAY_MEDAL). The payout amount data becomes data indicating a value corresponding to the payout amount when a small winning combination is won in the game and the payout amount is determined (step S293 in FIG. 40). When a small winning combination is won, the payout amount data corresponding to the winning small winning combination is stored, and the medal payout process is executed. Here, the payout amount data is decremented by "1" for each payout of one medal (addition of "1" to the number of credits or one payout of the actual medal (from the hopper 35)). That is, it has a role as the number of times the payout process is executed. As a result, when the medal payout process is completed, the payout amount data becomes "0".

The address “F041(H)” is a storage area of the payout amount data buffer (_BF_PAY_MEDAL). Similar to the payout amount data, the payout amount data buffer becomes data indicating a value corresponding to the payout amount when a small winning combination is won in the game and the payout amount is determined. Here, unlike the payout amount data, the payout amount data buffer is not subtracted for each one medal payout process, and the initially stored value is maintained. The value is maintained until the next game medal payout number update process (step S293 in FIG. 41). For example, when a small winning combination of 8 coins is won in the game, "8(H)" is stored as the payout amount data buffer, and when the winning combination is not won in the next game, the payout amount data buffer is used. "0" is overwritten.

The address "F042(H)" is a storage area for automatic bet amount data (_NB_REP_MEDAL). The automatic bet number data indicates the number of medals to be automatically bet at the time of the replay winning, and “2” or “3” is stored in this embodiment.
The automatic bet amount data is set in step S325 during the game start setting process of FIG.
The address “F043(H)” is a storage area for bet number data (_NB_PLAY_MEDAL). The bet number data indicates the bet number in the current game, and in the present embodiment, any one of “0” to “3” is stored. The bet number data is performed in the medal management process (detecting inserted medals, performing a bet process and a credit addition process) in step S276 during the main process of FIG.

The address "F051(H)" is a storage area of the LED display counter (_CT_LED_DSP). The LED display counter is the one shown in FIG. 34A, and is updated every time the interrupt processing is performed, as described above.
The address “F052(H)” is a storage area for the LED display request flag (_FL_LED_DSP). The LED display request flag is the one shown in FIG. 34(B), and takes a value corresponding to the normal state, the setting change, or the setting confirmation.

The address "F061(H)" is a storage area for the advantageous zone type flag (_NB_ADV_KND). The advantageous section type flag is a flag indicating whether the current game section is a normal section or an advantageous section.
The advantageous section type flag stores "00000000(B)" when the section is a normal section, and the D0 bit becomes "1" when the section shifts from the normal section to the advantageous section.
The timing at which the advantageous section type flag is updated will be described later.

The address “F062(H)” is a storage area for the advantageous section display LED flag (_FL_ADV_LED ). The advantageous zone display LED flag is a flag indicating whether or not the advantageous zone display LED 77 is turned on. When the advantageous zone display LED 77 is off, the advantageous zone display LED flag is "0", and when the advantageous zone display LED 77 is on, the advantageous zone display LED flag is "1".
The advantageous zone display LED 77 may be turned on at any time after shifting to the advantageous zone (for example, the advantageous zone display LED 77 may be turned on at the same time as shifting to the advantageous zone).

On the other hand, even after shifting to the advantageous zone, the advantageous zone display LED 77 may not be turned on.
Specifically, first, the advantageous zone display LED 77 is not turned on at the time of transition to the advantageous zone, but may be turned on after that (during the advantageous zone).
Secondly, when the advantageous zone display LED 77 is not turned on at the time of transition to the advantageous zone and the end condition of the advantageous zone is satisfied before the condition for turning on the advantageous zone display LED 77 is satisfied, the advantageous zone display LED 77 is never displayed. The advantageous section may be ended without being turned on.

Furthermore, in the present embodiment, when the instruction function is activated (when the correct answer pressing order is notified) in the gaming state in which the section is the advantageous section and the section Sim payout rate exceeds "1", the advantageous section is displayed. The LED 77 is turned on.
Further, after the advantageous section display LED 77 is once turned on, the lighting is maintained during the advantageous section.
Further, at the time of the game end check processing in the final game of the advantageous zone, processing for turning off the advantageous zone display LED 77 is executed. Specifically, when the condition for ending the advantageous period is satisfied, initialization process of the advantageous period display LED flag storage area (clearing process of the advantageous period display LED flag) is executed. As a result, the advantageous section display LED 77 is turned off in the subsequent interrupt processing.

Furthermore, the lighting timing in the case of lighting the advantageous section display LED 77 in the game in which the instruction function is operated is, for example, when the start switch 41 is operated (more specifically, after the rotation of the reel 31 is started, Until the rotation reaches the constant speed state).
However, it is not limited to this, and other lighting timings include, for example,
1) Before the start switch 41 is operated 2) After the start switch 41 is operated, when all the reels 31 are in a constant speed state and the operation of the stop switch 42 can be accepted,
3) When at least one reel 31 is stopped and the other at least one reel 31 is rotating,
4) When all reels 31 are stopped,
5) Before all the reels 31 are stopped (the game ends) and before the settlement switch 43 can be operated before the next game starts.

However, when the advantageous section display LED 77 is turned on in the game in which the instruction function is operated, it is necessary to determine the winning combination in the game, and therefore, before the operation of the start switch 41 (before the role lottery) is excluded. ..
When the advantageous section display LED 77 is turned on in the game in which the instruction function is activated, the start switch 41 is operated and the lottery for the winning combination is executed. Therefore, after the reel 31 starts rotating, the reel 31 rotates. The shortest timing is to turn on the advantageous zone display LED 77 before the constant speed state is reached.

The address "F063(H)" is a storage area of the advantageous section clear counter (_CT_ADV_CLR). The advantageous zone clear counter is a decrement counter for counting the number of games played in the advantageous zone. The advantageous section clear counter is "0" during the normal section, and when shifting to the advantageous section, "1500 (D)" is set as an initial value. Further, the advantageous section clear counter is set so that "1" is subtracted per game not only during the advantageous section but also during the normal section. However, the minimum value is "0". For this reason, in the normal section, when the advantageous section clear counter (before subtraction) is "0", the counter after subtraction is "0" even if "1" is subtracted is used. Therefore, during the normal section, "1" is subtracted for each game, but "0" is maintained. In other words, when "0" is stored in the advantageous section clear counter, it is a normal section (non-advantageous section).

Further, when shifting to the advantageous section, the advantageous section clear counter is set to "1500 (D)" as an initial value, so that the advantageous section clear counter becomes "1499 (D)" in the next game.
The advantageous interval clear counter stores an initial value "1500 (D)" at the maximum, and is therefore composed of 2 bytes. In other words, when a value other than "0" is stored in the advantageous interval clear counter, it is an advantageous interval.

The address "F065(H)" is a storage area of the difference counter (_SC_24HGAME). The difference number counter is a counter that stores a value corresponding to the cumulative value of the difference number of sheets in the advantageous section, and is also referred to as “MY counter”.
The difference number counter does not simply store the cumulative value of the difference number itself, but stores a “value corresponding to” the accumulated value of the difference number. For example, when the difference number becomes a value corresponding to minus, the value is corrected to "0 (H)". Therefore, “cumulative number of difference sheets≠difference number counter value”.
The difference number counter is an increment counter for determining whether or not the value corresponding to the cumulative value of the difference numbers in the advantageous section exceeds “2400(D)”. Therefore, the difference counter is composed of a storage area of 2 bytes.

The difference counter suffices to count at least the cumulative value of the number of difference sheets in the advantageous section, and need not count in the non-advantageous section (normal section).
Here, when the difference number counter value is updated on condition that it is an advantageous section, it is necessary to perform a process for determining whether each game is an advantageous section or not. Therefore, in the present embodiment, the difference counter value is updated including in the non-advantageous section (normal section). By doing so, the difference number counter value can be updated without determining whether or not each game is an advantageous section, so that the process can be simplified.

Further, the difference number counter value is updated even when the difference number becomes negative in the game this time and the value corresponding to the accumulated value of the difference number becomes the carry-down data. However, as a result of the calculation, when the difference number counter is the carry-down data, the difference number counter value is corrected to "0".

To give a specific example (the difference counter value at the start of the first game is set to "0 (H)"),
First game: When the bet number is “3” and the payout number is “0”, the difference counter after calculation is “FFFD(H)”, and the difference counter after correction is “0 (H)”
Second game: bet number "3", payout number "9", difference counter after calculation "0006(H)" (no correction)
3rd game: bet number “3”, payout number “0”, difference number counter “0003 (H)” after calculation (without correction)
4th game: bet number “3”, payout number “1”, difference number counter “0001 (H)” after calculation (without correction)
Fifth game: bet number “3”, payout number “0”, difference number counter “FFFE(H)” after calculation, difference number counter “0(H)” after correction
Is updated as.
Even when the difference number counter of the previous game is “0 (H)” and the difference number counter of the current game is “0 (H)”, the difference number counter value reflecting the difference number of the game is newly updated. Since it is the result of calculation, this case also corresponds to "update" of the difference counter.

As described above, when the difference number counter value after the calculation has a carry-down value, the difference number counter value is corrected to "0" (initial value "0" is set). The method of determining whether a carry-down has occurred will be described later.
By updating the difference number counter value as described above, for example, when the payout number is large relative to the bet number, that is, when the difference number is being increased, the difference number counter value increases as the game progresses. On the other hand, when the number of payouts is less than the number of bets, for example, in a game during a normal section, the difference number counter value increases by the number of payouts when there is a payout based on the winning of a small win, but thereafter, the number of payouts If is less than the bet number, it will eventually become "0".

FIG. 36 is a diagram (slump graph) for explaining the concept of the difference number counter value, where (a) shows Example 1 and (b) shows Example 2. In FIG. 36, the horizontal axis is the number of games played, and the vertical axis is the difference number.
In Example 1, the difference number first proceeds in the negative direction as the game progresses, but the difference number starts to increase in the middle, for example, when AT is started. Then, the difference number counter is counted as "0" when the difference number becomes the minimum value in the course of the game, so that the range indicated by the arrow in the figure is counted by the difference number counter as the increase amount of the difference number. To be done. As described above, in the present embodiment, the advantageous section is ended when the difference counter value exceeds “2400(D)” (the next game is controlled to be the game of the normal section).

It should be noted that when the difference counter exceeds "2400(D)", the end condition of the advantageous section is satisfied, so, for example, when the difference counter is just "2400(D)" at the end of the current game, the current game Then, the condition for ending the advantageous section is not satisfied.
Then, in the next game, assuming that the maximum difference number for the game machine is obtained, this is the case where the bet number is "1" and the payout number is "15", so the difference number in the next game is "+14", The difference number counter value at the end of the next game is “2414 (D)”. When the difference counter is "2414 (D)", it is determined that the condition for ending the advantageous section is satisfied.
Therefore, the maximum value that the difference counter can take is “2414(D)”.

The determination as to whether the difference counter exceeds “2400(D)” is not limited to reading the difference counter value stored in the RWM 53 and making a determination, and is temporarily stored in a register for updating or the like. It also includes determining the difference number counter value (hereinafter the same).
Further, when it is determined whether or not the value exceeds “2400(D)” based on the difference number counter value temporarily stored in the register, when it is determined that the value does not exceed “2400(D)”, The difference number counter value of the register is stored (saved) in the RWM 53. On the other hand, when it is determined that the difference number exceeds “2400(D)”, the difference number counter value is not stored in the RWM 53, and the difference number counter value stored in the RWM 53 is cleared. It is also possible.

In addition, as in Example 1, Example 2 shows an example in which the difference number advances in the negative direction as the game progresses, but the difference number starts to rise from the middle, for example, when AT is started. .. In Example 2, even when the difference counter exceeds “2400(D)”, the cumulative value of the difference is not positive, but even in such a case, the advantageous section is ended. That is, regardless of the cumulative value of the difference number with the progress of the game up to that point, if the difference number counter value exceeds “2400(D)”, counting from the time when the difference number becomes the minimum value, the advantageous section Ends (the next game is controlled to be a game in the normal section).

If the difference counter is updated during the normal section, the difference counter may exceed “2400(D)” even during the normal section. For example, such a situation may occur when the special combination is won many times and the special game is repeated. In such cases,
1) A method of updating the difference counter value as it is until the start of the advantageous period,
2) When the value exceeds “2400(D)”, there is a method of temporarily resetting the difference number counter value to “0” at that time.
For example, when the difference counter exceeds “2400(D)” during the advantageous section, when the difference counter is cleared based on the end of the advantageous section, whether the process is in the advantageous section or not. If the process is executed regardless of whether the difference counter exceeds "2400(D)" during the normal section, it is cleared.

On the other hand, if the processing for clearing the difference counter is processing unique to the advantageous section, the difference counter is not cleared even if the difference counter exceeds “2400 (D)” during the normal section.
When the advantageous section is started (first game of the advantageous section), the difference counter is cleared (initial value “0” is set. Step S354 in FIG. 45 described later). Therefore, there is no problem with any number of difference counters before the start of the advantageous section.
And
1) When the difference counter exceeds “2400(D)” during the advantageous zone,
2) When the number of games in the advantageous zone reaches 1500 games,
Satisfies the end condition of the advantageous section.
When the end condition of the advantageous section is satisfied, the difference counter is cleared (initialized). The difference counter is cleared at the end of the advantageous section so that the data (value) regarding the advantageous section is not carried over to the normal section when the advantageous section is ended and the normal section is shifted to. The clearing of the difference counter is executed in step S435 in FIG. 51 described later.

FIG. 37 is a diagram (slump flag) showing the relationship between the difference number counter value and the advantageous section, where (a) shows Example 1 and (b) shows Example 2.
In Example 1, in the normal section, the difference number decreases with the progress of the game, and the difference number further decreases from the time when the advantageous section starts (“A” in the figure) to “B” in the figure. An example is shown. It should be noted that AT is not started at the same time as the start of the advantageous section, and the beginning of the advantageous section is CZ, a sign, and AT preparation (for example, when the RT state is in the low probability state, the RT state is changed from the low probability state to the high probability state). In the case of specifications that start from the middle of waiting for the replay to win), the number of differences may decrease even after starting the advantageous section. In addition, even when the AT is started, the number of differences may decrease if the push order bell is not won very often.

Since the difference counter value is initialized at the start of the advantageous section, it is "0" at the time "A" in the figure. In addition, as described above, the difference number counter value maintains “0” under the situation where the difference number is decreasing. Therefore, in the figure, the difference number counter value remains "0" from the point "A" to the point "B".
In addition, an example is shown in which the difference number starts to increase from the “B” point. As a result, the difference number counter value also increases. Then, when it is determined that the difference number counter value exceeds “2400 (D)” (when the point reaches “C” in the figure), it is determined that the end condition of the advantageous section is satisfied, and the advantageous section is ended. (Move to normal section).

In this way, the difference counter does not count the difference from the start of the advantageous section, but after the start of the advantageous section, the difference counter starts counting positively at the time when the difference reaches its lowest value (“B”), It is no longer possible to give medals to the player beyond the range in which the number of balls increases (the range from "B" to "C" in FIG. 37(a)). As a result, the player's ambition can be prevented.

The above points will be described more specifically by taking numerical values as an example.
For example, if the specification is such that the AT is started by lottery after starting the advantageous section, the difference number may decrease as the game progresses in the case of the advantageous section and non-AT.
For example, it is assumed that the player X wins the advantageous section and the advantageous section is started, but AT is not started and the game is stopped when the difference number becomes "-200 sheets".

Next, it is assumed that when the player Y starts playing a game with the gaming machine and the difference number becomes "-50", the player wins the AT and the AT is started. Then, after starting the advantageous section, when the advantageous section (AT) is continued until the difference number exceeds “+2400 coins”, the player Y can win the medal of “2400+250=2650 coins”. ..
Therefore, as described above, after the advantageous section is started, by setting the end condition "from the time when the difference number becomes the minimum value to the point where it exceeds "+2400"", for example, the fit amount of another player We are trying to prevent motivation by preventing them from being able to win.

In Example 2 shown in (b) of FIG. 37, the difference number decreases in the normal section, the positive point starts from the “D” point on the way, and the advantageous section starts from the “E” point. In such a case, as described above, when the difference number counter value is updated including the normal section, the difference number counter value is positive at the time of “E” in the figure. However, the difference number counter value is initialized (cleared, that is, updated to “0”) at the start of the advantageous section (“E” in the figure).
Therefore, the increment before the advantageous section (the increment from “D” to “E”) is not counted by the difference counter. Therefore, the difference counter continues to be incremented from the point “E”, and the advantageous section is ended when “2400 (D)” is exceeded.

The description returns to FIG.
The address “F067(H)” is a storage area for the AT flag (_FL_AT_KND). The AT flag is a flag for determining whether or not AT is in progress, and is set to "0" during non-AT and to "1" during AT. The timing at which the AT flag is set to "1" is when the AT lottery is won, and is executed in step S364 of FIG. 46 described later. Further, the AT flag is turned off at the end of the game in the final game of the AT, and is executed, for example, in the game end check process (step S415 of FIG. 50) described later. Further, the AT flag is included in the data that is cleared (initialized) at the end of the advantageous section.

The address "F068 (H)" is a storage area of the AT game number counter (_CT_ART). The AT game number counter is a decrement counter that counts the number of games played during AT (including ART). Unlike the advantageous section clear counter, when the AT game number counter becomes "0", the subsequent counting (subtraction) is stopped.
The AT game number counter is updated (subtracted) during AT after the start switch 41 is operated during the main processing (step S281 in FIG. 41 described later).

Further, in this embodiment, since the initial value of the AT game number may exceed "255 (D)", the AT game number counter is composed of a 2-byte counter. When the maximum number of AT games is "255 (D)" or less, the AT game number counter may be composed of a 1-byte counter.
When the AT is started (or when the AT preparation is made), an initial value is set in the AT game number counter. The initial value may be a fixed value or may be determined by lottery or the like when the AT is won. Further, after the initial value is determined, the AT game number may be updated to "0" without being changed thereafter. Alternatively, when a predetermined condition is satisfied during AT, the AT game number may be increased, and when the additional lottery is won, the AT game number may be increased. In this case, the increment is added to the AT game number counter.
This AT game number counter is also included in the data cleared at the end of the advantageous section.

In the present embodiment, since the game number management type AT is illustrated, an AT game number counter is provided. Therefore, in the case of the difference number management type AT, an AT difference number counter is provided instead of the AT game number counter. Then, at the start of the AT, the initial value of the obtainable difference number of sheets is set. In addition, when the player wins the addition, the difference number of the addition is added. Then, each time the payout is made, the difference number of the game is subtracted, and when the AT difference number counter becomes "0", the AT is ended.

Next, each process during the game will be described using a flowchart.
FIG. 38 is a flowchart showing the program start processing (M_PRG_START) by the main control board 50. When the power is turned on, the process starts from the program start process of FIG.
In FIG. 38, when the program is started in step S201, in the next step S202, the main control board 50 initializes the register. Specific processing includes, for example, setting of the communication speed of the serial communication circuit provided in the main CPU 55, setting of the type of interrupt (for example, setting to maskable interrupt, etc.), and parity bit added to the control command to be transmitted. (For example, setting to even parity). In other words, the initial values required to operate the slot machine 10 normally are set in various registers.

Next, in step S203, the main control board 50 determines whether or not the power-off processing completed flag is a normal value. In the present embodiment, the power-off processing completed flag is stored when the power is turned off (step S484 in FIG. 54 described later). The power-off processing completed flag is a flag for determining whether or not the previous power-off was normally performed when the power was turned on. When it is determined that the power-off processing completed flag is a normal value, the process proceeds to step S204, and when it is determined that the power-off process completed flag is not the normal value, the process proceeds to step S206.

In step S204, the checksum of the RWM 53 is calculated. Specifically, the checksum is calculated in the same range as the checksum of the RWM 53 executed during the power-off process (for example, the work area used by the program, the unused area, and the stack area).
In step S205, it is determined whether the range of the RWM 53 for calculating the checksum is completed. Specifically, the next address is designated from the address of the RWM 53 for which the checksum is calculated at the present time, and it is determined whether or not the next address is the address for which the checksum is calculated. If it is determined that the checksum calculation has not been completed, the process returns to step S204 and continues. On the other hand, if it is determined that the RWM 53 range for calculating the checksum is completed, the process proceeds to step S206.

Further, also in the subsequent processing, when the data stored in the plurality of ranges (addresses) of the RWM 53 is initialized, the same processing is executed in the designated range of the RWM 53 in the present embodiment.
When it is determined in step S203 that the power-off processing completed flag is not the normal value, the abnormal value is set as the power-off recovery data without executing the checksum calculation of the RWM 53.

In step S206, the main control board 50 stores the power interruption recovery data in a predetermined register (for example, B register). If it is determined that the power-off processing completed flag is a normal value and the checksum calculation (entire range) of the RWM 53 is normally completed, the normal value is stored as the power-off recovery data. On the other hand, when the power-off processing completed flag is an abnormal value (when “No” in step S203), or when it is determined that there is an abnormality during the checksum calculation (entire range) of the RWM 53 in step S204, the power-off is performed. An abnormal value is stored as return data.

In the next step S207, the level data of the predetermined input port 51 is stored in a predetermined register (for example, A register). Next, in step S208, it is determined whether or not the designated switch is on, based on the level data of the predetermined input port 51. Here, in the present embodiment, the “designated switch” means a signal of a door switch (a switch that is turned on when the front door 12 (housing) is opened) among the predetermined input ports 51, a set door switch. (The door provided on the setting key switch. Note that the setting door is not necessary.), the signal of the setting key switch (the switch that turns on when the setting key is inserted and rotated in the specified direction) There are three.

Then, the signal of the door switch is ON (the front door 12 is opened), the signal of the setting door switch is ON (the setting door is opened), and the signal of the setting key switch is ON. Only when there is permission to change the setting. When all three designated switches are on, it is possible to shift to the setting change process of step S212, but when at least one designated switch is not on, it is not permitted to shift to the setting change process of step S212. ..
That is, even when the door switch signal is off (the front door 12 is closed) or when the setting door switch signal is off (the setting door is closed), the setting key switch signal is Since it cannot be turned on and there is a high possibility of fraud, it does not allow the transition to the setting change process.

Therefore, if it is determined in step S208 that all the designation switches are on, the process proceeds to step S209, and if it is determined that they are not on, the process proceeds to step S211.
In step S209, the main control board 50 determines whether or not the power failure recovery data is abnormal. The power-off recovery data is the data stored in the register in step S206.

When it is determined that the power failure recovery data is abnormal, the process proceeds to the setting change process (M_RANK_SET) in step S212, and when it is determined that the data is not abnormal, the process proceeds to step S210. In step S210, it is determined whether the setting unchangeable flag is on. Here, the setting change impossible flag is one of the data stored in the RWM 53, and is disabled during a start switch acceptance process (step S279) to a game end check process (step S301) of FIG. 41 described later. It is a flag that is set. Then, if the setting change impossible flag is ON, the process proceeds to step S211, and if it is not ON, the process proceeds to the setting change process (M_RANK_SET) of step S212.
Although the setting change impossible flag is provided in the present embodiment, the setting change prohibition flag may not be provided if the setting change is possible at all times. In that case, the process corresponding to step S210 becomes unnecessary.

In step S211, the main control board 50 determines whether the power-off recovery data is a normal value. This process is the same process as step S209. Then, when it is determined that the power-off recovery data is a normal value, the process proceeds to step S213, and power recovery processing (M_POWER_ON) is performed. On the other hand, when it is determined that the power-off recovery data is not a normal value, an “E1” error occurs, and the process proceeds to step S214 to perform unrecoverable error processing.

39 is a flowchart showing the setting change process (M_RANK_SET) in step S212 of FIG.
First, in step S221, a "predetermined range" is stored in the register as an initialization range within the use area of the RWM 53. Here, the “in-use area” refers to an area in the storage area of the RWM 53 for storing data relating to the progress of the game. The range shown in FIG. 35 is entirely within the use area. On the other hand, “outside the used area”, which will be described later, refers to an area in the storage area of the RWM 53 for storing data unrelated to the progress of the game. Specifically, a storage area in which data relating to the display of the management information display LED 74 (role ratio monitor) is stored can be cited.

Further, the "predetermined range" is an initialization range when it is determined that the power-off process has been normally executed, and includes set value data (address "F000(H)"), a gaming state (for example, RT state), and winning. The initialization range in which the flag of the special character holding the character is not initialized is defined as a “predetermined range”.
Therefore, in a twelfth embodiment to be described later, when the power is turned off and the inside of BB2 is in progress (when the winning flag of BB2 is on), if the power is turned off normally, the setting change process is executed. However, the winning flag of BB2 is maintained.
On the other hand, the "predetermined range" does not include data regarding the advantageous section or the AT. Therefore, in FIG. 35, the addresses “F061(H)” to “F068(H)” are targets of initialization here.

Next, in step S222, the main control board 50 determines whether the power-off recovery data (the value stored in step S206) is a normal value. When it is determined that the power-off recovery data is the normal value, the process proceeds to step S224, and the storage of the "predetermined range" in step S221 is maintained. On the other hand, if it is determined in step S222 that the power failure recovery data is not a normal value, the process proceeds to step S223.
In step S223, the main control board 50 stores the “specific range” in the register as the initialization range within the use area of the RWM 53. Here, the “specific range” is an initialization range when it is determined that the power supply is not cut off normally, and is the entire range within the use area including the set value data (address “F000(H)”).

Then, the process proceeds to step S224, and initialization of the predetermined range set in step S221 or the specific range set in step S223 (within the use area of the RWM 53) is started. In the next step S225, it is determined whether or not the initialization started in step S224 is completed. When it is determined that the initialization is completed, the process proceeds to step S226.

In step S226, the AF register (A register and F register (flag register)) is saved. Although it is originally desired to save the F (flag) register in order to save the AF register, the AF register is saved for the convenience of the instruction. Then, in step S227, a predetermined range outside the used area is stored as the initialization range of the RWM 53. Further, the “predetermined range” is an initialization range when it is determined that the power-off process has been normally executed.

In the next step S228, similarly to step S222, it is determined whether the power-off recovery data (the value stored in step S206) is a normal value. When it is determined that the power failure recovery data is the normal value, the process proceeds to step S230, and the storage of the "predetermined range" in step S227 is maintained. On the other hand, if it is determined in step S228 that the power failure recovery data is not a normal value, the process proceeds to step S229.
In step S229, the main control board 50 stores the “specific range” in the register as the initialization range outside the use area of the RWM 53. Here, the “specific range” is an initialization range when it is determined that the power supply is not normally cut off, and is an entire range including a ring buffer storing the number of games and the number of payouts for displaying the ratio.
Then, the process proceeds to step S230, and initialization of the predetermined range set in step S227 or the specific range set in step S229 (outside the use area of the RWM 53) is started.

In the next step S231, it is determined whether or not the initialization started in step S230 is completed. When it is determined that the initialization is completed, the process proceeds to step S232.
In step S232, the AF register saved in step S226 is restored. In the next step S233, the start setting of interrupt processing is performed. Here, various registers corresponding to the interrupt processing designated in step S202 are set. Since the timer interrupt process is used as the interrupt process in the present embodiment, a process of setting the cycle of the timer interrupt (“2.235 ms” in the present embodiment) is included. Then, the interrupt process is executed after the process of step S233. In other words, the interrupt process is not executed before the "interrupt activation".
In the next step S234, an output request set at the start of setting change is set. This process is a process of setting (storing) a control command to be transmitted to the sub control board 80 in the register in order to notify the sub control board 80 side that the setting change processing is started.

The “output request set” means a process of setting a control command to be transmitted to the sub control board 80. Further, the control command here does not mean only a command to be actually transmitted, but also a command which is a source of the command to be actually transmitted.
Next, proceeding to step S235, the main control board 50 executes the control command set 1. This process is a process of storing a control command to be transmitted to the sub control board 80 in the control command buffer (RWM 53).

Next, proceeding to step S236, the main control board 50 executes a 2-byte time waiting process (wait process) for starting the setting change. In the present embodiment, the process waits until the number of interrupts “224” is counted (“1” is subtracted for each number of interrupts and the set number of interrupts becomes “0”). This waiting is also called delay processing or waiting processing because the main processing is not advanced. During this waiting time (during the 2-byte time waiting process), the main process is prevented from proceeding, but the interrupt process is executed.

In this way, the 2-byte time waiting process (wait process) is executed in step S236 because the initialization process of the RWM 53 on the main control board 50 side is completed in a relatively short time, while the sub control board 80 side is completed. Since it takes a long time to initialize the RWM 83, the 2-byte time waiting process is executed on the main control board 50 side. In particular, the main control board 50 side cannot know whether or not the initialization process is completed on the sub control board 80 side.

Therefore, while the sub control board 80 side is still in the initialization process, the main control board 50 side has already completed the initialization, and the process is further advanced. It is possible to prevent the progress of the control processing of 80 from becoming out of synchronization.
Further, after the output request set and the control command set 1 at the time of starting the setting change are executed, the sub control board 80 starts the initialization of the RWM 83, but a sufficient time is set as the wait time for the initialization of the RWM 83 to end. To do. As a result, after the initialization processing of the RWM 83 is completed on the sub control board 80 side, the main control board 50 side proceeds to the processing of step S238 and thereafter.

The control command at the time of starting the setting change set in steps S234 and S235 is transmitted to the sub control board 80 even during the 2-byte time waiting process of step S236. However, while the 2-byte time waiting process is being executed in step S236, the process after step S237 does not proceed (the main process does not proceed).

After the 2-byte time waiting process in step S236 is completed, the process advances to step S237 to store the setting change display data as the acquired number data. Next, proceeding to step S238, the value "00011100(B)" corresponding to the setting being changed is stored in the LED display request flag.

By the processes of steps S237 and S238, when the interrupt process is executed after these processes, the digits 3a, 4a, and 5b (the acquired number display LED 78 and the set value display LED 73) can be turned on.
Specifically, in the interrupt processing executed after the processing of step S238, “8” can be displayed on each of the digits 3a and 4a (“88” is displayed on the acquired number display LED 78), and the digit b5 (set value display) can be displayed. The current set value can be displayed on the LED 73).
Since the acquired number data and the LED display request flag have been initialized by the initialization processing in the usage area of the RWM 53 in step S224, the value before step S237 is “0”.

Next, proceeding to step S239, interrupt waiting processing is executed. This process is a process of waiting until one interruption time (2.235 ms) elapses. Then, after the lapse of one interruption time, the process proceeds to step S240.
In step S240, it is determined whether the operation of the setting change switch (not shown in FIG. 1) has been detected. Here, it is determined whether or not the setting change switch is turned on by determining the rising data of the input port 51 including the setting change switch. When it is determined that the operation of the setting change switch is detected, the process proceeds to step S241, and when it is determined that the operation is not detected, the process proceeds to step S242.
In step S241, the set value data (address "F000(H)") of the RWM 53 is stored (updated). When the interrupt process is executed after the set value data is updated, the set value display LED 73 displays the updated value.

In the next step S242, it is determined whether or not the operation of the start switch 41 is detected. In this embodiment, when the start switch 41 is operated during the setting change, the set value at that time is fixed.
When it is determined that the start switch 41 has been operated, the process proceeds to step S243, and when it is determined that it has not been operated, the process returns to step S239.

In the above processing, step S239 (waiting for an interrupt) is provided to clear the rising data of the setting change switch.
For example, if the process of step S239 is not provided and the rising data of the setting change switch is determined to be on in step S240, the set value data is updated in step S241, and the start switch 41 is turned on in next step S242. If not, the process proceeds to step S240, and it is determined whether or not the rising data of the setting change switch is ON.

If it is determined in step S240 that the switch is on, the rising data of the setting change switch is turned off if the interrupt process is executed even once. However, until the interrupt process is executed, it is continuously determined in step S240 that the rising data of the setting change switch is ON. As a result, even if the setting change switch is operated once, the set value data continues to rise by "2" or more. Therefore, in step S239, interrupt waiting processing is executed.

In step S243, it is determined whether the setting key switch (not shown in FIG. 1) has been turned off. If it is determined that the setting key switch has been turned off, the process proceeds to step S244, and the acquisition number data is cleared (set to "0"). This is because the display of "88" indicating that the setting is being changed is erased. Next, proceeding to step S245, the value "00011111(B)" corresponding to normal is stored in the LED display request flag.

Due to the interrupt processing executed after the processing of step S244, the display of the digits 3a and 4a (acquired number display LED 78) changes from "88" to "00".
Further, by the interrupt processing executed after the processing of step S245, "0" is displayed on each of the digits 1a and 2a ("00" is displayed on the credit number display LED 76). Further, since the bit corresponding to the digit 5 of the LED display request flag is "1", the digit 5a (state display LED 79) can be turned on. On the other hand, the digit 5b (setting value display LED 73) does not light up because the setting is not being changed or the setting is not being confirmed.

Next, the process proceeds to step S246, and similarly to step S234, the output request set at the end of the setting change is set. In this process, the setting change process is terminated, and the data corresponding to the determined setting value (specifically, the setting value data stored in the address “F000(H)”) is sent to the sub-control board 80 side. This is a process of setting a control command to be notified to. Next, proceeding to step S247, the main control board 50 executes the control command set 1 as in step S235. Then, the process proceeds to step S248 and shifts to the main process (M_MAIN).

FIG. 40 is a flowchart showing the power restoration process (M_POWER_ON) of step S213 in FIG.
First, in step S251, the stack pointer (SP register) is restored. Here, the stack pointer is an area (stack area) of the RWM 53 that saves data (for example, register values, instruction processing of main processing before interrupt processing) at the time of power failure when power failure occurs. Of these, the one indicating the area (address) to be stacked next is indicated.
In the next step S252, the set value data is read and whether the range of the set value data is the normal range (whether it is within the range of set value 1 to set value 6), in other words, "F000 (H)" It is determined whether or not the set value data is within the range of "0 (H)" to "5 (H)". When it is determined that the set value data is within the normal range, the process proceeds to step S253, and when it is determined that the set value data is not within the normal range, an "E6" error occurs, the process proceeds to step S264, and the non-recoverable error process is performed. ..

In step S253, an unused area in the used area of RWM 53 is set in the register as an initialization range. Then, in the next step S254, the RWM 53 in the range set in step S253 is initialized. Here, it is conceivable that the value will be stored in the RWM 53 due to noise or the like even in an unused area. If a value is stored in the unused area, it may lead to fraudulent activities, so the unused area should be initialized when the power is turned on (normally once a day). There is.
In the next step S255, it is determined whether or not the initialization of the RWM 53 (unused area in the used area) is completed, and if it is determined that the initialization is completed, the process proceeds to step S256.

In step S256, the AF register is saved. This process is similar to the process of step S226 described above. In the next step S257, the initialization range of the unused area outside the used area of the RWM 53 is set in the register. Then, in the next step S258, the RWM 53 in the range set in step S257 is initialized.
In the next step S259, it is determined whether or not the initialization (unused area outside the used area) of the RWM 53 has been completed. In step S260, the AF register is restored. This process is similar to the process of step S232 described above.

In the next step S261, a predetermined input port 51 is read. This process is a process for updating each data (level data, rising data, falling data) of the input port 51 before power-off to the latest data.
Next, in step S262, an interrupt is activated. This process is, for example, a process of setting the cycle of the timer interrupt, and is similar to the above-described step S233.
Next, proceeding to step S263, the power-off processing completed flag is cleared, that is, set to "0". Then, the processing according to this flowchart is ended.

In the above program start processing, setting change processing, and power restoration processing,
1) In the program start process of FIG. 38, if it is determined to be "No" in step S203 (when the power-off process completed flag is an abnormal value) or there is an error in the checksum calculation of step S204, In S206, the abnormal value is stored as the return data after power failure. In this case, since “Yes” is determined in step S209, the process proceeds to the setting change process (FIG. 39) in step S212.
Then, in the setting change process of FIG. 39, since “No” is determined in step S222 and step S228, initialization of the entire range inside and outside the use area of the RWM 53, that is, “F000(H)” and thereafter All data in is initialized.

2) In the program start process, when the power-off process completed flag is determined to be a normal value and the checksum calculation is also normally performed, when the setting change process is performed, step S222 and step in FIG. Since it is determined to be “Yes” in S228, the process proceeds to step S224 and step S230, respectively, and the designated range (inside the used area and outside the used area) of the RWM 53 is initialized.

3) In the program start process, when the power-off process completed flag is determined to be a normal value and the checksum calculation is also normally performed, but the setting change process is not performed, the power recovery process of step S213 ( 40). In this case, if the setting value is normal in step S252 in FIG. 40, the initialization (inside and outside the use area) of the RWM 53 at the time of normal power-on is executed. This initialization is processing for initializing the unused area of the RWM 53, as described above.

FIG. 41 is a flowchart showing the main processing (M_MAIN) in this embodiment. The main process is the process of one game. While the game is in progress, each game and main processing are repeated.
First, in step S271, the stack pointer is set. As described above, the stack pointer refers to an area of the RWM 53 that saves data (for example, register value, instruction processing of main processing before interrupt processing) at the time of power failure when power failure occurs, The setting of the stack pointer is a process of setting the register value to the initial value in the area of the RWM 53.

In the next step S272, game start set processing (M_GAME_SET) is performed. This process is a process shown in FIG. 42, which will be described later, and is a process of generating, updating, saving, and the like of the operation state flag.
In the next step S273, bet medals are read. This process is a process of reading how many medals are bet at the present time, and reads bet number data or automatic bet number data.
In the next step S274, the presence or absence of a bet medal is determined based on the bet number read in step S273.

If it is determined in step S274 that there is a bet medal, the process proceeds to step S276, and if it is determined that there is no bet medal, the process proceeds to step S275 to perform a medal insertion waiting process, and then proceeds to step S276. In the medal insertion waiting process of step S275, it is determined whether or not the setting key switch is ON, and when it is ON, a process such as shifting to the setting confirmation mode is performed.
In step S276, management processing of inserted medals is performed. This process is a process of determining whether or not the medal has been cared for, determining whether or not the settlement switch 43 has been operated, and the like.

In the next step S277, soft random number update processing is performed. This process is a process of updating (for example, adding "1" each) a processing random number for processing (arithmetic processing) into a random number (hard random number or built-in random number) used in the winning combination lottery means 61. The soft random number is a 16-bit random number having a range of "0" to "65535(D)". As an update method, a process of adding an interrupt count value (a count value (variable) incremented at the time of interrupt) to the value before update may be executed.

In the next step S278, the main control board 50 determines whether or not the start switch 41 has been operated. If it is determined that the start switch 41 has been operated, the process proceeds to step S279, and if it is determined that the start switch 41 has not been operated, the process returns to step S273. Even if the start switch 41 is operated, if the bet number has not reached the specified number for the game, it is determined as “No” in step S278.

In step S279, the processing when the start switch is received is executed. This process is a process of setting a non-changeable setting flag, setting an output request at the start of rotation of the reel 31, and setting the number of outputs for outputting a medal insertion signal as an external signal to a hall computer or the like. ..
In the next step S280, the acquired number data is cleared. Therefore, when the start switch 41 is operated, even if the specified prescribed number display data and the payout amount data are stored as the acquired number data before that, it is cleared.
Here, although the details will be described later, in the twelfth embodiment, the specified number may be instructed (displayed) on the acquired number display LED 78 before the game starts. Therefore, when the start switch 41 is operated, the specified prescribed number display data may be stored as the acquired number data. Therefore, when the start switch 41 is operated, the acquired number data is cleared, and a process of displaying "00" on the acquired number display LED 78 (or turning off the light) is executed.
Further, at the time of step S280, when the payout amount data of the previous game is stored as the acquisition amount data, the payout amount data is cleared in this step S280.

Next, proceeding to step S281, the main control board 50 executes an AT game number update process. This process is a process shown in FIG. 43 which will be described later, and is a process of subtracting the number of AT games when the predetermined condition is satisfied during AT. Therefore, this process is not executed during non-AT.
Further, whether or not to increase the number of AT games during AT is determined based on the winning combination lottery result of the winning combination lottery process in step S282. For example, when the player has won a rare role, it is possible to determine the number of additional games to be added to the AT. Therefore, when the AT game number is added and the added amount is added to the AT game number counter, it is executed after the process of step S282 (not shown in FIG. 41).
After the start switch is received (step S279), the AT game number counter is updated in step S281. However, the present invention is not limited to this. After the role lottery process in step S282 or after all reels 31 are stopped (step S290 and thereafter) You may update the AT game number counter.
When the AT difference number counter is provided in the specification of the difference number management AT, the AT difference number counter is provided after all reels 31 have stopped and after the medal payout process due to winning is completed (after step S300). To update.

In step S282, the combination lottery means 61 executes the combination lottery (corresponding to the above-mentioned “internal drawing”) at the timing when the start switch 41 is operated, that is, when the operation signal of the start switch 41 is received. In addition, the random number value at the time of the lottery is acquired in step S279. Then, in step S282, it is determined whether or not the acquired random number value is a random number value corresponding to any winning combination by using the combination lottery table.

In the next step S283, the main control board 50 executes an advantageous section transition lottery process. This process is a process of FIG. 44 described later. In the present embodiment, the AT lottery is also executed when performing the advantageous section transition lottery. As will be described later with reference to FIG. 44, when in an advantageous section but not in AT (for example, when the main gaming state is CZ), in step S348 in FIG. 44, AT lottery processing is executed.
Next, proceeding to step S284, a push order instruction number set (M_ORD_INF) is performed. This process is the process shown in FIG. 48. When the instruction function is activated in the game during AT (when the push order instruction number is displayed on the acquired number display LED 78), the push order instruction number is generated, This is a process of displaying the push order instruction information.

In the next step S285, a reel rotation start preparation process is executed. This process executes a process of determining whether or not the minimum game time (4.1 seconds) has elapsed, and if the minimum game time has elapsed, the process proceeds to the next step S286.
Here, the RWM 53 is provided with an area for storing the timer value of the minimum game time (not shown in FIG. 35), and the initial value is “1834 (D) (2.235 ms×1834≈4099 ms)”. Is. When it is determined in step S279 that the minimum game time is "0", the initial value "1834(D)" is set as the minimum game time (timer value). Then, the minimum game time is subtracted by "1" for each interrupt process. When proceeding to step S285 of the next game, it is determined whether or not the minimum gaming time is "0", and when it is determined to be "0", processing proceeds to step S286.

In step S286, the reel control means 65 drives and controls the motor 32 and starts the rotation of the reel 31. Then, when the reel 31 reaches the constant speed state, the operation acceptance of the stop switch 42 is permitted, and the process proceeds to step S287.
In step S287, stop acceptance of the reel 31 is checked. Here, it is detected whether or not the operation signal of the stop switch 42 is received, and when the operation signal is received, the reel 31 corresponding to the stop switch 42 is based on the lottery result of the winning combination and the position of the reel 31. The stop position is determined, and the reel 31 is controlled to be stopped at the determined position.

In the next step S288, the reel control means 65 checks whether or not all reels 31 have stopped, and proceeds to step S289. In step S289, it is determined whether or not all reels 31 have stopped. If it is determined that all reels 31 have stopped, the process proceeds to step S290, and if it is determined that all reels 31 have not stopped, the process returns to step S287. ..

In step S290, the acquired number data is cleared (set to "0"). For example, during AT, the pushing number instruction information (for example, “=1”) may be displayed on the acquired number display LED 78 by activating the instruction function. In this case, the display of the acquired number display LED 78 becomes "00" by the interrupt processing executed after the processing of step S290.
The acquired number display LED 78 may be turned off. Specifically, “00010011(B)” may be stored in the LED display request flag, or data for turning off may be provided as segment data and the data may be output.

In step S291, the display of the symbol is determined. Here, the winning determination means 66 determines whether or not the symbol combination corresponding to the winning combination has stopped on the activated line.
In the next step S292, it is determined whether or not a display error of the symbol has occurred. When it is determined that the display error has occurred, the process proceeds to step S304, and when it is determined that the display error has not occurred, the process proceeds to step S293. move on.
Here, since the reel 31 is stopped based on the stop position determination table, normally, the reel 31 does not stop at a position other than the position determined by the stop position determination table. However, as a result of the display determination of the symbol, when the symbol (kicking symbol) which should not be originally displayed is displayed on the activated line, it is determined to be abnormal (“E5” error), and the process proceeds to step S304. Performs non-recoverable error handling.

When it is determined in step S292 that no display error has occurred and the process proceeds to step S293, the payout amount update process is executed. This process is a process of storing the number of payouts in the game as the number-of-payouts data and the number-of-payouts data buffer described above.
In the next step S294, the payout means 67 pays out the medals corresponding to the winning combination (M_WIN_PAY). This process is a process shown in FIG. 49 described later. Next, proceeding to step S295, interrupt waiting processing is performed. In the next step S296, interrupt processing is prohibited. By the processing of these steps S295 and S296, the interrupt is prohibited immediately after the interrupt.

In the next step S297, the AF register is saved. This process is similar to step S256 of FIG. Next, proceeding to step S298, a ratio setting process is executed. The "ratio setting process" is a process of updating various counter values and performing ratio calculation in order to display five types of ratios on the management information display LED 74 (role ratio monitor). Then, when the process proceeds to step S299, the AF register saved in step S297 is restored, and the interrupt is permitted (restarted) in the next step S300. In this way, when the ratio setting process is executed, the AF register is saved and the interrupt process is prohibited before execution.

Note that interrupt processing is prohibited during execution of the ratio setting process because the ratio setting process is a process that uses a program stored outside the used area, and when a program outside the used area is being executed in the main process. This is because if interrupt processing is entered in, the programs in the used area and the programs outside the used area are mixed, and the processing becomes complicated.

Next, proceeding to step S301, game end check processing (_M_GAME_CHK) is performed. This process is a process shown in FIG. 50, which will be described later, and performs a condition device (winning combination) flag clearing process and the like. Then, the process proceeds to step S302, the output request set at the end of the game, and the control command set 1 at the next step S303. These processes are processes for setting control command data for transmitting to the sub-control board 80 that one game has ended.
When the process of step S303 is completed, the process returns to the beginning of the main process (step S248).

FIG. 42 is a flowchart showing the game start set processing (M_GAME_SET) in step S272 in FIG.
First, in step S311, the game standby display time is set (stored in a predetermined storage area (not shown in FIG. 35) of the RWM 53). Since the game standby display time of this embodiment is set to the interrupt of "26846" (≈60,000 ms, that is, about 60 seconds (1 minute)), "26846" is set in the predetermined storage area of the RWM 53. When the game standby display time is set in step S301, the value is decremented by "1" for each interrupt process from this point.

When the game standby display time becomes "0", the acquired number data is cleared in step S275 (waiting for medal insertion) in FIG. As a result, “00” is displayed on the acquired number display LED 78. For example, even if the number of medals paid out to the game last time is "8" and the player has settled by operating the settlement switch 43 and finished the game, "00" is displayed after about 1 minute. To be done. As a result, the clerk in the hall or another player can recognize the vacant table, so that the vacant table can be reduced.
The acquired number display LED 78 is not limited to displaying "00", and the acquired number display LED 78 (upper digit and lower digit) may be turned off, or the upper digit of the acquired number display LED 78 may be turned off and the lower digit. May be displayed as "0". In any case, the display may be executed so that the clerk in the hall or another player can recognize it as an empty table.

Next, the process proceeds to step S312, and initialization processing of the push order instruction number is executed. This process is a process of clearing the push order instruction number stored in the predetermined storage area of the RWM 53.
In the next step S313, the data of the symbol combination display flag is acquired. In the next step S314, it is determined whether or not the 1BB operation symbol is displayed. In this process, when the D2 bit corresponding to 1BB in the data of the symbol combination display flag is "1", it is determined as "Yes", and when it is "0", it is determined as "No". When it is determined that the 1BB operation pattern is displayed, the process proceeds to step S315, and when it is determined that it is not displayed, the process proceeds to step S316.

In step S315, the number of coins that can be acquired during 1BB operation (during 1BB game) is stored. This process is a process of storing the maximum number of coins that can be acquired in the 1BB game in a predetermined storage area (not shown in FIG. 35) of the RWM 53. Then, the process proceeds to step S316.
In step S316, an operating state flag is generated. This process is a process of generating the value of the operation state flag based on the symbol combination display flag.
Further, in the next step S317, the operation state flag is updated, and in the next step S318, the operation state flag is stored. This process is a process of storing the generated operation state flag (stored in, for example, the A register at this point) in the address “F030(H)” of the RWM 53. As a result, the information on the operating state flag up to that point is replaced with the information on the operating state flag updated in step S317.
For example, when the symbol combination of 1BB is displayed (at the time of winning 1BB), the D2 bit corresponding to 1BB of the operating state flag is changed from "0" to "1".

In the next step S319, it is determined whether or not the RB operation has started. In the present embodiment, in the 1BB game, the RB operation flag is turned off (“0”) at the end of the 2 game (or at the time of winning twice), but when the ending condition of the 1BB game is not satisfied ( When the D2 bit corresponding to 1BB of the operation state flag is "1"), it is set to "1" in this game start set processing. When it is determined in step S319 that the RB operation is started, the process proceeds to step S320, and when it is determined that the RB operation is not started, the process proceeds to step S321.

In step S320, the number of games played and the number of wins during RB operation are stored. This process stores (stores) "2 (H)" in the game number counter (not shown in FIG. 35) at the time of RB operation provided in the RWM 53, and at the time of RB operation provided at the RWM 53. This is a process of storing (storing) "2(H)" in the winning number counter (not shown in FIG. 35). Then, the process proceeds to step S321.

Both of the game number counter during RB operation and the prize number counter during RB operation are set to "2 (H)" as an initial value, and each time the game number or the prize number increases by "1". The counter is decremented by "1". However, not limited to this, the initial value of these counter values is set to “0”, incremented by “1” each time the number of games or winnings is increased by “1”, and these counter values are set to “2( H)” may be determined.

In the next step S321, it is determined whether or not the condition for instructing the specified number is satisfied. Here, in the eleventh embodiment, there is no case where the specified number is designated. However, in a twelfth embodiment described later, the specified number may be instructed at the start of the game, and therefore this process is included in this flowchart. If it is determined that the condition for instructing the specified number is satisfied, the process proceeds to step S322, and if it is determined that the condition for instructing the specified number is not satisfied, the process proceeds to step S323.
In step S322, the specified prescribed number display data is stored as the acquired number data. In the twelfth embodiment, there is a case where the prescribed number "2" is instructed, and when the prescribed number "2" is instructed, "0A" is displayed on the acquired number display LED 78. Then, the specified prescribed number display data for displaying "0A" is defined as "0B(H)" (details will be described later), and in this step S322, "0B(H)" is obtained as the acquired number data. Memorize
Further, when displaying the specified number “2”, “0A” is displayed instead of “02” in order not to be confused with the payout amount, the error number, and the pushing order instruction information.
The display of the number of payouts is any of "01" to "15", and "A" is not displayed in the lower digit. Also, regarding the error number, "A" is not displayed in the lower digit.

Here, the error numbers (the numbers displayed on the acquired number display LED 78 when an error occurs) in this embodiment are as follows.
HP: Medal jam error HE: Empty medal error (no medals in hopper 35)
H0: Abnormality of payout sensor 37 CE: Error of retaining medal CP: Error of illegal passage of medal CH: Abnormality of passage sensor 46 C0: Abnormality of insertion sensor 44 C1: Abnormal insertion error of medal FE: Sub tank (not shown in FIG. 1) Full dE: Opening the front door E1: Power failure recovery error E5: Display judgment error E6: Setting error E7: Random number error

The type of error is not limited to the above. An error in which the upper digit of the error number is "E" means a non-recoverable error.
As described above, since "A" is not displayed in the lower digit of the error number, the error number and the specified prescribed number are not confused.
Further, the push order instruction information displayed on the acquired number display LED 78 by the operation of the instruction function is “=1” to “=6”. Therefore, the pushing order instruction information and the prescribed instruction number are not confused.

Further, in step S322, the payout amount data in the previous game may be stored as the acquisition number data before the instruction prescribed number display data is stored as the acquisition number data (when a small winning combination is won in the previous game). ). The payout amount data is stored in step S399 of the medal payout process by winning (FIG. 49 described later). Therefore, when the specified prescribed number display data is stored, it may be overwritten on the payout amount data up to that point. However, not limited to this, a process of clearing the acquired number data may be provided before step S322 (for example, immediately before step S311).

In the next step S323, based on the symbol combination display flag acquired in step S313, it is determined whether or not the symbol combination of the replay is stopped and displayed. When it is determined that the replay symbol combination is stopped and displayed, the process proceeds to step S324, and when it is determined that the replay symbol combination is not stopped and displayed, the process proceeds to step S326.

In step S324, the main control board 50 reads a bet medal. This process is a process of reading the number of medals previously bet in the game (bet number data). Next, in step S325, the automatic bet amount data is set. This process is a process of storing the bet number read in step S324 in the automatic bet number data.
Next, proceeding to step S326, an output request for the operating state is set. In the next step S327, the control command set 1 is executed. Specifically, information indicating that the replay has been activated, that the 1BB has been activated, etc. is transmitted to the sub-control board 80. Then, the processing according to this flowchart is ended.

It should be noted that the former (meaning before the application of the present application, and does not mean “publicly known”; the same applies hereinafter) is performed in the step S276 during the process of adding the bet number, specifically, during the main process of FIG. In the medal management process, the process of clearing the acquired number data was executed. As a result, even if the small winning combination was won in the previous game and the payout amount data at the time of winning the small winning combination was stored as the winning number data, the winning number data was cleared during the bet number addition process.
However, in the present embodiment, before the medal management process is executed, if the condition for instructing the prescribed number is satisfied, the indicated prescribed number display data is stored as the obtained number data.
When the specified number is specified, it is necessary to prevent the specified specified number display data from being cleared during the bet processing. This is because in the present embodiment, when the prescribed number is instructed, the state in which the prescribed number is instructed is maintained at least until the start switch 41 is operated.
Therefore, in the present embodiment, the acquisition number data is not cleared in the medal management process, and when the start switch 41 is operated, the acquisition number data is cleared in the process of step S280 in FIG.

However, not limited to this, when the specified number is instructed, the instructed specified number display data is cleared after the start switch 41 is operated, but when the specified number is not instructed, the bet number addition processing is performed as before. The acquired number data may be cleared (in the medal management process). In this case, for example, in the process of adding the bet number, it is determined whether or not the specified number is instructed in the game this time before the clearing process of the acquired number data is performed, and it is determined that the specified number is instructed. Is to not clear the acquired number data, and to clear the acquired number data when it is determined that the specified number is not instructed.

FIG. 43 is a flowchart showing the AT game number counter updating process in step S281 in FIG.
First, in step S331, it is determined whether the AT flag is on ("1"). When it is determined that the AT flag is on, the process proceeds to step S332, and when it is determined that the AT flag is not on, the process according to this flowchart ends. That is, if it is not AT, the AT game number counter is not updated.

In step S332, it is determined whether or not the bet number is "3". In this processing, the bet number data of the RWM 53 or the automatic bet number data is read, and it is determined whether or not the bet number of the game is "3". When the bet number is "3", the process proceeds to step S333, and when the bet number is not "3", the process according to this flowchart is finished. In the present embodiment, the AT game number counter is updated (the process relating to the instruction function is executed) only when the game is played with the bet number (specified number) “3” in the AT. In other words, even during AT, when the game is started with the bet number (specified number) “2”, the AT game number counter is not updated.
On the other hand, as will be described later, the advantageous section clear counter and the difference number counter are updated regardless of the bet number.

When proceeding to step S333, the main control board 50 subtracts "1" from the value of the AT game number counter. Then, the processing according to this flowchart is ended.
In the case of the difference number management type AT, when the AT difference number counter is provided, similarly, the AT difference number counter is not subtracted (updated) when the bet number is not “3” even during AT.

FIG. 44 is a flowchart showing the advantageous zone transition lottery processing in step S283 in FIG.
In the present embodiment, the AT lottery processing (step S348) is provided in the advantageous zone transition lottery processing, but the present invention is not limited to this, and the advantageous zone transition lottery processing and the AT lottery processing are executed independently. May be. For example, in FIG. 41, step S283 may be limited to the advantageous section transition lottery process, and the AT lottery process may be executed after step S283.
First, in step S341, it is determined whether or not the bet number (specified number) of the current game is "3". When it is determined that the bet number is "3", the process proceeds to step S342, and when it is determined that the bet number is not "3", the process according to this flowchart is ended.
Therefore, when the bet number (prescribed number) is “3”, it is possible to execute the advantageous section transition lottery in step S345 and the advantageous section transition processing (processing relating to the advantageous section) in step S347, which will be described later, and step S348. The AT lottery process (the process related to the instruction function) can be executed. However, when the bet number (specified number) is not "3", these processes are not executed.

In step S342, it is determined whether the advantageous section type flag is "0". When it is determined that the advantageous zone type flag is “0” (which is a non-advantageous zone), the process proceeds to step S343, and when it is determined that the advantaged zone type flag is “1” (which is an advantageous zone), step S348. Proceed to. When the advantage zone type flag is "1" (when the advantage zone is already in progress), the advantage zone transition lottery is not performed, but the AT lottery is performed.

In step S343, it is determined whether or not the winning combination lottery result in the game this time is the target winning lottery result, that is, whether the winning combination of the winning combination in the advantageous section has been won. Although a detailed description is omitted here, for example, when the special winning combination is individually won, when the special winning combination and the small winning combination are repeatedly won, and when the small winning combination (rare small winning combination) is won, the target lottery result is obtained. to decide. The target lottery result does not include non-win. This is because, in the non-winning game of the winning combination (the game in which the condition device is inoperative), the processing relating to the advantageous section is not executed.
When it is determined in step S343 that the target lottery result is obtained, the process proceeds to step S344, and when it is determined that the target lottery result is not obtained, the processing according to this flowchart is ended (that is, the advantageous section lottery is not performed or the advantageous section is not selected). To win).

In step S344, it is determined whether the target lottery result is the specific lottery result. Here, although detailed explanation is omitted, for example, among the lottery-winning roles, the middle-tier cherry (single win or double win with the special win) is set as the definite win (winning win) in the advantageous zone transition lottery. Every other time, when the middle-tier cherry is won, it is considered that the result is a specific lottery result.
When it is determined in step S344 that the result is the specific lottery result, the process proceeds to step S347, and when it is determined that the result is not the specific lottery result, the process proceeds to step S345. In other words, when it is not the specific lottery result, the advantageous section transition lottery is performed, and when it is the specific lottery result, the advantageous section transition process (step S347) is executed without performing the advantageous section transition lottery (always shift to the advantageous section). To). It is also possible to execute the advantageous section transition lottery even with the specific lottery result, and set to win the advantageous section transition lottery with a probability of 100%.

In step S345, an advantageous section transition lottery is performed. As the advantageous section transition lottery, for example, a lottery may be performed in the same manner as the role lottery by using a lottery table in which the number of characters corresponding to the result of the lottery is predetermined. For example, if the winning number is "A", there is a 35% chance of winning the advantageous section, and if the winning number is "B", there is a 60% chance of winning the advantageous section, and so on. Is mentioned.
If the winning combination lottery result is not the lottery target of the advantageous section, the result is “No” in step S343. Therefore, if the result of step S343 is “Yes”, that is, the winning combination lottery result is the subject of the advantageous section transition lottery. In this case, the lottery is carried out in the advantageous section transition lottery by the lottery table having at least "1" or more. However, the winning probability of the advantageous section transition lottery is set to "1/17500" or more.

Next, proceeding to step S346, it is determined whether or not the advantageous section has been won in the lottery at step S345. If it is determined that the advantageous zone has been won, the process proceeds to step S347, and if it is determined that the advantageous zone has not been won, the process according to this flowchart ends.
In step S347, an advantageous section transition process is executed. This process is the process shown in FIG. 45, and is the process of setting flags and counters based on the winning of the advantageous section.
In the next step S348, AT lottery is performed. This processing is the processing shown in FIG. Then, the processing according to this flowchart is ended.
Not limited to the example of the present embodiment, AT may be always started (without performing AT lottery) when shifting to the advantageous section. Alternatively, a non-AT may always be set when shifting to the advantageous section, and after shifting to the advantageous section (for example, after a predetermined number of games have been exhausted), whether or not to execute AT may be drawn by lottery.

FIG. 45 is a flowchart showing the advantageous zone transition processing in step S347 of FIG.
First, in step S351, the main control board 50 turns on the advantageous zone type flag (“1”). Next, proceeding to step S352, the main control board 50 sets the advantageous zone clear counter to the advantageous zone initial value "1500 (D)".

In the next step S353, "0" is set in the difference number counter. The difference counter is continuously updated even during the normal section (non-advantageous section), and when it is not the advantageous section, if "0" is always set at the end of the game, the process of step S353 is unnecessary. However, the initial value “0” may be set for noise prevention and the like.
Since the initialization process including the difference counter is executed at the end of the advantageous section, the difference counter is "0" at the start of the normal section. Therefore, in the case of the specification in which the difference counter is updated only during the advantageous period, the difference counter at the start of the advantageous period is "0", and thus the process of step S353 can be omitted. ..
On the other hand, when the difference number counter is continuously updated during the non-advantageous section as in the present embodiment, the difference number counter may be positive even immediately before the transition to the advantageous section. Therefore, in step S353, the difference counter is set to "0". Then, the processing according to this flowchart is ended.

FIG. 46 is a flowchart showing the AT lottery process in step S348 of FIG.
First, in step S361, AT lottery is executed based on the winning combination lottery result. In this lottery, similar to step S345, AT lottery is performed using a lottery table in which the number of winning prizes is set for each winning combination lottery result.
Note that the AT lottery does not necessarily have to be executed, and, for example, a winning combination lottery result that is not determined by the AT and a winning combination lottery result that is always determined by the AT may be provided.
In the next step S362, the main control board 50 determines whether or not an AT is won in the AT lottery in step S361. If it is determined that the AT is won, the process proceeds to step S363, and if it is determined that the AT is not won, the process proceeds to step S365.

In step S363, the main control board 50 executes AT initial game number determination processing. This process is a process shown in FIG. 47 described later. Next, proceeding to step S364, the main control board 50 sets the main game state to AT and turns on the AT flag. Then, the processing according to this flowchart is ended.
Here, the main game state of the present embodiment includes normal (non-advantageous section), CZ (advantageous section and non-AT), AT, and 1BB operation. Although it is possible to set a sign as a main game state after winning the AT and before starting the AT, in the present embodiment, for simplification of the description, when the AT is won, the AT is started immediately. And The information on the main gaming state is stored in a predetermined area (not shown in FIG. 35) of the RWM 53.
On the other hand, if it is determined in step S362 that the AT has not been won and the process proceeds to step S365, the main control board 50 sets the main gaming state to CZ. Then, the processing according to this flowchart is ended.

FIG. 47 is a flowchart showing the AT initial game number determination processing in step S363 in FIG.
In FIG. 47, in a step S371, it is determined whether or not the winning combination lottery result in the current game is the winning of the confirmed winning combination. As described above, a rare winning combination such as a middle-tier cherry is set as the definite winning combination. If it is determined that the winning combination has been won, the process proceeds to step S372, and if it is determined that the winning combination has not been won, the process proceeds to step S373.
In step S372, the initial number of AT games is set to "100 (D)" and stored in the AT game number counter. On the other hand, in step S373, the initial number of AT games is set to "30 (D)" and stored in the AT game number counter. Then, the processing according to this flowchart is ended.

Note that, in the example of FIG. 47, the specification is such that the number of AT initial games is distributed according to whether or not a final winning combination is won, but the present invention is not limited to this, and the number of games played is determined using a lottery table based on the winning combination lottery result. You may perform a lottery. In other words, even with one winning combination lottery result, any number of games may be selected from a plurality of games.
Further, even during AT, the AT game number determination process shown in FIG. 47 may be executed as an additional lottery for the AT game number. When the player has won the AT game number addition lottery, the determined addition number is added to the AT game number counter.

FIG. 48 is a flowchart showing the pushing order instruction number setting process (M_ORD_INF) in step S284 of FIG.
First, in step S381, it is determined whether or not the instruction condition (condition for operating the instruction function) is satisfied. When the game is AT and a winning combination having an advantageous pressing order such as a pressing order bell is won, it is determined that the instruction condition is satisfied.
When the advantageous section is won in this game (“Yes” in step S346 in FIG. 44) and the AT is won (when “Yes” in step S362 in FIG. 46), the advantageous section starts from the next game. This time, the game is not an advantageous zone. Therefore, since the instruction function cannot be operated in the game this time, “No” is obtained in step S381.
When it is determined in step S381 that the instruction condition is satisfied, the process proceeds to step S382, and when it is determined that the instruction condition is not satisfied, the process according to this flowchart ends.

In the next step S382, it is determined whether or not the bet number of the current game is "3". In this processing, it is determined whether or not the bet number is "3" by reading the bet number data of the RWM 53 or the automatic bet number data.
When it is determined that the bet number is "3", the process proceeds to step S383, and when it is determined that the bet number is not "3", the process according to this flowchart is ended. As described above, in the present embodiment, the condition for operating the instruction function (performing the processing related to the instruction function) is set to be the bet number “3” (one specified number). Therefore, for example, even when a game is started with a bet number of "2" during AT and a winning combination having a favorable pressing order (for example, a pressing order bell) is won, the instruction function does not operate (the correct pressing order is Not notified).

In the next step S383, the winning number (condition device number) is set. The winning number (condition device number) determined in the winning combination lottery process is stored in a predetermined area (not shown in FIG. 35) of the RWM 53. Then, in step S383, the value stored in this storage area is stored in the A register.
Next, proceeding to step S384, a push order instruction number table (not shown) is set. Here, the start address of the push order instruction number table is stored in the HL register. Then, the process proceeds to the next step S385.

In step S385, designated address data is set. In this process, a value obtained by adding the A register value to the HL register value is set as a new HL register value, and the data stored at the address indicated by the HL register value is stored in the A register.
That is, the data stored in the winning number (conditional device number) is used as the offset value, and the data corresponding to the address obtained by adding the offset value to the start address of the push order instruction number table is acquired. As a result, the push-order instruction number corresponding to the winning number is stored in the A register.
Then, in step S386, the A register value (pushing order instruction number) is stored in a predetermined area of RWM 53 (area for storing the pushing order instruction number, not shown in FIG. 35).
In the next step S387, the A register value (pushing order instruction number) is stored as the acquired number data.

In the eleventh embodiment, the winning combination is assumed to be the same as in FIG. 58 (twelfth embodiment) described later. When the winning numbers “3” to “8” are won during AT, the push order instruction number corresponding to the winning number is set. The relationship between the winning number and the push order instruction number stored in the acquired number data is as follows.
Winning number "3": Push order instruction number "A1 (H)"
Winning number "4": Push order instruction number "A2 (H)"
Winning number "5": Push order instruction number "A3 (H)"
Winning number "6": Push order instruction number "A4 (H)"
Winning number "7": Push order instruction number "A5 (H)"
Winning number "8": Push order instruction number "A6 (H)"

For example, when the winning number "3" is won during AT, the pushing order instruction number "A1(H)" is stored as the acquired number data by the pushing order instruction number setting process of FIG. As a result, by the LED display control (I_LED_OUT) of FIG. 55 described later, the pressing order instruction information “=1” corresponding to the pressing order instruction number “A1(H)” is displayed on the acquired number display LED 78.

After step S387, the process proceeds to step S388, and it is determined whether or not the advantageous zone display LED flag is on (lighted). When it is determined that the advantageous zone display LED flag is on, the processing according to this flowchart is ended. On the other hand, when it is determined that the advantageous zone display LED flag is not on, the process proceeds to step S389.
In step S389, it is determined whether or not the gaming state of this game (RT or main gaming state) is a gaming state in which the section Sim payout rate exceeds "1". In addition, whether or not the gaming state in which the section Sim payout rate exceeds "1" is set in advance, and here, it is determined whether or not the gaming state is set in advance. Specifically, the current RT and data of the main gaming state are stored in a predetermined area of the RWM 53, and by reading this data, the gaming state of the current game exceeds the section Sim payout rate "1". Or not. If it is determined that the gaming state in which the section Sim payout rate exceeds "1", the process proceeds to step S390. If it is determined that the gaming state in which the section Sim payout rate does not exceed "1", the processing according to this flowchart ends. To do. In step S390, the advantageous section display LED flag is turned on. Therefore, the advantageous section display LED 77 is turned on by the interrupt processing executed after step S390. Then, the processing according to this flowchart is ended.

As described above, in the game in which the instruction function is operated, the advantageous section display LED 77 is not turned on yet, and when the section Sim payout rate is in the game state exceeding “1”, the advantageous section display LED 77 is displayed. Since the condition that must be turned on is satisfied, the advantageous section display LED 77 is turned on.
However, the present invention is not limited to this. For example, when the advantageous section transition lottery is won, the advantageous section display LED 77 may be turned on before the game of the next game is started. Alternatively, after the transition to the advantageous section, before activating the instruction function or even in the gaming state in which the section Sim payout rate exceeds "1", at any timing (when the arbitrarily set lighting condition is satisfied, ), the advantageous zone display LED 77 may be turned on.

FIG. 49 is a flowchart showing the medal payout process (MS_WIN_PAY) by winning in step S294 in FIG.
First, in step S391, the main control board 50 acquires payout amount data. This process is a process of storing the value of the payout amount data in the A register.
Next, in step S392, it is determined whether or not medals are paid out. Specifically, it is determined whether or not the payout amount data (A register value) is “0”. Then, when it is determined that the value is “0”, that is, when it is determined that the medals are not paid out, the processing according to this flowchart is ended. On the other hand, when it is determined that the value is not “0”, that is, when the medal is paid out, the process proceeds to step S393.

In step S393, the value of the credit amount data is acquired.
Next, in step S394, it is determined whether or not the number of credits is the limit value. Specifically, when the credit amount data acquired in step S393 is "50 (D)", it is determined that the credit amount is the limit value, the process proceeds to step S398, and the acquired credit amount data is "50". If it is less than (D)”, it is determined that the number of credits is not the limit value, and the process proceeds to step S395.

In step S395, a waiting time for adding credits is set. In the present embodiment, in order to set about 100 ms as the waiting time, the number of interrupt processing “46” (46×2.235 ms=about 100 ms) is set. Specifically, "00000000(B)" is set as the B register value and "00101110(B)" is set as the C register value.
Next, proceeding to step S396, a 2-byte time waiting process is executed. This process is a process of subtracting the BC register value for each interrupt process and waiting until it becomes "0".

When the 2-byte time waiting process in step S396 ends, the process advances to step S397 to add "1" to the value of the credit amount data. As a result, the display of the credit amount display LED 76 becomes “+1” by the interrupt processing executed after the processing of step S397. For example, the display of the credit amount display LED 76 changes from "08" to "09". After the processing of step S397, the process proceeds to step S399.

When the process proceeds from step S394 to step S398, a single medal payout process (a process of paying an actual medal to the player from the hopper 35) is executed. This process drives the hopper motor 36, and as shown in FIGS. 7 and 8, when the on/off of the payout sensors 37a and 37b is detected at a predetermined timing, it is determined that one medal has been paid out correctly. to decide.
Through the above processing, the credit number is added until the credit number reaches the limit value, and when the credit number is the limit value, a process of paying out an actual medal from the hopper 35 is executed.

In step S399, "1" is added to the acquired number data. As a result, the display of the acquired number display LED 78 becomes "+1". For example, the display of the acquired number display LED 78 changes from "02" to "03".
In the next step S400, "1" is subtracted from the payout amount data. In this step S400, only the payout amount data is updated, and the value of the payout amount data buffer is not updated.

Next, in step S401, it is determined whether or not the medal payout is completed. This process is a process of determining whether or not the updated payout amount data is “0”. When it is determined that the payout amount data is "0", the process according to this flowchart is ended, and when it is determined that the payout amount data is not "0", the process returns to step S393 to continue the process.

In the above payout process, when performing the payout process of adding "1" to the number of credits, the waiting time of about 100 ms is set by the processes of steps S395 and S396. This allows the player to appear as if the display of the credit number display LED 76 counts up. For example, when the display of the credit number display LED 76 before adding credits is "08" and eight medals are added to this, "display "08"→standby processing for 100 ms→display "09"→100 ms Standby process→...→Standby process for 100 ms→Display “16”. On the other hand, if a waiting time is not provided when adding "1" to the number of credits, it will appear that the display "08" is instantaneously changed to the display "16".
Then, as in the present embodiment, when the number of credits is added, by executing a 2-byte time waiting process for each addition of "1", the payout sound output from the side of the sub control board 80 ("plururu... It is also possible to synchronize ")" with the increase in the number of credits.

On the other hand, when the number of credits exceeds the maximum number of “50 (D)” and the medal is actually paid out in the process of step S398, the 2-byte time waiting process of steps S395 and S396 is not provided.
This is because in order to pay out one actual medal, the hopper motor 36 is driven to pay out, and it takes about 100 ms to pay out one medal. Therefore, when the medal is actually paid out, it is possible to synchronize with the payout sound output from the sub-control board 80 side without providing a 2-byte time waiting process.

FIG. 50 is a flowchart showing the game end check processing (M_GAME_CHK) in step S301 of FIG.
First, in step S411, a process of clearing a flag of the condition device (also referred to as winning information; stored in a predetermined area (not shown in FIG. 35) of the RWM 53) is performed. This process is a process of clearing the condition devices other than the special role, and when it is determined that the symbol combination corresponding to the special role has stopped on the activated line, the condition device of the special role is also cleared. In the next step S412, the replay display LED 79f is extinguished. This process is a process of setting the bit corresponding to the replay of the medal management flag (not shown in FIG. 35) provided in the RWM 53 to “0”. Next, proceeding to step S413, the replay operation flag is cleared. This process is a process of setting the D0 bit of the operation state flag to "0".

In the next step S414, it is determined whether or not the AT game number counter has become "0". Here, the AT game number counter is updated in step S281 (FIG. 43) during the main processing of FIG. 41, as described above. Thus, in the present embodiment, the AT game number counter is updated after the start switch acceptance process (step S279 in FIG. 41), but the invention is not limited to this. For example, in FIG. 41, step S301 (game end) It may be executed before the check process) or within the process of step S301 (for example, before step S414 in FIG. 50).
Further, in the present embodiment, an example of the game number management type AT for updating the AT game number counter is shown, but in the case of the difference number management type AT, the AT difference number counter is set to “0” in step S414. Judge whether or not The AT difference number counter is updated after the medal payout process (step S294 in FIG. 41) due to winning.
When it is determined that the AT game number counter is "0", the process proceeds to step S415, and when it is determined that it is not "0", the process proceeds to step S416. In step S415, the AT flag is turned off.
Next, proceeding to step S416, the advantageous section counter management is executed. This process is a process of updating the advantageous section clear counter and the difference number counter, and is the process shown in FIG. 51 or FIG. 52 described later. Then, the processing according to this flowchart is ended.

51 and 52 are flowcharts showing the advantageous zone counter management in step S416 of FIG. 51 shows Example 1 and FIG. 52 shows Example 2.
In the advantageous zone counter management, the following processing is executed.
1) Update of advantageous zone clear counter 2) Update of difference number counter 3) Judgment as to whether end condition of advantageous zone is satisfied 4) Initialization (clearing) of data regarding advantageous zone when the end condition of advantageous zone is satisfied )
Further, the advantageous section counter management is executed regardless of the bet number (specified number).
In the present embodiment, the advantageous section counter management is executed regardless of whether it is the advantageous section or the non-advantageous section (normal section). However, it may be configured such that it is determined whether or not it is in the advantageous section, and the advantageous section counter management is executed only in the advantageous section.

51, in step S421, the address value of the advantageous period clear counter is stored in the HL register. Therefore, "F063(H)" is stored in the HL register.
In the next step S422, "1" is subtracted from the data stored in the address indicated by the HL register. The subtraction here is as follows, for example.
"0010 (H)" → "1" subtraction → "000F (H)"
"0001 (H)" → "1" subtraction → "0000 (H)" (zero flag = 1)
"0000 (H)" → "1" subtraction → "0000 (H)" (carry flag = 1)

As described above, even if “1” is subtracted from “0000 (H)”, no carry is generated, and “0000 (H)” is maintained. As described above, regardless of the value before the subtraction, since it is one instruction (1 step) that only subtracts "1", it is determined whether the count value before the update is "0". Is unnecessary, and the process of adding the value of the carry flag after subtraction is also unnecessary. Therefore, the time required to update the count value can be significantly reduced. Further, by configuring as described above, it is determined whether or not it is in the advantageous section from the value of the advantageous section clear counter, and whether or not the condition for ending the advantageous section is satisfied (for example, the game of the advantageous section is 1500). It is also unnecessary to judge whether or not the game is executed, whether or not an arbitrary ending condition is satisfied, and the like.

In the next step S423, the main control board 50 determines whether or not the advantageous zone clear counter value before subtraction is "0". This processing is determined by whether or not the carry flag becomes "1" in the subtraction processing in step S422.
When the carry flag becomes "1" (when the value before subtraction is "0"), the process proceeds to step S436. When the carry flag is not "1" (when the value before subtraction is not "0") It proceeds to step S424. When the carry flag becomes “1” (when the value before subtraction is “0”), the current game is not in the advantageous section (the current game is a non-advantageous section (normal section). It means that.

In step S424, the main control board 50 determines whether or not the subtraction result (after subtraction) in step S422 is "0". This processing is determined by whether or not the zero flag is "1" in the subtraction processing in step S422. That is, it is determined whether or not the value before subtraction was "1".
When the zero flag is "1", the process proceeds to step S435, and when the zero flag is not "1" (when the subtraction result is not "0"), the process proceeds to step S425. In addition, when the zero flag becomes "1" (when the subtraction result is "0"), the game of the advantageous section is ended in the current game (the next game is the non-advantageous section (normal section)). ) Means that.

In step S425, the value of the difference counter is acquired. This process is a process of reading the value of the difference counter and storing it in the HL register.
Next, proceeding to step S426, the main control board 50 determines whether or not a re-game operation symbol has been displayed in the current game (whether or not a replay has won). This process determines whether or not the D0 bit of the symbol combination display flag is "1", and when it is "1" it is determined that the re-game operation symbol is displayed. When it is determined that the re-game operation symbol is displayed, the process proceeds to step S434, and when it is determined that the re-game operation symbol is not displayed, the process proceeds to step S427.

In step S427, the payout amount data buffer is acquired. This process is a process of reading the payout amount data buffer and storing the value in the A register.
In the next step S428, processing for adding the number of payouts to the difference number counter is executed. This process is a process of adding the A register value (payout amount data buffer value) to the HL register value (difference number counter) and storing the value after the addition in the HL register.

Next, proceeding to step S429, the value of bet number data is acquired. This process is a process of reading the bet number data and storing the value in the A register.
In the next step S430, the bet number is subtracted from the difference number counter. This process is a process of subtracting the A register value from the HL register value and storing the subtraction result in the HL register. Here, when the HL register value becomes less than "0", the carry flag becomes "1".

In the next step S431, it is determined whether or not the subtraction result in step S430 is less than "0". This process determines whether or not the carry flag has become "1" by the subtraction in step S430. If the carry flag is "1", it is determined that the subtraction result has become less than "0", and the process proceeds to step S432. move on. On the other hand, when the carry flag is not "1" (when the subtraction result is not less than "0"), the process proceeds to step S433.

In step S432, processing for clearing the HL register value (setting it to "0") is executed. Then, in the next step S433, the difference number counter value is stored. This process is a process of storing the HL register value in the difference counter. Therefore, when the process proceeds to step S433 via step S432, the difference number counter becomes "0".
In the next step S434, the main control board 50 determines whether or not the difference counter exceeds the upper limit value. The upper limit value of the difference number counter is set to “2400(D)”. In the processing here, a comparison operation between the HL register value and “2401(D)” is performed. In this comparison operation, the carry flag is "0" when the HL register value is larger, and the carry flag is "1" when the HL register value is smaller. Therefore, when the carry flag is "1" (when the HL register value is smaller), it is determined that the upper limit value has not been exceeded, and the processing according to this flowchart ends.

On the other hand, when it is determined that the upper limit value is exceeded (when the carry flag is “0”), the process proceeds to step S435. When the difference counter exceeds the upper limit value, the end condition of the advantageous section is satisfied.
In step S435, the RWM 53 initializes the storage area related to the advantageous section (clears data related to the advantageous section). Examples of the data regarding the advantageous section include an advantageous section clear counter, an advantageous section type flag, a difference counter, an advantageous section display LED flag, an AT flag, an AT game number counter, and the like. Furthermore, information on the main gaming state is given. It should be noted that the information regarding the advantageous section does not include the RT state number, the LED display counter, and the like. Specifically, in FIG. 35, “F000(H)” to “F052(H)” are not included.

For example, the data cleared in step S435 does not include the LED display counter.
Here, it is assumed that the LED display counter is cleared. In that case, the LED display counter becomes "0" when the advantageous section ends. Specifically, if the LED display counter is initialized when it is "00000010 (B)", the LED display counter is normally updated to "00000001 (B)" in the next interrupt processing, Although the LED corresponding to the display counter (specifically, the upper digit of the credit number display LED 76) can be turned on, the LED display counter becomes "00010,000 (B)". Therefore, since the LED display counter delays the display of the LED corresponding to "00000001(B)", the LED display counter may appear to turn off for a moment.

Further, the data cleared in step S435 does not include, for example, the following data.
1) Excitation information of the motor 32 2) Error information when an error occurs 3) Data for displaying the management information display LED 74 (role ratio monitor) (total game number counter, total payout counter, etc.)
4) Timer value of minimum game time (4.1 seconds) (set in step S285 in FIG. 41)
5) Information of input port 51 6) Data of control command buffer 7) Data of stack area 8) Information of external signal Note that the above is an example of typical data, and the data that cannot be cleared is limited to the above data. It does not mean that you can be.

Next, proceeding to step S436, the main control board 50 determines whether or not the advantageous section type flag is “0” (normal section). When the advantageous zone type flag is "0", the processing according to this flowchart is ended. On the other hand, when the advantageous section type flag is not "0", particularly when it is determined that the advantageous section type flag is "1" (advantageous section) in this embodiment, the process proceeds to step S437. At this point, the advantageous zone type flag is "1" because this time the game has won the advantageous zone transition lottery, and the advantageous zone type flag is set to "1" in step S351 in FIG. In this case, it is determined that “Yes” is determined in step S423 and the process proceeds to step S436. On the other hand, when the process proceeds to step S436 via step S435, the advantageous section type flag is cleared in step S435, and therefore it is not determined to be “No” in step S436.

In step S437, an initial value is set in the advantageous zone clear counter. This process is a process of setting "1500 (D)" to the advantageous section clear counter. Here, "1500 (D)" is stored at the address indicated by the HL register value. Note that "F063(H)" is set in the HL register in step S421. Then, the processing according to this flowchart is ended.

In the above-described advantageous section counter management, when updating the difference counter, the payout number is first added (step S428), and then the bet number is subtracted (step S430). The reason for processing in this way is as follows.
For example, it is assumed that the bet amount is “3 (D)” and the payout amount is “9 (D)” when the difference counter is “2 (D)”.
Here, when the bet number is first subtracted from the difference number counter, it becomes "-1 (D) (actually, "FFFF (H)")" and the carry flag becomes "1". When the number of payouts is added, "-9 (D)" is added to "-1 (D)", which results in "8 (D)" and the carry flag is "1" (carry is carried. It indicates that it will occur).

Since the difference number of the game this time is "+6", the carry flag becomes "1" only by adding the difference number "+6" to the difference number counter "2(D)" before the update, which is irregular. The situation arises. In other words, the process of step S431 (whether the subtraction result is less than "0") cannot be determined depending on whether the carry flag is "1". If it is determined whether or not the carry flag is "1", it is determined as "Yes" in step S431 even though the carry has not occurred, and the difference counter is initialized in step S432. The value will be set. The carry flag is a flag that becomes "1" in either case where a carry or a carry occurs as a result of the subtraction.

On the other hand, when the difference counter is "2 (D)", if the payout number "9 (D)" is added first, the difference counter becomes "11 (D)" at that point, and then the bet is placed. Subtracting the number yields "8(D)". In this case, since carry does not occur, the carry flag is "0".
For the above reason, when the difference counter is updated, if the payout number is first added and then the bet number is subtracted, the determination process of step S431 can be executed by a simple process using the carry flag.

Further, in the advantageous zone counter management of the present embodiment, first, the subtraction process (step S422) of the advantageous zone counter is executed, and when the value before the subtraction is “0” (when “Yes” in step S423, that is, In the non-advantageous section), the process proceeds to step S436 without executing the difference number counter updating process (steps S425 to S430). Therefore, in the present embodiment, the advantageous section counter management is executed regardless of whether the section is the advantageous section or the non-advantageous section. By not executing, the processing efficiency is improved. Therefore, the processing sequence is such that the subtraction processing of the advantageous interval clear counter is first executed, and then the update processing of the difference number counter is executed. Of course, if the specification is such that it is determined whether or not it is in the advantageous zone, and if it is in the advantageous zone, the advantageous zone clear counter is subtracted and the difference counter is updated, the advantageous zone clear counter is subtracted. It is also possible to execute the difference counter updating process prior to the process.

In addition, the process of step S434 is executed even when the result of determination in step S426 is “Yes” (during replay winning). By doing this, even if an abnormal value (a value exceeding 2400 (D)) is stored in the difference sheet counter due to noise or the like at the end of the game, it becomes "Yes" in step S434. The advantageous section can be ended. On the other hand, if such confirmation is unnecessary, the process of this flowchart may be terminated when the result of step S426 is "Yes".

Further, in the example of FIG. 51, it is determined whether or not the re-game operation symbol is stopped and displayed in step S426, and when it is determined that the re-game operation symbol is stopped and displayed, the difference number counter is updated (step S427-). By skipping S430), the processing is speeded up.
In particular, in the game in which the re-game operation symbol is stopped and displayed, it is considered that the payout number of the game is regarded as "0" (deemed payout number) and the bet number of the next game is regarded as "0" and the difference counter is updated. .. However, for example, an SB (single bonus) is provided as a winning role during the advantageous section, and when the SB is won, one SB game that sets the bet number to "1" is executed in the next game. In the case of winning the replay, the re-game operation symbol may be stopped and displayed. In this case, since the next game is not the SB game, the bet number is "3" (other than the SB game, the bet number "1" cannot be played). However, in this case, since the number of payouts in the SB game and the number of bets in the next game do not match, there is a problem in how to count the difference counter.
Therefore, in the present embodiment, in the game in which the re-game operation symbol is stopped and displayed, the above problem can be solved by not updating the difference number counter.

FIG. 52 is a flowchart showing Example 2 of advantageous section counter management in step S416 of FIG. In FIG. 52, the same steps as those in FIG. 51 are designated by the same step numbers.
In Example 1 of FIG. 51, the payout number is first added to the difference counter and then the bet number is subtracted from the difference counter.
On the other hand, in the example 2 of FIG. 52, the bet number is first subtracted from the difference number counter, and then the payout number is added to the difference number counter.

In the example of FIG. 51, when the payout number is added after the bet number is subtracted from the difference number counter, the carry flag may be “1” even if no carry-down occurs finally, and the calculation result is It has been explained that whether or not it is “0” cannot be determined by whether or not the carry flag is “1”.
On the other hand, in Example 2 of FIG. 52, the bet number is subtracted from the difference number counter (step S430), and then the payout number is added (step S428), and in step S441, the carry flag value is not referred to. It is determined whether the calculation result is less than "0".
Specifically, in step S441 of FIG. 52, depending on whether or not the D7 bit (the most significant bit) of the H register (register storing the upper digit) value of the HL register value is “1”, it is determined in step S441. It is determined whether or not the calculation result of is less than "0".

For example,
Difference number counter value (HL register value)=0000 (H) (before calculation)
Bet number data = 3 (H)
Payout amount data = 0 (H)
Suppose that
In this case, the difference counter value after calculation is
0000(H)-3(H)=FFFD(H)
Becomes
Therefore,
H register value=FF(H) (1111/1111(B))
L register value=FD(H) (1111/1101(B))
Becomes
It should be noted that “/” indicates a 4-bit delimiter in binary notation.

In the above example, the HL register value before the calculation is "0000 (H)", but the HL register value before the calculation is not "0000 (H)" and "the difference number in the current game>HL register"Value", for example,
This game difference number = 03 (H)
HL register value = 0001 (H) (before calculation)
, The HL register value after calculation is
HL register value=FFFE(H)
Becomes
Therefore,
H register value=FF(H) (1111/1111(B))
L register value=FE(H) (1111/1110(B))
Becomes

Furthermore, when the HL register value is not "0000 (H)" and "the difference in the current game <HL register value", for example, firstly,
This game difference number = 03 (H)
HL register value = 0100 (H) (256 (D)) (before calculation)
, The HL register value after calculation is
HL register value = 00FD (H)
Becomes
Therefore,
H register value = 00 (H) (0000/0000 (B))
L register value=FD(H) (1111/1101(B))
Becomes

Secondly,
This game difference number = 03 (H)
HL register value = 00FF (H) (255 (D)) (before calculation)
, The HL register value after calculation is
HL register value = 00FC (H)
Becomes
Therefore,
H register value = 00 (H) (0000/0000 (B))
L register value = FC(H) (1111/1100(B))
Becomes

Furthermore, thirdly,
This game difference number = 03 (H)
HL register value = 0960 (H) (2400 (D)) (before calculation)
, The HL register value after calculation is
HL register value = 095D(H) (after calculation)
Becomes
Therefore,
H register value = 09 (H) (0000/1001 (B))
L register value=5D(H) (0101/1101(B))
Becomes

On the other hand, the upper limit value of the difference number counter is “2400(D)”. Here, when "2400(D)" is represented by a binary number,
"0000/1001/0110/0000 (B)"
Becomes
Since the upper limit value of the difference number counter is “2400(D)”, when the value exceeding “2400(D)” is stored in the difference number counter, it is determined that the end condition of the advantageous section is satisfied, and the difference number The counter is cleared (step S435 in FIGS. 51 and 52).
At the end of the current game, the difference counter value becomes "2400(D)", but since it does not exceed "2400(D)", it is determined that the condition for ending the advantageous section is not satisfied, and the next game is started. Suppose that it has moved. Then, in the next game, the difference number is most increased when the bet number is "1" and the payout number is "15 (D)", so the difference number in the game is "14 (D)". Becomes
Therefore, the difference number counter value in this case is “2414 (D)”.
Here, when "2414(D)" is represented by a binary number,
"0000/1001/0110/1110(B)"
Becomes

Also, when the difference number counter value becomes "2414 (D)", since it exceeds "2400 (D)", the difference number counter is cleared in the game and becomes "0 (D)".
From the above, the maximum value that the difference counter can take during the game is "2414 (D)", that is, "0000/1001/0110/1110 (B)".

Therefore, when the HL register value is "2414(D)",
H register value = 0000/1001(B)
L register value = 0110/1110 (B)
Therefore, the D7 bit (most significant bit) of the H register value becomes “0”.
Therefore, when the HL register value, that is, the difference number counter value is in the range of "0(D)" to "2414(D)", the D7 bit of the H register value is always "0".

As described above, the D7 bit (the most significant bit) of the H register value is always "0" and never becomes "1" except when a carry occurs.
In addition, in order for the D7 bit of the H register value to become "1", the difference number counter value needs to be "32768 (D)", and the difference number reaches such a value except for carry carry. The advantageous section will not continue until.

On the other hand, as mentioned above,
Bet number data = 3 (H)
Payout amount data = 0 (H)
HL register value (difference counter)=0000 (H) (before calculation)
, The HL register value after calculation is “FFFD(H)”.
Here, "FFFD(H)" is
"1111/1111/1111/1101(B)"
Is.

Therefore,
H register value = 1111/1111 (B)
L register value = 1111/1101(B)
Therefore, the D7 bit of the H register value becomes "1".
Similarly, before calculation,
Bet number data = 3 (H)
Payout amount data = 0 (H)
HL register value (difference counter) = 0002 (H)
When the difference number counter is updated, the HL register value becomes “FFFF(H)”.

Here, "FFFF(H)" is
"1111/1111/1111/1111(B)"
Is.
Therefore,
H register value = 1111/1111 (B)
L register value = 1111/1111 (B)
Therefore, the D7 bit of the H register value becomes "1".
Thus, when a carry-down occurs, the D7 bit (most significant bit) of the H register value becomes "1".

As described above, as a result of updating the difference counter, the D7 bit of the H register value is “0” when no carry occurs, and the D7 bit of the H register value is “0” when the carry occurs. 1".
Therefore, in step S441 of FIG. 52, when it is determined whether the operation result is less than "0", it is determined whether the D7 bit of the H register value is "1". When the D7 bit of the H register value is "1", it is determined that the operation result is less than "0".
By doing so, it is possible to determine whether or not the result of the operation is "0" without determining whether or not the carry flag is "1" as a result of the operation.
Then, since it is determined whether or not the calculation result is “0” without using the carry flag, there is no problem even if the payout number is added after the bet number is subtracted from the difference number counter value.

Further, as is clear from the above, even if the maximum value that the difference counter can take is “2414 (D)”, it is not limited to the D7 bit (most significant bit) of the H register value, but the D6 bit, D5 bit, and The D4 bit is also "0".
On the other hand, when the carry-down of the difference number counter value occurs, not only the D7 bit (most significant bit) of the H register value, but also the D6 bit, the D5 bit, and the D4 bit become "1".

Therefore, in step S441 in FIG. 52, instead of determining whether the D7 bit of the H register value is "1", it may be determined whether the D6 bit is "1". , D5 bit may be determined to be “1”, and D4 bit may be determined to be “1”. In any case, when the bit is "1", the operation result is less than "0", and when the bit is not "1", the operation result is not less than "0".
Note that, as is clear from the above, also in the example 1 (step S431) of FIG. 51, the operation result is less than “0” by referring to the D7 bit (or D6, D5, or D4 bit) of the H register value. It is also possible to judge whether or not there is.

51 and 52, the advantageous section clear counter is updated (step S422), the difference counter is updated (steps S428 and S430), and it is determined whether the advantageous section clear counter is "0". The determination (step S424), the determination as to whether the difference counter exceeds the upper limit value (step S434), and the initialization of the information regarding the advantageous zone (step S435) are performed regardless of the bet number (specified number) in the current game. Is executed. Therefore, even if the advantageous section clear counter becomes "0" or the difference counter exceeds the upper limit value as a result of the game being played with the bet number (specified number) "2", the advantageous section ends. To do.

FIG. 53 is a flowchart showing an interrupt process (I_INTR) by the main control board 50 (main CPU 55). As described above, the main control board 50 performs the interrupt process shown in FIG. 53 at a period of 2.235 ms (but not limited to this time period) in parallel with the main process.
When the process shifts to the interrupt process of step S451, the register value is saved and the duplicate interrupt is prohibited as an initial process in step S452. Here, since the register of the main CPU 55 used in the main process is used in the interrupt process, the current register value is saved in the stack area of the RWM 53. Further, the interrupt prohibition flag is turned on so that the next interrupt process is not started during the interrupt process. This is done because, for example, an interrupt process execution request may be issued during execution of the power-off process.

In the next step S453, power-off processing (I_POWER_DOWN) is executed. This process is a process shown in FIG. 54, which will be described later, and is a process of detecting whether or not the signal of the power failure detection signal is input.
In the next step S454, the interrupt counter value is updated. The interrupt counter value is stored in a predetermined area (not shown in FIG. 35) of the RWM 53.
In the next step S455, timer measurement is performed. This process is a process of subtracting the time set in the main process. Specifically, for example, whether or not the minimum game time (4.1 seconds) has elapsed can be mentioned.

Next, proceeding to step S456, LED display control (I_LED_OUT) is performed. This process is a process shown in FIG. 55, which will be described later, and is a process of turning on the LEDs (digits 1 to 5) according to the state of the slot machine 10.
It should be noted that the errors that occur in the slot machine 10 include a non-recoverable error and a recoverable error. For the non-recoverable error, an error display is output by the main processing (for example, step S304 in FIG. 41), but the recoverable error is possible. The error display is performed by this LED display control at each interrupt processing.

Next, proceeding to step S457, reading processing of the input port 51 is performed. As a result, whether or not the bet switch 40, the start switch 41, the stop switch 42, and the like are operated, the switch signal, and the input signals of various sensors are read, and the data based on the input port 51 (level data, rising data, (Falling data) is generated and stored in a predetermined area (not shown in FIG. 35) of the RWM 53.

In the next step S458, it is determined whether or not the set value is within the normal range. Here, the setting value data stored in the address “F000(H)” is read and the range of the setting value data is within the normal range (whether the setting value data is within the range of “0” to “5”). ) Judge whether or not. When it is determined that the set value data is within the normal range, the process proceeds to step S459, and when it is determined that the set value is not within the normal range, the process proceeds to step S470 and the non-recoverable error process is performed. The error in this case is referred to as “E6” error in the present embodiment, and the fact that it is “E6” is displayed on the acquired number display LED 78.

In step S459, a check process of the built-in random number is performed. In this embodiment, a flag is provided that turns on when an error occurs in the built-in random number, and it is determined whether or not this flag is on.
Specifically, for example, when an abnormality in the clock frequency of the random number for the winning combination is detected (when the random number is updated slowly), the error flag is turned on.
Then, in step S460, it is determined whether or not an error has occurred in the built-in random number (whether or not the error flag is on). If it is determined that no error has occurred, the process proceeds to step S461, and the error When it is determined that the error has occurred, the process proceeds to step S470 and the non-recoverable error process is performed. The error display content at this time is "E7".

In step S461, drive control of the reel 31 is performed. This control is performed for each reel 31 (left, center, right), and includes stop, constant speed, acceleration, deceleration, deceleration start, and standby depending on the operating state. When the drive control of the reel 31 is completed, the process proceeds to step S462, and port output processing is performed. In this process, the excitation output of the (reel) motor 32 and the hopper motor 36 and the excitation output of the blocker 45 are performed.

In the next step S463, an input error check process is executed. This process is a process of determining whether or not there is an abnormality in each sensor.
In the next step S464, control command transmission processing is performed. This process is a process of transmitting the set control command (untransmitted control command stored in the command buffer (not shown in FIG. 35) of the RWM 53) to the sub control board 80.
Specifically, when the control command is set in the command buffer, in the interrupt processing after that time point (in the case where the command buffer is empty, in principle, the interrupt processing that comes after that time point), this step S464 The control command is transmitted to the sub control board 80 by.

In the next step S465, the data for the external signal stored in the RWM 53 is stored in the register. Then, in the next step S466, an external signal is output from the output port 52 (output port 5 in FIG. 33) (a signal is transmitted to the external centralized terminal board 100).
Next, proceeding to step S467, a ratio display preparation process is performed. This process is a process of updating the timer for displaying the ratio of the management information display LED 74, outputting segment data, and the like.

In the next step S468, a random number updating process is performed. Next, proceeding to step S469, the register value saved at step S452 is restored and the next interrupt is permitted. Specifically, the register data stored at the start of the interrupt process is restored, and the interrupt prohibition flag is turned off so that the next interrupt process can be started. Then, the processing according to this flowchart is ended.

As shown in the above process, the credit number display LED 76, the acquired number display LED 78, the status display LED 79 (79a to 79f), the set value display LED 73, and the management information display LED 74 are turned on/off by the interrupt process every 2.235 ms. Controlled.
Furthermore, for each interrupt process, when a control command that has not been transmitted to the sub control board 80 is stored in the command buffer, the transmission process is performed.

Note that interrupt processing is not performed during non-recoverable error processing (interrupt processing is suspended until normal recovery).
The non-recoverable error is a serious error that cannot normally occur, and processing based on abnormal data (data update of the RWM 53 based on data from the input port, transmission of control commands to the sub control board 80), etc. is executed. In order to prevent it, the interrupt itself is prohibited.
If an untransmitted command is stored in the control command buffer when the non-recoverable error occurs, the command is not transmitted to the sub control board 80. This is because the control command stored in the buffer may be incorrect.

FIG. 54 is a flowchart showing the power-off process (I_POWER_DOWN) in step S453 of FIG.
In step S481, the main control board 50 determines whether or not the power-off detection signal has been turned on in the previous interrupt processing. Here, when the voltage becomes a predetermined value or less (V1 or less in the example of FIG. 3) by a voltage monitoring device (power cutoff detection circuit; not shown) provided on the main control board 50, a predetermined input is performed. Since the power failure detection signal is input to the predetermined bit of the port 51, it is detected whether or not the signal is input. Further, when the power failure detection signal is turned on, it is stored in a predetermined address of the RWM 53.
If it is determined that the power-off detection signal is ON in the previous interrupt processing, the process proceeds to step S482, and if it is determined that the power-off detection signal is not ON, the processing according to this flowchart ends.

In step S482, the main control board 50 determines whether or not the power-off detection signal is ON in the interrupt processing this time. When it is determined that it is not on, the processing according to this flowchart is ended. On the other hand, when it is determined that the power switch is on, the process proceeds to step S483.
When it is determined to be “Yes” in both the above steps S481 and S482 (when the power interruption detection signal is input for two consecutive interrupts), it is determined that the power interruption has occurred, and the process proceeds to step S483 and subsequent steps.
In step S483, the outputs of all output ports 52 are turned off. By this processing, for example, when the motor 32 is being driven (during rotation of the reel 31) or the hopper motor 36 is being driven (during payout of medals), the driving is stopped.
Next, proceeding to step S484, the power-off processing completed flag is stored in the RWM 53. This process is a process of storing data indicating that the normal power-off process has been executed in the RWM 53.

In the next step S485, the checksum data of the RWM 53 is calculated. This processing is to calculate a checksum including a work area (RWM53) used in the program, and the target program use area includes a program work area, an unused area, a stack area, and the like.
Then, in the next step S486, it is determined whether or not the calculation of the entire range of the checksum has been completed. When it is determined that the calculation of the entire range of the checksum has not been completed, the process returns to step S485 to continue the calculation of the checksum. On the other hand, if it is determined that the checksum calculation is completed, the process advances to step S487.

In step S487, the calculated checksum is stored in a predetermined address of the RWM 53. Here, the data stored in the RWM 53 is 1-byte data (also referred to as complement data) which becomes “0” when all the data in the program use area and the value stored at the above-mentioned predetermined address are added at the time of checksum of the RWM 53. ).
Then, when the checksum of the RWM 53 is executed at the start of the program, all the data in the program use area of the RWM 53 in the same range as above and the checksum data are added. If the checksum data calculated by this is "0", it is determined to be a normal value, and if it is not "0", it is determined to be an abnormal value.
Next, the process proceeds to step S488 and the reset waiting state is set. When the voltage reaches a predetermined value, a reset signal is output from the voltage monitoring device (power supply cutoff detection circuit) provided on the main control board 50, and therefore in step S488, a state of waiting for the output of the reset signal is entered.

FIG. 55 is a flowchart showing the LED display control (I_LED_OUT) in step S456 in FIG.
First, in step S491, the output ports 2 and 3 (see FIG. 33) are turned off. This process is a process of outputting "00000000(B)" from the output ports 2 and 3. In the next step S492, the output port 4 (see FIG. 33) is turned off. This process is also a process of outputting "00000000(B)" from the output port 4 similarly to the above process.

In step S493, the LED display counter is updated. This processing updates the bit "1" of the LED display counter by shifting it to the right by one digit.
In the next step S494, it is determined whether or not the LED display counter is "0". When it is determined to be "0", the process proceeds to step S495, and when it is determined that it is not "0", the process proceeds to step S496. ..
In step S495, the LED display counter is initialized. Here, the process of setting the LED display counter "00000000(B)" to "00010000(B)" is executed. Then, the process proceeds to step S496.
In step S496, the LED display counter and the LED display request flag stored in the RWM 53 are acquired. Here, the value of the LED display counter is stored in the D register, and the value of the LED display request flag is stored in the E register.

Next, proceeding to step S497, error number display data, LED display data, and bet display data are acquired. Here, in the storage area of the RWM 53, a storage area for storing error number display data when an error occurs, and LED display data indicating ON/OFF of the game start display LED 79d to the replay display LED 79f among the status display LEDs 79 are stored. A storage area and a storage area for storing (1-3) bet display data indicating ON/OFF of the bet display LEDs 79a to 79c are provided.
Specifically, the LED display data is configured as follows.
D0: Not used D1: Not used D2: Not used D3: "1" when the game can be started, "0" when the game cannot be started
D4: "1" when the medal can be inserted, "0" when the medal cannot be inserted
D5: "1" when the replay is won, "0" when the replay is not won
D6: Not used D7: Not used Note that the D3 to D5 bits of the LED display data correspond to the segments D to F of the status display LED 79 shown in FIG. 32.

Moreover, the bet display data is configured as follows.
With 0 bets: 00000000
With one bet: 00000001
With two bets: 00000011
With 3 bets: 00000111
The D0 to D2 bits of the bet display data correspond to the segments A to C of the status display LED 79 shown in FIG.
Then, in step S497, the error number display data is read and stored in the B register. Further, the LED display data is read and stored in the A register, and the bet display data is read and stored in the C register.

In the next step S498, the A register value (LED display data) and the C register value (bet display data) are ORed (combined), and the operation result is set as the segment data for the output port 3. When the A register value (LED display data) and the C register value (bet display data) are OR-operated, it becomes data indicating whether the status display LED 79 is on or off. When there is a request to display the digit 5 (“Yes” in step S516), this segment data is output from the output port 3.
Next, proceeding to step S499, the register that sets the segment data for the output port 4 is cleared.

In the next step S500, a value obtained by ANDing the LED display counter value (D register value) and the LED display request flag value (E register value) is stored in the D register, and whether or not the value is "0" is determined. To judge. If it is determined to be "0", it is determined that there is no display request, and the process proceeds to step S516. On the other hand, if it is determined that it is not “0”, it is determined that there is a display request and the process proceeds to step S501.

In step S501, the LED segment table 2 is set. Here, the LED segment table of the present embodiment is an LED segment table 1 that defines segment data when displaying an error number, and other than the error number (credit number, payout number, setting value, setting change display, push order). The LED segment table 2 that defines the segment data for displaying the instruction information and the prescribed number of instructions is provided and stored in the use area of the ROM 54. Then, in step S501, the head address of the LED segment table 2 is read and the value is stored in the HL register.

Here, in the LED segment table 2 set in step S501, offset and segment data are set as follows.
Offset "0": Segment data displaying "0" Offset "1": Segment data displaying "1" Offset "2": Segment data displaying "2" Offset "3": Displaying "3" Segment data Offset "4": Segment data displaying "4" Offset "5": Segment data displaying "5" Offset "6": Segment data displaying "6" Offset "7": "7" Segment data to be displayed Offset “8”: Segment data to be displayed “8” Offset “9”: Segment data to be displayed “9” Offset “A”: Segment data to be displayed “=” Offset “B”: “A Data to display

For example, first, when the payout amount data "10 (H)" is stored in the acquired amount data, the upper digit offset of the payout amount data is "1" and the lower digit offset is "0". Becomes Thus, when the digit 3a is turned on, segment data indicating "1" is acquired, and when the digit 4a is turned on, segment data indicating "0" is acquired.
Secondly, for example, when the setting change display data “88 (H)” is stored in the acquired number data, the upper digit offset of the setting change display data is “8”, and the lower digit is The offset is “8”. Thus, when the digit 3a is turned on, segment data indicating "8" is acquired, and when the digit 4a is turned on, segment data indicating "8" is acquired.

Furthermore, thirdly, for example, when the pushing number instruction number “A1(H)” is stored in the acquired number data, the upper digit offset of the pushing order instruction number is “A” and the lower digit The offset is “1”. As a result, when the digit 3a is turned on, segment data indicating "=" is acquired, and when the digit 4a is turned on, segment data indicating "1" is acquired.
Further, for example, fourthly, when the designated specified number display data “0B(H)” is stored in the acquired number data, the upper digit offset is “0” and the lower digit offset is “B”. Becomes Thus, when the digit 3a is turned on, segment data indicating "0" is acquired, and when the digit 4a is turned on, segment data indicating "A" is acquired.

Next, proceeding to step S502, first, set value data is acquired. Here, the setting value data stored in the address “F000(H)” is read and stored in the A register. Next, "1" is added to the A register value to generate set value display data, which is stored in the A register. The set value display data serves as an offset value when the set value is displayed.
As will be described later, the segment data stored at the address (of the LED segment table 1 or 2) of the value obtained by adding the offset value to the head address value of the LED segment table 1 or 2 is acquired.
Next, in step S503, it is determined whether or not there is a display request for the set value. Here, when the D register value is “00010000 (B)” and the setting is being changed or the setting is being confirmed, it is determined that there is a display request for the set value. If it is determined that there is a display request for the set value, the process proceeds to step S514, and if it is determined that there is no display request, the process proceeds to step S504.

In step S504, the credit amount data is acquired and stored in the A register. In the next step S505, the upper digit offset is acquired. In this process, the credit amount data (A register value) acquired in step S504 is divided by "10(D)", the quotient value is stored in the A register, and the remainder value is stored in the E register. Processing.
In the next step S506, it is determined whether or not there is a display request for the upper digit of the credit number. In this process, it is determined whether the D0 bit (bit corresponding to the digit 1a) of the D register value is "1", and when it is "1", it is determined "Yes". If it is determined that there is a display request for the upper digits of the credit amount, the process proceeds to step S514, and if it is determined that there is no display request, the process proceeds to step S507.

In step S507, it is determined whether or not there is a display request for the lower digit of the credit number. In this process, it is determined whether or not the D1 bit (bit corresponding to the digit 2a) of the D register value is "1". If it is "1", it is determined "Yes", and the process proceeds to step S513. .. On the other hand, if it is determined that there is no request to display the lower digit of the credit amount, the process proceeds to step S508.

In step S508, the acquired number data is read and stored in the A register. Here, in the acquisition number data, the payout number data is stored at the timing when the medals are paid out based on the winning of the small winning combination. Further, at the timing of the setting change, the setting change display data “88 (H)” is stored. Furthermore, when it is the timing to instruct the specified number, the specified specified number display data "0B(H)" is stored. Further, at the timing when the instruction function is operated (the pressing order is notified), the pressing order instruction number “=x (x=1 to 6)” is stored. Then, any one of these data is acquired and stored in the A register.

In the next step S509, it is determined whether or not this is the case when an error is displayed. In this processing, the B register value (error number display data stored in step S497) is read and it is determined whether it is "0". If it is not "0", it is determined that an error is being displayed and step S510 is performed. When it is “0”, it is determined that the error is not being displayed, and the process proceeds to step S511.
In step S510, the LED segment table 1 for error display is set. Note that description of the specific configuration of the LED segment table 1 is omitted. In step S510, a process of storing the start address of the LED segment table 1 in the HL register is executed. Therefore, in this case, the start address of the LED segment table 1 is set (stored in the HL register) instead of the start address of the LED segment table 2 set in step S501.

In the next step S511, the offset for the upper digit is acquired. In this process, when an error is displayed (when the B register value is not "0"), the B register value is divided by "10(D)" and the quotient is stored in the A register. Are stored in the E register. On the other hand, when the error is not displayed (when the B register value is “0”), the A register value (payout amount data, setting change display data, instruction prescribed number display data, or push order instruction number) is set to “10 ( D)" is performed, the quotient is stored in the A register, and the remainder is stored in the E register.

In the next step S512, it is determined whether or not there is a display request for the upper digit of the acquired number display LED 78. This processing determines whether or not the D2 bit (bit corresponding to the digit 3a) of the D register value is "1", and when it is "1", it is determined that there is a display request. If it is determined that there is a display request, the process proceeds to step S514, and if it is determined that there is no display request, the process proceeds to step S513.

In step S513, the offset for the lower digit is acquired. This process is a process of storing the data stored in the E register in the A register. That is, the upper digit value and the lower digit value are interchanged in the A register and the E register. Then, the process proceeds to step S514.
In step S514, segment data is acquired. In this processing, the data stored in the HL register (the head address of the LED segment table 1 or 2) and the data stored in the A register (offset value) are added, and the added address is corresponded to (the LED segment table). This is a process of storing the segment data (of Table 1 or 2) in the C register.

In the next step S515, segment data for output port 4 is set. The data set here is segment data for displaying the set value (digit 5b). Since the digits 1b to 4b perform the lighting process in the ratio display process (step S522) described later, the segment data of the digits 1b to 4b are not set here.
Therefore, in step S515, "Yes" (setting value display request is issued) in step S503, and when the segment data for setting value display is acquired and stored in the C register in step S514, the C register value is output. Set as segment data for port 4.

Next, in step S516, it is determined whether there is a digit 5 display request. Here, the digit 5 is requested to be displayed when the D register value is "00010000 (B)". If it is determined that there is a digit 5 display request, the flow proceeds to step S520, and if it is determined that there is no digit 5 display request, the flow proceeds to step S517.

In step S517, the segment data for output port 3 is set. Here, the C register value stored in step S514 is set as the segment data for the output port 3. If "Yes" in step S516 (when there is a display request for digit 5), the data set in step S498 becomes the segment data for the output port 3.

In the next step S518, the data of the advantageous zone display LED 77 is set. Here, the value of the advantageous zone display LED flag is acquired, and it is determined whether or not the value is “0”. When the value of the advantageous zone display LED flag is not "0", it is determined whether or not the digit turned on in this interrupt processing is the digit 4a. When the D3 bit of the D register value is "1", it is determined that it is the lighting timing of the digit 4a. In this case, the data obtained by ORing the segment data set in step S517 and "10000000" is set as the segment data for the output port 3. As a result, the data that enables the segment P (advantageous section display LED 77) of the digit 4a to be turned on is set.

Next, proceeding to step S519, the segment data for output port 4 set at step S515 is cleared. This is because the digit 5b (the set value display LED 73) is not turned on when there is no request to display the digit 5 (“No” in step S516).
Then, in step S520, the digit signal is output from the output port 2 and the segment signal is output from the output port 3. Here, the D register value is set as the digit data of the output port 2 and output from the output port 2.
The data of the segment signal output from the output port 3 is the data set in step S498 (when the digit 5 is turned on) or the data set in step S517 (when the digits 1 to 4 are turned on).

Next, in step S521, the segment signal is output from the output port 4. The data of the segment signal output from the output port 4 is the segment data set in step S515 (when there is a setting value display request) or the data cleared in step S519 (when there is no setting value display request). In other words, when the segment data for the output port 4 is cleared in step S519, "00000000(B)" is output from the output port 4.
Next, proceeding to step S522, the process proceeds to the ratio display process (process for turning on the management information display LED 74). In the present embodiment, the description of the ratio display process will be omitted. Then, the processing according to this flowchart is ended.

Next, the relationship between the advantageous zone display LED 77 and the power cutoff (when the power cutoff occurs while the advantageous zone display LED 77 is lit) will be described.
In the interrupt process, when a power failure is detected in FIG. 54, the process proceeds to step S483 and subsequent steps, but in this case, the data stored in the RWM 53 is retained even after the power is disconnected.
Then, after the power is turned on, in the program start process (M_PRG_START) of FIG. 38, if the setting key switch is off, it is determined as “No” in step S208, so if the power-off recovery is normal, the step The process proceeds to the power off recovery process (M_POWER_ON; FIG. 40) in S213.

In the power-off recovery process of FIG. 40, the initialization range of the RWM 53 is set in step S253, and this range is the unused area of the RWM 53 as described above. Therefore, in FIG. 35, the advantageous section display LED flag of the address “F062(H)” is not subject to initialization. The same applies to the LED display counter at the address "F051(H)".

In the power-off recovery process of FIG. 40, when the initialization of the RWM 53 is completed, an interrupt is activated in step S262. Therefore, the interrupt process of FIG. 53 is executed at intervals of 2.235 ms after step S262. When the interrupt process is executed, the LED display counter value is read in step S496 during the LED display control (I_LED_OUT) in FIG. Further, the case of "No" in step S512 is when there is a display request for the digit 4a. In this case, when the error is not displayed (“No” in step S509) and the advantageous section display LED flag is “1”, in step S518, the D7 bit of the segment data is set to “1” and the segment Data is output (step S520). As a result, the advantageous section display LED 77 lights up.
As described above, when the power is cut off while the advantageous section display LED 77 is on, the advantageous section display LED 77 is turned on again when the interrupt process is executed in the power-off recovery process.

On the other hand, when the power is turned on with the setting key switch turned on after the power is turned off, the following occurs.
In the program start process of FIG. 38, if the setting key switch is on, the result of step S208 is “Yes”, and the process proceeds to the setting change process (M_RANK_SET; FIG. 39) of step S212.
In FIG. 39, the initialization range of the RWM 53 is designated in step S221, and this initialization range also includes the advantageous section display LED flag of the address “F062(H)”. If it is determined that the power failure recovery is not normal and the process proceeds to step S223, the entire range of the RWM 53 (including the address "F062(H)") is initialized.

Therefore, even if "1" indicating turning on is stored by the initialization of the advantageous zone display LED flag, it becomes "0" indicating turning off.
Then, in step S233 of FIG. 39, an interrupt is activated. When the interrupt is activated, the current set value is displayed on the set value display LED 73 at the lighting timing of the set value display LED 73 in the LED display control (FIG. 55). Then, in step S240 in FIG. 39, the setting value can be changed (the setting value is changed by turning on the setting change switch).

In addition, in FIG. 39, when the interrupt processing is started in step S233 and the LED display control (FIG. 55) is executed, even when the digit 4a lighting timing comes, the value of the advantageous section display LED flag is already " Since it is “0”, the advantageous section display LED 77 remains off.
As described above, when the power is turned on with the setting key switch turned on and the process proceeds to the setting change process, the advantageous section display LED 77 does not light up. Further, even if the setting change process is ended and the process shifts to the main process, the advantageous section display LED 77 remains off.

Further, in the main process of FIG. 41, when the advantageous section display LED 77 is lit and the power is cut off during the loop from step S286 to step S289, that is, during the rotation of the reel 31, the following occurs. ..
When the power interruption is detected in the interrupt processing, all output ports 52 are turned off in step S483 in FIG. 54, so that the drive signal of the motor 32 for rotating the reel 31 is also turned off. As a result, the rotating reel 31 (motor 32) also stops due to the power cut.

Next, when power is supplied, the state before the power is cut off is restored through the power restoration processing (M_POWER_ON) of FIG. 40 described above. This causes the output port 52 to output the same drive signal for the motor 32 as before the power was turned off. Here, the drive signal of the motor 32 before power-off is a signal for maintaining a constant speed state. In the present embodiment, it is assumed that the motor 32 (reel 31) is driven in one step with one interrupt (2.235 ms) in a constant speed state. However, even if a drive signal in a constant speed state is output from the beginning to the motor 32 after the driving is stopped, the rotational torque is weak, so that the motor 32 cannot be driven.

Therefore, since the reel 31 does not rotate, the index sensor 33 does not detect the index of the reel 31 (does not cut the index). When it is determined that the index is not detected for a certain period of time, it is determined that the reel 31 is not rotating and the motor 32 is re-accelerated (restarted). For the acceleration of the motor 32, for example, 20 interrupts (20×2.235=44.7 ms) are first driven in one step, next 16 interrupts are driven in one step, and next 12 interrupts are driven in one step. It is a method of driving one step gradually in less time. The accelerated state requires about 100 steps, for example. As a result, the rotation of the reel 31 can be started.

On the other hand, when the power is turned on and the interrupt is activated in step S262 in FIG. 40, the digits 1a to 5a are dynamically lighted based on the value of the LED display counter, but the first LED display counter after the interrupt activation is the digit. When it is a value for lighting 3a (“00000100(B)” in FIG. 34), the LED display counter becomes “00001000(B)” after four interruptions from that point, and the digit 4a (advantageous section display LED 77) is turned on. Timing comes.

On the other hand, the power supply is cut off before the index of the reel 31 is detected by the reel sensor 33 (for example, when the reel sensor 33 detects the index of the reel 31 in the remaining "1" to several steps), and after the power is turned on. Even if it is determined that the index of the reel 31 is not detected by the reel sensor 33 and the re-acceleration is performed, at least several tens of interrupts are required until the reel 31 (motor 32) reaches the constant speed state as described above. It costs.
Therefore, after the power is turned on, the reel 31 enters the constant speed state after the advantageous section display LED 77 lights up. That is, when the operation of the stop switch 42 is ready to be received, the advantageous section display LED 77 is lit.

Further, when the reel 31 stops at a position where the index of the reel 31 is relatively far from the reel sensor 33, several to several tens of interrupts are generated until it is determined that the reel sensor 33 does not detect the index of the reel 31 after interrupt activation. Requires. Therefore, in this case, the advantageous section display LED 77 lights up before the motor 32 is re-accelerated.
As described above, the advantageous section display LED 77 is set to light up after the power supply is restored and before the reel 31 re-rotates and returns to the constant speed state.

Further, in the main process of FIG. 41, when the advantageous zone display LED 77 is turned on and the power is cut off during the driving of the hopper motor 36 in the medal payout process due to the winning in step S294, the following occurs. .. As described in the sixth embodiment, the hopper motor 36 is a DC motor.
In the medal payout process by winning shown in FIG. 49, in step S398, when the hopper motor 36 is driven and each of the payout sensors 37a and 37b normally detects the movable piece 39a (see FIG. 8). , S31 to S34), it is determined that one medal has been normally paid out. The hopper motor 36 continues to be driven until it is determined that medals corresponding to the number of payouts have been paid out.
If the power interruption is detected in the interrupt process before all the medals are paid out during the medal payout, all the output ports 52 are turned off in step S483 in FIG. 54. The drive signal is also turned off. As a result, the medal payout process is interrupted.

Next, when power is supplied, the process returns to the step S294 (medal payout process by winning) of the main process (FIG. 41) through the power recovery process (M_POWER_ON) of FIG. 40 described above. As a result, the drive signal for the hopper motor 36 is output from the output port 52 in the same manner as before the power was turned off. Note that, as shown in FIG. 41, the main process does not proceed until the payout process by winning in step S294 is completed.
On the other hand, when the power is turned off, as described above, the lighting timing of the digit 4a (advantageous section display LED 77) comes within 4 interrupts.

On the other hand, as shown in FIG. 8, the time required for paying out one medal is not generally specified, but it takes about 100 ms. Therefore, the advantageous section display LED 77 lights up until the medal payout process by winning is returned from the power-off and before the remaining medals are paid out. In other words, when the medal payout process for winning is completed after the power is turned off, the advantageous section display LED 77 is lit at that point.

In addition, as a method of preventing the advantageous section display LED 77 from being momentarily turned off when the power is momentarily cut off, the following methods can be mentioned.
As shown in FIG. 54, when the power failure is detected, the outputs of all the ports 52 are turned off in step S483. Therefore, after this process, the digit signal from the output port 2 and the segment signal from the output port 3 are output. Is not output. As a result, the advantageous section display LED 77 which is the segment P of the digit 4a is turned off.

Then, the process proceeds to step S488 of FIG. 54, and after the reset wait, when the advantageous zone display LED flag is “1”, the ON signal of the D3 bit (digit 4a) is output from the output port 2, and The output port 3 may output a D7 bit (segment P) ON signal. Note that in step S488 in FIG. 54, the interrupt processing does not occur in the loop processing after waiting for the reset, so that the advantageous section display LED 77 is constantly turned on (static lighting). Thereby, even if a momentary interruption occurs, it is possible to prevent the advantageous section display LED 77 from being visually unlit.
Alternatively, in the process of step S483 in FIG. 54, the process of turning off the output ports 2 and 3 but not the other output ports may be executed. Even with such control, it is possible to prevent the advantageous section display LED 77 from turning off due to a momentary interruption.

In the present embodiment, the segment P of the digit 4a is set to the advantageous section display LED 77, and the advantageous section display LED 77 is turned on by dynamic lighting. However, the present invention is not limited to this, and the advantageous section display LED 77 may be composed of separate and independent LEDs. Then, the advantageous section display LED 77 is statically turned on, and even when the power failure is detected, unless the output port corresponding to the advantageous section display LED 77 is turned off, the advantageous section display LED 77 is prevented from being turned off at the time of a momentary interruption. can do.

Next, the difference number display on the sub control board 80 side will be described. The sub-control board 80 displays the difference number of images on the image display device 23 during AT. Therefore, in the present embodiment, the RWM 83 of the sub control board 80 is provided with the following storage areas.
Comprises:
1) AT flag 2) Sub difference number counter 3) Pullback flag 4) Pullback game number counter

In the main control board 50, a command corresponding to each game and ON/OFF of the AT flag is transmitted to the sub control board 80. The command may be transmitted only when the AT flag on the main control board 50 side is changed from off to on and when it is changed from on to off.
The sub control board 80 receives ON/OFF information of the AT flag from the main control board 50, and turns on/off the AT flag provided on the sub control board 80 side. Further, the sub-control board 80 stores that the AT flag on the side of the sub-control board 80 has been turned from OFF to ON (AT flag rising data) and turned from ON to OFF (AT flag falling data). ..

Further, as described above, the main control board 50 updates each game and the AT game number counter during the AT, and ends the AT when the AT game number counter becomes “0”. Further, when the difference counter becomes "2400 (D)" or the advantageous section clear counter becomes "0", the AT (and the advantageous section) is ended.
The main control board 50 executes the initialization processing of the difference counter when ending the AT and the advantageous section, so that the difference counter becomes "0" when shifting from the next game to the normal section.

On the other hand, the sub control board 80 includes a sub difference number counter that counts the difference number in AT. The sub difference number counter is "0" at the time of starting the AT (except when the AT is won and the AT is started during the withdrawal period described later), and thereafter, each game and the difference number are updated. Note that when a carry-down occurs, unlike the difference counter of the main control board 50, it is not corrected to "0", and the carry-down remains.

For example, if you start AT,
1st game: Non-winning role (different number "-3")
2nd game: Non-winning role (different number "-3")
3rd game: Push order bell win (difference number "+5")
4th game: Non-winning role (difference number "-3")
5th game: Push order bell win (difference number "+5")
Suppose that
In this case, the sub difference number counter (2 byte counter)
1st game: 0 (H)-3 (H) = FFFD (H)
Second game: FFFD(H)-3(H)=FFFA(H)
3rd game: FFFA(H)+5(H)=FFFF(H)
4th game: FFFF(H)-3(H)=FFFC(H)
5th game: FFFC(H)+5(H)=0001(H)
And will be updated.

When the replay is won, the sub difference number counter is not updated like the difference number counter. Note that the number of payouts may be set to "0" in the game at the time of winning the replay, and the bet number of the next game (at the time of the replay) may be set to "0" to calculate the sub difference number.
Further, as described above, the difference number counter of the main control board 50 executes the initialization process when the advantageous section is ended, but the sub difference number counter of the sub control unit 80 sets AT (advantageous section). There is a case where the initialization process is not immediately executed and the counting is not stopped even after the end. The sub control board 80 turns on the pullback flag (“1”) when the AT is finished and the count of the sub difference number counter is continued.

The sub control board 80 determines the sub difference number counter value at the end of the AT, and when the sub difference number counter value is less than (or less than) a predetermined value (for example, “2000(D)”), the sub difference number counter. Continue counting. On the other hand, when the sub difference number counter value exceeds the predetermined value (or is equal to or more than the predetermined value), the sub difference number counter is cleared. When the AT is pulled back when the sub difference sheet counter is close to the upper limit value and the AT ends, the sub difference sheet counter value may reach the upper limit value immediately. , So that the next AT won't inherit the difference.

The withdrawal flag is a flag for determining whether or not the AT has been withdrawn (re-winned) within a predetermined number of games (“50” game in the present embodiment) after the AT ends.
At the end of AT, the pullback flag is turned on and "50(D)" is set in the pullback game number counter. The withdrawal game number counter is for counting the number of games (during the withdrawal period) after the end of AT. At the end of the AT, the pullback game number counter is set to "50(D)", and thereafter, if the AT is not won, each game is continuously decremented by "1". When the pullback game number counter becomes "0", the AT pullback fails, the pullback flag is turned off, and the sub difference number counter is cleared (initialized).
Then, the sub control board 80 updates the sub difference number counter when the pullback flag is ON after the AT is completed.

Also, during the withdrawal period (when the withdrawal flag is on), when a special role such as BB is won and a special game such as BB game is executed, the withdrawal game number counter is decremented (updated) during the special game. )do not do.
On the other hand, if the player wins the AT before the pullback game number counter reaches "0", the AT is successfully withdrawn, and the subsequent AT displays the number of images succeeding the difference from the previous AT.
For example,
Difference number at the first AT: +1000 sheets After the first AT, until the second AT is won: -100 sheets, the difference number at the start of the second AT is "+900 sheets" Image is displayed.

Further, an upper limit value that can be counted by the sub difference number counter is set. In this embodiment, the settings are as follows.
1) Upper limit value in AT: 2414 (D)
2) The symbol combination corresponding to the special combination is stopped during AT, and the upper limit value when the number of obtainable cards (probability difference) in the special game relating to the special combination is "250 (D)": "2414 (D) )-250(D)=2164(D)"
3) Upper limit during withdrawal period: 2000 (D)

As shown in 1) above, when the sub difference number counter value exceeds "2414(D)" during AT, counting of the sub difference number is stopped and the sub difference number counter is cleared.
In the present embodiment, the sub difference number counter value and the difference number displayed as an image on the image display device 23 are linked (matched). For example, when the sub difference number counter reaches "1000 (D)" during AT, the image is displayed on the image display device 23 as "acquired number in AT: 1000".

As described above, when the difference counter of the main control board 50 exceeds "2400(D)", the AT (and the advantageous section) is ended. Therefore, the maximum value that the difference counter can take is “2414 (D)”, as described above.
Therefore, also for the sub difference number counter on the side of the sub control board 80, the maximum value that can be counted is set to “2414 (D)” in accordance with the difference number counter of the main control board 50.
Since the maximum value of the sub difference number counter is "2414 (D)", the maximum difference number displayed on the image display device 23 is "2414". As a result, it is possible to prevent an excessively large number of images from being displayed, and it is possible to prevent an image display that is extremely exciting.

Further, in the present embodiment, as shown in FIG. 26 (the ninth embodiment), when the number of coins that can be acquired in the BB game is 250, the BB is won during the AT, and the symbol combination corresponding to the BB. When is stopped and displayed, the sub difference number counter value at that time is determined. Then, when the sub difference number counter value exceeds "2164 (D)" described above, since it exceeds "2414 (D)" at the end of the BB game, the sub difference when the symbol combination corresponding to BB is stopped and displayed. Clear the number of sheets counter (2 above).

In this case, the image display device 23 displays “Congratulations”, “Congratulations”, etc. as an image display corresponding to the difference number. In this way, instead of displaying "Congratulations" from the beginning of the BB game, the sub difference number counter is not cleared at the start of the BB game, and the sub difference number is exceeded until "2414 (D)" is exceeded. The counter may be continuously counted, and when "2414(D)" is exceeded, the sub difference number counter may be cleared and an image such as "Congratulations" may be displayed.

Furthermore, the difference in number of sheets may increase during the withdrawal period. For example, there may be a case where the special number is won during the withdrawal period, and as a result of digesting the special game, the difference number counter value increases.
In particular, if the specification is to win the AT when a specific BB is won, after the end of the BB game, the operation shifts to the AT. On the other hand, when the sub difference number counter is close to the upper limit value at the end of the BB game, even if the difference number is taken over by the AT after the end of the BB game, the upper limit value is reached immediately. Therefore, when the sub difference number counter value exceeds "2000 (D)" during the pullback period, the sub difference number counter is cleared. For example, during the AT pullback period, if the BB with AT is won and the BB game is exhausted, when the sub difference number counter value exceeds “2000 (D)” at the end of the final game of the BB game, Clear the sub difference number counter. As a result, in the AT after BB ends, the display of the difference number starts from "0".

As described above, even if the special game is moved during the pullback period, the pullback game number counter is not decremented during the special game. When the special combination is won during the withdrawal period, the update of the sub difference number counter may be continued or interrupted during the special game. As an example of suspending the update, for example, when the BB with AT is won when the sub difference sheet counter value during the withdrawal period is "1000 (D)", the sub difference sheet counter value is "1000 (D)". Stop at. Then, even if "250" is acquired in the subsequent BB game, this "250" is not added to the sub difference number counter. Therefore, when the game is transferred to the AT after the end of the BB game, the difference number is started from "1000".

On the other hand, as an example of continuing to update the sub difference number counter, for example, when the sub difference number counter value during the pullback period is "1000 (D)", the BB with AT is won, and in the subsequent BB game, " When "250" is acquired, the sub difference counter at the end of the BB game is "1250 (D)". When the game is transferred to the AT after the end of the BB game, the difference number is started from "1250".
Further, in the case of continuing to update the sub difference number counter, for example, when the sub difference number counter value during the pullback period is "1800 (D)", the BB with AT is won, and in the subsequent BB game, "250". When the number of sheets is acquired, the sub difference number counter at the end of the BB game becomes "2050 (D)", which exceeds "2000 (D)". Therefore, the sub difference number counter is cleared by the end of the BB game, and the display of the difference number is started from "0" in the AT after the BB ends.

Further, the sub difference number counter may update the difference number of the game regardless of the bet number, but in the present embodiment, the difference of the game is limited only when the game is started with a predetermined prescribed number. Update the number of sheets.
Here, the difference counter of the main control board 50 is updated regardless of the bet number of the game.
On the other hand, in the present embodiment, the condition for updating the sub difference number counter is set to be the bet number (specified number) "3", and the game is started with the bet number (specified number) "2". Does not update the difference in the game.

Next, the sub difference number counter management process will be described using a flowchart.
56 and 57 are flowcharts showing the sub difference number counter management processing in the eleventh embodiment. 57 is a flowchart following FIG. 56.
In step S531 of FIG. 56, the sub control substrate 80 determines whether or not the AT flag is ON (whether or not AT is currently in progress). When it is determined that the AT flag is on, the process proceeds to step S533, and when it is determined that the AT flag is not on, the process proceeds to step S532.

In step S532, the sub control board 80 determines whether or not the pullback flag is on. If it is determined that the pullback flag is on, the flow proceeds to step S533, and if it is determined that the pullback flag is not on, the processing according to this flowchart ends. That is, when not in AT and when the pullback flag is off, the sub difference number counter is not updated.

In the next step S533, the sub control board 80 determines whether or not a bet command has been received from the main control board 50. When the start switch 41 is operated and the bet number of the game is confirmed, the main control board 50 transmits a bet command capable of determining the bet number of the game to the sub control board 80. If it is determined that this bet command is received, the flow proceeds to step S534.

In step S534, it is determined based on the received bet command whether or not the bet number (specified number) is "3". When it is determined that the bet number is "3", the process proceeds to step S535, and when it is determined that the bet number is not "3", the process according to this flowchart is ended. As described above, in the present embodiment, the sub difference number counter is updated only when the bet number is “3”. Therefore, even during the AT or during the withdrawal period, when the bet number is other than "3", the sub difference number counter is not updated in the game. As is clear from FIG. 51 and FIG. 52, the difference counter on the main control board 50 side is updated regardless of the bet number (specified number) in the game.

When the process proceeds from step S534 to step S535, the sub control board 80 subtracts the bet number (“3”) from the sub difference number counter. Next, proceeding to step S536, the sub control board 80 determines whether or not a payout command has been received. During the main process (M_MAIN) of FIG. 41, after the display determination is made in step S291, the main control board 50 transmits a payout command capable of determining the number of payouts to the sub control board 80.
When it is determined in step S536 that the payout command is received, the process proceeds to step S537, and the sub control board 80 adds the payout number to the sub difference number counter.
In the next step S538, the sub control board 80 determines whether the AT flag is on. When it is determined that it is on, the process proceeds to step S539, and when it is determined that it is not on, the process proceeds to step S547 in FIG.

In step S539, it is determined whether or not the AT flag is turned on in the game this time (whether or not the rise of the AT flag is on). When it is determined that the AT flag is turned on in the game this time, the process proceeds to step S540, and when it is determined that the AT flag is not turned on in the game (the rise of the AT flag is off), the process proceeds to step S543. Therefore, the process proceeds from step S539 to step S543 at the time of AT from before the previous game.

In step S540, the sub control substrate 80 determines whether the pullback flag is on. When it is determined that the pullback flag is on, the process proceeds to step S541, and when it is determined that the pullback flag is not on, the process according to this flowchart ends. For example, when the AT flag is turned on in this game (“Yes” in step S539) and the pullback flag is off (“No” in step S540, that is, when the pullback period is not in progress), the sub difference number Since the counter is "0", there is no need to update the sub difference counter, so the processing according to this flowchart is ended.

When the process proceeds from step S540 to step S541, the sub control board 80 turns off the pullback flag. In the next step S542, the sub control board 80 clears the pull-back game number counter. Here, “Yes” in step S539 and “Yes” in step S540 correspond to the case where the AT is won during the withdrawal period. Therefore, in this case, the pullback flag is turned off, and the pullback game number counter is cleared.
Next, proceeding to step S543, the sub control board 80 determines whether or not the sub difference number counter exceeds the upper limit value "2414 (D)". If it is determined that the sub difference sheet counter exceeds "2414(D)", the flow proceeds to step S546. Then, in step S546, the sub difference number counter is cleared. This may occur when the difference sheet count increases during the withdrawal period after the AT ends and the sub difference sheet counter exceeds "2414 (D)".

On the other hand, in step S543, when it is determined that the sub difference number counter does not exceed "2414(D)", the process proceeds to step S544, and the sub control board 80 stops and displays the symbol combination corresponding to BB in the current game. Determine whether or not. When the symbol combination corresponding to BB is stopped and displayed, the command is transmitted from the main control board 50.
“Yes” in this step S544 is when the BB with AT is won during the withdrawal period. In this flowchart, it is assumed that the symbol combination corresponding to BB is stopped and displayed in the game winning BB.
When it is determined that the symbol combination corresponding to BB is stopped and displayed, the process proceeds to step S545, and when it is determined that the symbol combination corresponding to BB is not stopped and displayed, the process according to this flowchart ends.

In step S545, the sub control board 80 determines whether the sub difference number counter exceeds "2164(D)". When it is determined that the sub difference sheet counter exceeds "2164(D)", the process proceeds to step S546, the sub difference sheet counter is cleared as described above, and the process according to this flowchart ends. On the other hand, if it is determined in step S545 that the sub difference sheet counter does not exceed "2164(D)" (the sub difference sheet counter value is maintained), the processing according to this flowchart is ended.

As described above, when the BB game of the present embodiment ends with a payout exceeding 250 cards as shown in FIG. 26 (the ninth embodiment), the sub difference number counter is "2164(D)" at the start of the BB game. If it exceeds, it will exceed "2414 (D)" (upper limit value) by the final game of the BB game. Therefore, in the example of this flow chart, at the time of starting the BB game (before the start), it is determined whether or not the sub difference number counter exceeds the upper limit value during the BB game. The sub difference counter is cleared before the start. Since the difference number displayed on the image display device 23 is based on the sub difference number counter, the difference number itself is not displayed in the BB game after the sub difference number counter is cleared, or the difference number is not displayed. Instead of displaying the number display, for example, "Congratulations" or "Celebration" is displayed.

When it is determined that the AT flag is not on in step S538 and the process proceeds to step S547 of FIG. 57, the sub control board 80 determines whether or not the AT flag is turned off in this game (whether or not the fall of the AT flag is on. That is, it is determined whether or not AT has been finished in the game this time). When it is determined that the AT flag is turned off in the game this time, the process proceeds to step S548, and when it is determined that the AT flag is not turned off in the game (the fall of the AT flag is off), the process proceeds to step S551. ..

In step S548, the sub control board 80 determines whether the sub difference number counter is less than "2000 (D)". When it is determined that the sub difference sheet counter is less than "2000 (D)", the process proceeds to step S549. On the other hand, if it is determined that it is not less than “2000(D)”, the process proceeds to step S557.

In step S549, the sub control board 80 turns on the pullback flag. Next, proceeding to step S550, the sub control board 80 sets an initial value "50 (D)" to the pullback game number counter. Then, the processing according to this flowchart is ended.
By the processing of the above steps S548 to S550, when the sub difference number counter is less than "2000 (D)" at the end of AT, the pullback flag is turned on and the initial value "50 (D)" of the number of pullback games is set. Set. The reason for setting "50 (D)" as the initial value of the number of pullback games is to set AT pullback within 50 games as a continuous CH of AT (condition to take over the sub difference number to the next AT). Therefore, the number of withdrawal games is not limited to "50 (D)", but can be set to various values such as "30 (D)" and "100 (D)" according to the specifications.
Further, if the sub difference sheet counter is “2000 (D)” or more at the end of AT, even if the AT is pulled back after that, the sub difference sheet counter may exceed the upper limit value during the AT after the pullback. Therefore, in such a case, the pullback flag is not set.

On the other hand, if it is determined in step S548 that the sub difference sheet counter is not less than "2000 (D)" and the process proceeds to step S557, the sub control board 80 clears the sub difference sheet counter. Then, the processing according to this flowchart is ended. In other words, when the sub difference sheet counter is equal to or larger than "2000 (D)" at the end of AT, the sub difference sheet counter starts from the initial value "0" even if the operation shifts to AT thereafter.

Further, when the process proceeds from step S547 to step S551, the sub control board 80 determines whether or not the current game is the BB operation (BB game). The information of the operating state flag shown in FIG. 35 is transmitted from the main control board 50 to the sub control board 80.
When it is determined in step S551 that the BB is not operating, the process proceeds to step S552, and the sub control substrate 80 determines whether the pullback flag is on. When it is determined that the pullback flag is on, the process proceeds to step S553, and when it is determined that the pullback flag is not on, the process of this flowchart ends.

In step S553, the pullback game number counter is decremented by "1". In other words, during the pullback period, when the BB is operating (BB game is in progress), the pullback game number counter is not updated (subtracted). However, the present invention is not limited to this, and the pullback game number counter may be subtracted even during the BB game during the pullback period.
In the next step S554, the sub control board 80 determines whether or not the pullback game number counter has become "0". When it is determined that the pull-back game number counter is not "0", the process according to this flowchart ends. On the other hand, when it is determined that the pull-back game number counter is "0", the process proceeds to step S555.

In step S555, the pullback flag is turned off. In the next step S556, the pull-back game number counter is cleared. Note that, if "Yes" in the step S554, the pull-back game number counter is "0", so the clear process of the pull-back game number counter in the step S556 may be omitted. However, when the result is “No” in step S560, which will be described later, the pullback game number counter is cleared via step S556.
Next, proceeding to step S557, the sub control board 80 clears the sub difference number counter. Thus, when the pullback flag is off and the pullback game number counter is "0" (clear), the sub difference number counter is cleared (set to "0"), and thereafter "0" is set until the AT starts. maintain.

When it is determined in step S551 that the BB is in operation and the process proceeds to step S558, the sub-control board 80 determines whether or not the current game is the final game of the BB operation (BB game). Whether or not it is the final game of the BB game may be determined by calculating the payout amount from the start of the BB game on the side of the sub control board 80, or transmitted from the main control board 50. The judgment may be made based on the incoming command.
When it is determined that the BB game is the final game, the process proceeds to step S559, and when it is determined that the BB game is not the final game, the process according to this flowchart is ended.

In step S559, the sub control substrate 80 determines whether the pullback flag is on. When it is determined that the pullback flag is on, the process proceeds to step S560, and when it is determined that the pullback flag is not on, the process of this flowchart ends.
In step S560, the sub control board 80 determines whether the sub difference number counter is less than "2000 (D)". When it is determined that the sub difference number counter is less than "2000 (D)", the process proceeds to step S561 and the pullback game number counter is reset to "50 (D)". Then, the processing according to this flowchart is ended. As a result, the BB game is executed when the withdrawal flag is on, and when the sub difference number counter is less than "2000 (D)" in the final game of the BB game, the withdrawal period (50 games is restarted from the next game. ) Will be newly set. That is, the number of withdrawal games is set to the initial value "50" after the end of AT, the BB game is executed during the withdrawal period, and the difference number counter is less than "2000 (D)" in the final game of the BB game. , The number of pullback games is reset to "50".

On the other hand, when it is determined in step S560 that the sub difference number counter is not less than "2000 (D)", the process proceeds to step S555. After step S555, the pullback flag is turned off, the pullback game number counter is cleared, and the sub difference number counter is cleared. This ends the withdrawal period. Thus, in the final game of the BB game, when the pullback period is in progress, the sub difference number at that time is determined, and when the sub difference number is "2000 (D)" or more, the pullback period is ended. ..

In the above sub difference number counter management, the sub difference number counter is updated at the timing when the bet command is received. That is, the sub differential number is updated before all the reels 31 are stopped. On the other hand, since the difference number counter is executed by the advantageous section counter management of the game end check processing, the bet number subtraction is also executed after all reels 31 are stopped.
Therefore, similarly to the difference number counter, the sub difference number counter may also execute the subtraction of the bet number and the addition of the payout number after stopping all the reels 31.

In addition, the sub difference number counter stores the value (the digit-reduced value) even if the difference number at the end of the game becomes negative (even if the digit is reduced). However, not limited to this, like the difference number counter, when the sub difference number counter is negative at the end of the game (when a carry-down has occurred), it may be corrected to “0”.
Further, even if the sub difference number counter may have a negative value, the image display device 23 displays the difference number "0".

In this case, the following processing may be mentioned.
As described above, the sub difference number counter is a 2-byte counter, and its upper limit value is "2414 (D)", that is, "096E (H)". Therefore, the value of the most significant digit is “0 (H)”. Therefore, by determining whether or not the value of the most significant digit is “0 (H)”, it is possible to determine whether or not a carry-down has occurred. When it is determined that a carry-down has occurred (the value of the most significant digit is not "0(H)"), the difference number displayed on the image display device 23 may be set to "0".

Further, in the examples of FIGS. 56 and 57, BB is given as an example, but the present invention is not limited to this, and the same can be applied to a sub bonus (AT that looks like a bonus (BB)). The sub-bonus sets the number of games, the number of payouts, or the number of differences as the ending condition. In this case, in step S544, it is determined whether or not the sub bonus symbol is stopped and displayed. In step S551, it is determined whether or not the sub bonus game is being performed. Furthermore, in step S558, it is determined whether or not it is the final game of the sub bonus game.

<Twelfth Embodiment>
Subsequently, the twelfth embodiment will be described. In the twelfth embodiment, when a predetermined condition is satisfied, a specified number (bet number) is instructed before the game starts.
The display of the push order instruction information is the operation of the instruction function (processing relating to the instruction function), but the “instruction function” is a device that facilitates winning. Therefore, the specified number of instructions is not the operation of the instruction function (the process related to the instruction function). However, the present invention is not limited to this, and the prescribed number of instructions may be defined as one of the processes related to the instruction function.

FIG. 58 is a diagram showing the accessory condition device, the specified number for each RT, and the winning number in the twelfth embodiment.
As shown in FIG. 58(A), BB1 and BB2 are provided as the accessory condition device (special role). If BB1 is won and the symbol combination corresponding to BB1 is stopped, the game shifts to the BB1 game. The BB1 game ends with a payout of more than 100 cards. After the BB1 game is over, the game moves to non-RT.
In addition, when BB2 is won and the symbol combination corresponding to BB2 is stopped, the game shifts to the BB2 game. The BB2 game ends with a payout of more than 30 cards. After the BB2 game is over, the game moves to non-RT.

As shown in FIG. 58(B), RT includes non-RT, inside BB1, inside BB2, during operation BB1, and during operation BB2.
Non-RT continues until either BB1 or BB2 wins. If the player wins BB1 in the non-RT, the player moves to the inside of BB1, and if the player wins BB2, the player moves to the inside of BB2.
The inside of BB1 continues until the symbol combination corresponding to BB1 is stopped and displayed. When the symbol combination corresponding to BB1 is stopped in the inside of BB1, it shifts to BB1 operation, that is, BB1 game. Similarly, the inside of BB2 continues until the symbol combination corresponding to BB2 is stopped and displayed. When the symbol combination corresponding to BB2 is stopped in the inside of BB2, the process shifts to the BB2 operation, that is, the BB2 game.
The number of special roles that can carry over the winning is limited to one. Therefore, BB2 is not won when it is in the inside of BB1. Similarly, when BB2 is inside, BB1 is not won.

As shown in FIG. 58(B), the specified number is limited to “3” during the operation of BB1 and the operation of BB2 (when the accessory is operated). The game cannot be started with the bet number "1" or "2".
On the other hand, the prescribed number in the non-RT, inside BB1, and inside BB2 when the accessory is not activated is "2" or "3". As a result, the game can be started if the specified number is either "2" or "3".
In FIG. 58C, the internal lottery placement number indicates the number when the denominator is “65536”. For example, the winning probability of the winning number “1” (normal replay) in non-RT is “9000/65536”. In addition, the advantageous section lottery number indicates the number when the denominator is “16384”. Therefore, when the number of lots for advantageous section lottery is “16384”, it means that the advantageous section is won with a probability of “16384/16384”.
Further, as shown in FIG. 58C, in the non-RT, BB2 is drawn by lot with the specified number “2”, but BB1 is not drawn. On the contrary, when the specified number is “3”, BB1 is drawn, but BB2 is not drawn.

Furthermore, as shown in FIG. 58(C), when the non-RT specified number is “3” or the specified number inside the BB2 is “3”, the advantageous section can be drawn. In the lottery for the advantageous section, the winning is always set in the advantageous section except when the winning combination is not won. Therefore, in the twelfth embodiment, it is possible to make the game section a substantially advantageous section. In other words, the twelfth embodiment has the “7P” type specifications described above.

In the twelfth embodiment, it is assumed that the game is progressing within the BB2 and with the specified number "3". Then, the AT is selected within the BB2, and when the AT is won, the AT is executed. Furthermore, it is assumed that BB2 who has carried over the winning will not win the prize.
For example, if it is currently non-RT, it is necessary to shift from non-RT to inside BB2 (win BB2 in non-RT). In order to win BB2 in non-RT, it is necessary to play the game with the specified number "2".
Therefore, in the case of non-RT at the present time, the game is played with the specified number “2”, the BB2 is won, and the game is transferred to the inside of the BB2 from the next game. Furthermore, since the lottery of the advantageous section is received in the inside of BB2 when the specified number is "3", the game is advanced in the specified number of "3" inside the BB2.

Also, for the BB2 won by the specified number "2", the symbol combination cannot be stopped and displayed unless the specified number "2". Similarly, BB1 won by the specified number "3" cannot stop and display the symbol combination on the activated line unless the specified number "3" is selected.
Therefore, in the non-RT, when the specified number "2" is won to BB2, the game is transferred to the inside of BB2 and the game is progressed with the specified number "3", even if the winning combination is not won, BB2 The symbol combination corresponding to is not stopped and displayed on the activated line.
As described above, in the twelfth embodiment, the symbol combination corresponding to the winning special combination is stopped to shift to the special game and the special game is not designed to increase medals, but the special role is to carry over the winning. In other words, it is for creating the inside of the BB.

As shown in FIG. 58(C), in non-RT, BB2 can be won with a probability of about "1/5", so that it is possible to move into non-RT into BB2 early.
Further, inside BB2, when a small win or a replay is won, there is a 100% probability of winning the advantageous section. Therefore, within the BB2, most of the game period is an advantageous section. It is of course possible to set the winning probability of the advantageous section to less than 100%.

Further, the instruction function can be activated (the processing relating to the instruction function can be executed) only when the game is played with one prescribed number, particularly with the prescribed number “3” in the present embodiment. Therefore, when the AT is won during the advantageous section in the inside of BB2 and the AT is executed, when the game is started with the specified number "3" and the push-order bell is won, by operating the instruction function. The pushing order instruction information is displayed on the acquired number display LED 78. On the other hand, when the game is started with the specified number (bet number) “2” during AT, the instruction function is not activated even when the push order bell is won.

Further, similar to the eleventh embodiment, even when the game is played with the specified number "2" during the AT, the difference counter is updated based on the bet number and the payout number in the game, and The advantageous section clear counter is updated. However, the AT game number counter (AT difference number counter in the case of the difference number management type AT) is not updated. On the other hand, when the game is played with the specified number "3" in the AT, the difference number counter, the advantageous section clear counter, and the AT game number counter (AT difference number counter in the case of the difference number management type AT) Update everything.
In addition, for any of the specified numbers, the RT is always transferred when the transition condition is satisfied (when the symbol combination satisfying the transition is stopped and displayed). On the other hand, for the main game state (normally, CZ, AT, etc.), any specified number may be set to be transferable, or the game is played with one specified number (for example, "3"). It may be set so that it can be transferred only when

In BB2 inside, when the player starts the game with the specified number "2" due to a mistake in operation, and when the winning combination is not won, the symbol combination corresponding to BB2 carrying the winning can be stopped and displayed. Becomes On the other hand, when a player starts a game with a specified number of "2" due to an operation error and a winning combination of any of the winning combinations is made, the winning of the winning combination of the winning combination is prioritized. The symbol combination corresponding to the winning BB2 is not stopped and displayed. However, when a replay is won in the game, the next game will be played with the bet number "2", so that the symbol combination corresponding to BB2 having the win is also stopped and displayed in the next game as well. there is a possibility.

If the inside of BB2 and the AT start the game with the specified number "2", and the symbol combination corresponding to BB2 is stopped and displayed, the BB2 game is started. Then, when the BB2 game is finished, it shifts to non-RT (AT). Then, in this non-RT, the information corresponding to the specified number "2" is displayed on the acquired number display LED 78 to notify the player that the game should be played with the specified number "2" (instruction of the specified number). .. This is because the game is played with the specified number “2”, the BB2 is won, and the game is transferred to the inside of the BB2. Therefore, in the case of AT and non-RT, the prescribed number "2" is instructed until winning BB2.

As described above, when the information corresponding to the specified number “2” is displayed on the acquired number display LED 78, “0A” is displayed. It should be noted that the instruction of the prescribed number "2" is not limited to "0A", and it is not confused with any of the number of payouts, the setting change display "88", the error number, and the push order instruction information. May be For example, since the maximum number of medals displayed on the acquired number display LED 78 is "15", "22" may be displayed as the information corresponding to the specified number "2".

Further, in the present embodiment, the specified number is specified only during the AT, and the specified number is not specified during the non-AT. For example, after the BB2 game is over, in the case of shifting to non-RT, if it is not AT at that time, the prescribed number is not designated. Therefore, in this case, it is necessary for the player to play the game with the specified number "2" and shift the inside of the BB2.
As shown in FIG. 58, in the case of a non-RT and non-advantageous section, if a small win or replay is won when a game is played with a prescribed number "3", the advantageous section is also won. Then, when it is a non-RT and an advantageous section, a prescribed number "2" may be instructed (even if it is a non-AT).
Further, the present invention is not limited to the above, and when the shift is made to the non-RT, the specified number “2” may be instructed regardless of AT/non-AT and advantageous section/non-advantageous section.

Further, in the non-RT, when the player sets the bet number to "2", the specified number may not be designated, and when the player sets the bet number to "3", the specified number may be designated. In the main process of FIG. 41, the bet number is determined in the medal management process of step S276, but if it is determined that the current bet number is "2", the prescribed number "2" is not instructed. (The clearing process of the acquired number data is executed), and the specified number “2” is instructed when the bet number at the present time is “3” (the specified specified number display data is stored as the acquired number data). Can be mentioned.

In addition, when the BB2 game is ended and the game is transferred to the non-RT, the wait process may be executed at the end of the final game of the BB2 game. During the wait process, the game cannot proceed (main process shown in FIG. 41). For this reason, after the wait process is completed, the process proceeds to the next game (non-RT) game start set process, and the specified number is instructed there.

In the non-RT during AT, the instruction of the specified number “2” continues until the player wins BB2. Therefore, the game may be finished in one game, or may be played in a plurality of games.
In addition, as shown in FIG. 58C, when a game is played with a prescribed number “2” in a non-RT, a replay (normal replay, watermelon play, cherry replay) may be won. As a result of playing the game with the specified number "2", when the replay is won, it is optional whether or not to instruct the specified number "2" in the next game. In the non-RT and AT, the specified number "2" may be instructed before the game starts, regardless of whether or not the symbol combination corresponding to the replay is stopped until the player wins BB2. Alternatively, when the symbol combination corresponding to the replay is stopped and displayed, in the next game (replay), the player cannot arbitrarily select the specified number (bet number), so do not instruct the specified number in the game. You may

This is the same when the symbol combination corresponding to the replay is stopped and displayed as a result of playing the game with the specified number "3" in the non-RT and AT, for example. In the next game (replay), the player cannot arbitrarily select the specified number (the number of bets), so that the specified number may not be specified in this case as well. Alternatively, even if the number of bets in the game cannot be selected, a specified number “2” may be designated for the purpose of calling attention.
In the non-RT and AT, the game is played with the specified number "2", and if the player wins BB2 and moves from the next game to the inside of BB2, then the specified number of instructions will be given unless it moves to the non-RT again. Does not.

Further, the timing for instructing the prescribed number is after the stop of all reels 31 and when the payout based on the winning of the small winning combination is finished, and the start switch 41 of the next game is operated. Before (for example, before betting of medals is possible (before bet acceptance)). Therefore, after the payout based on the winning of the small winning combination in the final game of the BB2 game, the specified number “2” is instructed before the next game (non-RT) game is started. As shown in FIG. 42 (the eleventh embodiment), in step S321 of the game start set process (MS_GAME_SET), the main control board 50 sets a prescribed number of instruction conditions when the game is non-RT and AT. Judge that it satisfies.

If it is determined in step S321 in FIG. 42 that the specified number of instruction conditions are satisfied, the process proceeds to step S322, and the acquired number data is displayed as "0B" as the specified instruction number display data corresponding to the specified instruction number "2". (H)” is stored.
As a result, in the subsequent LED display control (FIG. 55), at the timing at which the digit 3a (the higher digit of the acquired number display LED 78) is turned on, the higher digit of the designated prescribed number display data “0B(H)” is determined in step S511. The offset "0 (H)" is acquired, and the segment data indicating "0" is acquired based on the LED segment table 2 in step S514. By outputting this segment data from the output port 3 in step S520, "0" is displayed on the digit 3a (the higher digit of the acquired number display LED 78).

Further, at the timing of turning on the digit 4a (the lower digit of the acquired number display LED 78), the lower digit offset "B(H)" of the designated prescribed number display data "0B(H)" is acquired in step S513. In step S514, segment data indicating "A" is acquired based on the LED segment table 2. By outputting this segment data from the output port 3 in step S520, "A" is displayed on the digit 4a (lower digit of the acquired number display LED 78).

In the main process (M_MAIN) of FIG. 41, the game start set process of step S272 is a process before betting is possible and before the start switch 41 is operated, so before betting is possible and is started. The prescribed number of instructions is displayed before the switch 41 is operated.
Further, as shown in FIG. 42, after the specified prescribed number display data is stored as the acquired number data in step S322, the automatic bet number data is set in step S325. Therefore, when instructing the prescribed number in the next game at the time of winning the replay, the prescribed number is instructed before automatic betting. This allows the player to promptly specify the prescribed number.
Further, in FIG. 41, when the operation of the start switch 41 is detected in step S278, the acquired number data (specified specified number display data) is cleared in step S280. As a result, in the interrupt process after step S280, the acquired number display LED 78 displays "00".

Here, the information “0A” corresponding to the specified number of instructions “2” is displayed on the acquired number display LED 78, and when the game is played with the specified number of “2”, the instruction function does not occur even during AT. Does not work. That is, even when the push order bell is won in the game, the push order instruction information is not displayed on the acquired number display LED 78. This is because in the present embodiment, the processing related to the instruction function is limited to the case where the specified number is “3”. Therefore, when the start switch 41 is operated after the information “0A” corresponding to the specified number “2” is displayed on the acquired number display LED 78, the acquired number display LED 78 is at least until all reels 31 are stopped. Is displayed as "00".

On the other hand, in AT and non-RT, the information “0A” corresponding to the specified number “2” is displayed on the acquired number display LED 78, but the game is played with the specified number “3” and the push order bell is won. If so, the pushing order instruction information (for example, "=1") is displayed on the acquired number display LED 78. This process is executed in step S284 in FIG. Therefore, in this case, the acquired number display LED 78 displays the information "0A" corresponding to the instruction prescribed number "2" before the game starts, and when the start switch 41 is operated (at the prescribed number "3"), " After displaying "00", if the push order bell is won, the push order instruction information (for example, "=1") is displayed.

Further, when the pressing order instruction information is displayed on the acquired number display LED 78, it is cleared in step S290 (after all reels are stopped) in FIG. Since the acquired number data is cleared in step S280 after the start switch 41 is operated, the process of step S290 may be skipped in the game in which the pressing order instruction information is not displayed on the acquired number display LED 78.
Then, when the small winning combination is won and the medal payout process by the winning is executed in step S294, the acquired number data is incremented by "1". It

Then, when proceeding to the game start set processing in step S272 of the next game, as described above, when the condition for instructing the prescribed number is satisfied, information corresponding to the instructed prescribed number is displayed on the acquired number display LED 78. In addition, when displaying the information corresponding to the specified number of instructions, the specified number display data is stored as the acquired number data, but at this point, the payout number data of the previous game may be stored as the acquired number data. Therefore, the acquisition number data may be cleared before the information corresponding to the specified number of instructions is stored. For example, in FIG. 42, a process of clearing the acquired number data may be performed before step S311.

In AT and non-RT, even though the specified number "2" is specified, it is ignored and the game is executed with the specified number "3", BB1 is won, and the game is transferred to the inside of BB1. Furthermore, it is possible to execute a BB1 game.
In order to suppress such an action, for example, the process related to the instruction function is not executed inside the BB1. In addition, in the BB1 game, the payout rate is set to be less than "1" so that the BB1 game cannot increase the number of medals.
It is to be noted that since the player is free to decide which prescribed number of games to play, even if the prescribed number of "3" is played in a game in which the prescribed number of "2" is instructed in AT and non-RT, the game is played. There is no penalty on the person.

In the above example, when the specified number is designated, the specified number is displayed on the acquired number display LED 78 (on the main control board 50 side), but the present invention is not limited to this, and the specified number is obtained. In addition to displaying on the number display LED 78, the specified prescribed number may be displayed on the liquid crystal display device 23 or the like (on the side of the sub control board 80).
Here, the display start timing when the specified number of instructions is displayed on the liquid crystal display device 23 or the like is set to be almost the same as the display start timing when the specified number of instructions is displayed on the acquisition number display LED 78 (before the game starts). To be
Furthermore, the display end timing after displaying the specified number of instructions on the liquid crystal display device 23 or the like may be the same as or different from the display end timing after displaying the specified number of instructions on the acquired number display LED 78.
As the display end timing after displaying the specified number of instructions on the liquid crystal display device 23 or the like,
(1) When the start switch 41 is operated (2) When all the reels 31 are stopped (3) When the start switch 41 is operated in a specified number of "2" games (4) All reels in a specified number of "2" games 31 when stopped (5) After winning BB2 in a specified number of games of "2" (6) When all reels 31 are stopped in a specified number of games of "2" and in games where BB2 is won.
In addition, when the specified prescribed number is displayed on the dedicated display device, it is possible to continue displaying the prescribed specified number of images on the image display device 23 or the like over a plurality of games.

<Thirteenth Embodiment>
In each of the above embodiments, the number of reels 31 and the number of stop switches 42 are each three.
On the other hand, in the thirteenth embodiment, the number of reels 31 and the number of stop switches 42 are each four.
FIG. 59 is a front view, a plan view, and a right side view showing the outline of the configuration including the reel 31 (31A to 31D) and the stop switch 42 (42A to 42D) in the thirteenth embodiment. In the front view, the reels 31</b>A to 31</b>D are illustrated so as to be seen without being blocked by the front surface of the front door 12. Further, in the plan view, the reel 31 positioned behind the front surface of the front door 12 is shown so as to be visible. Further, in the right side view, the illustration of the medal insertion slot 47 is omitted.

As shown in FIG. 59, a control panel 12c is provided on the front surface of the front door 12, and the operation button 24 and the medal insertion slot 47 are arranged on the control panel 12c. The medal slot 47 is the same as that shown in FIG. Further, although not shown in FIG. 1, the operation button 24 is electrically connected to the sub control board 80, and bidirectional communication with the sub control board 80 is possible. For example, at least a part of the operation button 24 is formed to be lightable, and the lighting mode of the operation button 24 can be controlled by the control of the sub-control board 80. When the operation button 24 is operated, the signal is input to the sub control board 80.
A start switch 41 and four stop switches 42A to 42D are arranged below the control panel 12c of the front door 12.

In the front view of FIG. 59, a line in the vertical direction passing through the midpoints of the four reels 31A to 31D is defined as line L1 (center line). The line L1 is at an intermediate position between the reels 31B and 31C. Then, between the reels 31A and 31B, between the reels 31B and 31C, and between the reels 31C and 31D, all are W1 (uniform). Therefore, the reels 31A and 31B and the reels 31C and 31D are arranged symmetrically with respect to the line L1.
Also, regarding the four stop switches 42A to 42D, W2 (uniform) is all between the stop switches 42A and 42B, between the stop switches 42B and 42C, and between the stop switches 42C and 42D. The line L1 passes through the intermediate position between the stop switches 42B and 42C.

The gap W2 between the stop switches 42 may be the same as the gap W1 (W2=W1), may be larger than the gap W1 (W2>W1), or may be smaller than the gap W1 (W2<W1).
Furthermore, in the front view, the vertical line passing through the left end of the leftmost reel 31A is defined as line L2, and the vertical line passing through the right end of the rightmost reel 31D is defined as line L3. In this case, the leftmost stop switch 42A is arranged on the right side (closer to the center) of the line L2, and the rightmost stop switch 42D is arranged on the left side (closer to the center) of the line L3.

Further, in the front view, if the spacing (center-to-center distance) between the reels 31 is W3, all between the reels 31A and 31B, between the reels 31B and 31C, and between the reels 31C and 31D are W3 (constant). Is.
If the distance between the stop switches 42 (center-to-center distance) is W4, W4 (constant) is maintained between the stop switches 42A and 42B, between the stop switches 42B and 42C, and between the stop switches 42C and 42D. ).

Further, as shown in the front view of FIG. 59, a part of the spherical body (operating portion) at the tip of the start switch 41 is arranged so as to intersect the line L2. However, not limited to this, the spherical body (operating portion) at the tip of the start switch 41 is arranged on the left side (outside) of the line L2 without intersecting with the line L2, or the line L2 without intersecting with the line L2. It may be arranged on the right side (closer to the center).
Further, in the front view, the medal insertion slot 47 is arranged so that the medal insertion slot 47 and the line L4 intersect with each other. However, the present invention is not limited to this, and the medal slot 47 may be arranged on the right side (outside) of the line L4 so as not to intersect with the line L4. Alternatively, the medal slot 47 may be arranged on the left side (closer to the center) of the line L4.

The operation button 24 is formed in a horizontally long shape, and a line in contact with the left end of the operation button 24 is a line L4, and a line in contact with the right end of the operation button 24 is a line L5.
In this case, in the front view, the stop switch 42A is arranged so that part of the leftmost stop switch 42A intersects the line L4. Further, the stop switch 42D is arranged so that a part of the rightmost stop switch 42D intersects the line L5.

Further, as shown in the plan view, an index 12d is formed on the control panel 12c. The index 12d is formed by stamping, printing, etc., and in the example of FIG. 59, it has the shape of an arrow pointing to the stop switch 42 side. Further, the index 12d on the left side is arranged on the center line of the stop switch 42A (it may be slightly deviated from the center line). The index 12d on the right side is arranged on the center line of the stop switch 42D (it may be slightly deviated from the center line).

With the above arrangement, the player can operate the leftmost stop switch 42A with the left end of the operation button 24 as a guide. Similarly, the rightmost stop switch 42D can be operated with the right end of the operation button 24 as a guide.
Alternatively, the player can operate the stop switch 42A with the index 12d on the left side as a guide. Similarly, the stop switch 42D can be operated with the index 12d on the right side as a guide.

When the number of reels 31 and the number of stop switches 42 are three, as shown in FIG. 58 (the twelfth embodiment), a pressing order of “3!=6” at maximum can be provided. On the other hand, when the number of reels 31 and the number of stop switches 42 are four, it is possible to provide a pressing order of “4!=24” at maximum.
The larger the number of pressing the stop switch 42 is, the more the base is in non-AT (the number of outs per 100 ins when the accessory is not operated and in non-AT. For example, for 100 ins) In the case of 50 out sheets, it becomes the base 50.).

When the number of reels 31 and stop switches 42 is four, the push order bells that are randomly selected are 1234 bells (stop switches 42A→42B→42C→42D indicate the correct push order), 1243 bells,...・There are 24 types, 4312 bells, 4321 bells. Then, as shown in FIG. 58, if the number of wins of each pushing order bell is the same, the number of wins of each pushing order bell is set to “1500”. In this way, since the number of winnings of each push order bell can be set to "1/4", the probability that the push order operated by the player at the time of pushing order bell wins is the same as the correct push order. can do.

Here, when the number of reels 31 and the number of stop switches 42 are three, it is possible to display an image such as "123" or "left middle right" during AT. Therefore, it is easy to intuitively understand the correct pressing order.
On the other hand, when the number of reels 31 and the number of stop switches 42 are four, the following method may be mentioned as to how to notify the correct pressing order during AT.

For example, as a first method, the stop switches 42A, 42B, 42C, and 42D are set to "1", "2", "3", and "4", respectively, and the order of the stop switches 42 to be operated is notified. To be For example, when the pressing order of the stop switch 42 is in the order of the stop switches 42C, 42D, 42A, and 42B, the notification is “3412” (at least one of image display, audio display, and lamp color notification). ) Can be mentioned. Alternatively, the stop switches 42A, 42B, 42C, and 42D may be set to "A", "B", "C", and "D", respectively, and in the above example, "CDAB" may be notified.

As a second method, a color for identifying the base of the reel 31 and/or the stop switch 42 may be added.
For example, the base of the reel 31A and/or the stop switch 42A is white, the base of the reel 31B and/or the stop switch 42B is blue, and the base of the reel 31C and/or the stop switch 42C is yellow. The base of the reel 31D and/or the color of the stop switch 42D is red (different colors). Then, in the above example, instead of the notification of “3412”, notification of “yellow red white blue” (at least one of image display, audio display, and lamp color notification) can be given.

Furthermore, as a third method, of the stop switches 42 to be operated first to fourth, the image corresponding to the fourth (last) stop switch 42 to be operated is darkly displayed (or hidden). Are listed. In this case, “the brightness of the image corresponding to the first stop switch 42 to be operated>the brightness of the image corresponding to the second stop switch 42 to be operated≧the third brightness corresponding to the stop switch 42 to be operated” Image brightness≧image brightness corresponding to the fourth stop switch 42 to be operated”.
Then, when the first (first) stop switch 42 is operated, the image corresponding to the first stop switch 42 is darkened (or hidden), and the stop switch 42 corresponding to the fourth operation is operated. The brightness of the image to be displayed may be set to be approximately the same as the brightness of the image corresponding to the stop switch 42 to be operated third.
For example, when the pressing order of "3412" is notified by the image as in the above example, "312" is first displayed as an image. Note that “●” is an image corresponding to the “4”-th press order, and may be dark (concealed) so that the character “4” cannot be seen at all, or “4” The characters may be dimly recognizable.

When the image display of "312" is performed, the image display is the same as that at the time of 6 selections, so that the player can intuitively understand the pushing order. Then, when the first stop switch 42C is operated, one of the following 1) to 3) is executed.
1) The "1" corresponding to the operated stop switch 42C is changed to the display of "●", and the previous "●" is changed to "4". Specifically, the image is displayed as "34●2".
2) The "1" corresponding to the operated stop switch 42C is changed to a display such as "-" or "○", and the "●" until then is changed to "4". Specifically, the image is displayed as "34-2" or "34○2".
3) Change "1" corresponding to the operated stop switch 42C to blank (no image), and change "●" up to then to "4". Specifically, "34*2"("*" means blank) is displayed as an image.

Further, after the second stop, similar to the above, it is possible to display images as "34●●", "34-", "34○○", "34**".
Furthermore, after the third stop, image display such as "●4●●", "-4--", "○4○○", and "*4**" can be mentioned.
Alternatively, after the third stop, the image itself in the pressing order may be erased.
Even when all the pressing orders are displayed as "4312" as in the first method described above, after the stop switch 42 is operated, the image corresponding to the operated stop switch 42 is displayed. Is preferably erased as described in 1) to 3) above because the operated stop switch 42 can be easily understood. Specifically, after displaying "4312" as an image, "43●2" (after operating the stop switch 42C) → "43●●" (after operating the stop switch 42D) → "4●●●" (stop switch 42B After the operation), an image is displayed (“●” may be “◯”, “−”, “*” as described above).

Furthermore, as a fourth method, there is a method of notifying the pushing order using a four-character idiom. For example, when "spring, summer, autumn, winter" is used as one of the four-letter idioms to notify the pushing order, the correct pushing order is "spring -> summer -> autumn ->winter".
Then, when the pressing order is "3412" as described above, notification (image display, audio display) of "autumn/winter/spring/summer" may be performed as in the first method.
Alternatively, as in the case of the third method, it is possible to display an image of "autumn-spring-summer" before the first stop and display an image of "autumn-winter-summer" after the first stop.
In any of the first method to the fourth method, when a pressing order error occurs in the middle, the image of the pressing order may be continuously displayed, or at the time when the pressing order error occurs. The image may be erased.

In addition, in the thirteenth embodiment, when 24 push-order bells are provided as described above, 24 types of push-order instruction numbers and push-order instruction information are provided. For example, if the pressing order instruction information is "A1" to "A9", "AA", "AC", "AF", "F1" to "F9", "FA", "FC", "FF", 24 types can be provided.

Although the 11th to 13th embodiments of the present invention have been described above, the present invention is not limited to the above-described contents, and various modifications such as the following are possible.
A. Eleventh Embodiment (1) In the non-advantageous section, the advantageous section is selected only when the winning combination lottery result is the target drawing result. As described above, when the winning combination lottery result is non-winning (when the condition device does not operate as a result of the internal lottery), the advantageous section transition lottery, which is the process related to the advantageous section, is set in this way This is because it was considered preferable not to do it. Therefore, it is not always necessary to set in this way, and the advantageous section transition lottery may be executed when the winning combination is not won.

(2) In the eleventh embodiment, the AT lottery process is executed after the advantageous section transition lottery. Here, a winning combination lottery result (winning number) that is always determined as an advantageous section is provided, and when the winning combination lottery result is obtained, the advantageous section shifting process (FIG. 45) is executed without executing the advantageous section shifting lottery. You may. Similarly, a winning combination lottery result (winning number) that is always determined as the AT is provided, and when the winning combination lottery result is obtained, the AT lottery is not executed and the AT setting process is performed (steps S363 and S364 in FIG. 46). May be executed.
Furthermore, a winning combination lottery result (winning number) that is always determined as an advantageous section and AT is provided, and when the winning combination lottery result is obtained, the advantageous section transition processing and the AT lottery processing are not executed, and the advantageous section transition processing and AT set processing may be executed.
Further, in the case where a winning combination lottery result (winning number) that does not win the advantageous section shifting lottery is provided, the advantageous section shifting lottery may be executed even when the winning combination lottery result is obtained. In this case, the winning number of the advantageous section may be set to "0".

(3) When the AT is won, the initial number of games of the AT is determined, the number of games is stored in the AT game number counter, and when the AT game number counter becomes "0", the AT is finished. However, the AT is not limited to such a game number management type AT, but may be a difference number management type AT. In the case of the differential sheet number management type AT, the initial value of the obtainable differential sheet number is determined when the AT is won, and is stored in the AT differential sheet number counter (different from the differential sheet number counter). Then, each time the payout is made, the difference sheet number is subtracted from the AT difference sheet number counter, and when the AT difference sheet number counter becomes “0”, the AT is ended.
Even in the case of such a difference number management type AT, the AT difference number counter is decremented when it is one prescribed number (for example, "3"), but when it is another prescribed number (for example, "2"), it is AT. Do not subtract the difference counter.

(4) In the setting change process (M_RANK_SET) of FIG. 39, the setting can be changed after the initialization process is executed. Therefore, when the advantageous section display LED 77 is turned on before the power is turned off, when the setting change processing is performed, the advantageous section display LED 77 is turned off before the setting can be changed. However, the present invention is not limited to this, and the advantageous section display is performed before ending the state in which the setting can be changed (after “Yes” in step S242 in FIG. 39) and proceeding to the main processing (before step S248). The LED flag clear (initialization) process may be executed. With this configuration, it is possible to control the advantageous section display LED 77 to be turned off after the set value is determined.

(5) One advantageous section clear counter and one difference number counter are provided. However, the present invention is not limited to this, and it is also possible to provide two advantageous section clear counters and two difference number counters (important counters) to check the consistency.
For example, as the advantageous zone clear counter, a first advantageous zone clear counter and a second advantageous zone clear counter are provided. During the advantageous zone, both the first advantageous zone clear counter and the second advantageous zone clear counter are updated every time the game is exhausted. Further, for example, in the determination of step S424 in FIGS. 51 and 52, the first advantageous zone clear counter is determined. When it is determined that the first advantageous zone clear counter is "0", whether the value of the second advantageous zone clear counter is "0", or the first advantageous zone clear counter and the second advantageous zone clear It is determined whether the counter has the same value. If it is determined to be "0" or the same value, the process proceeds to step S435.

The same applies to the difference counter.
A first difference number counter and a second difference number counter are provided as the difference number counter. Then, each time the game is exhausted, both the first difference number counter and the second difference number counter are updated. Further, for example, in the determination in step S434 in FIGS. 51 and 52, the first difference counter is determined. When it is determined that the first difference number counter exceeds the upper limit value, it is determined whether the second difference number counter exceeds the upper limit value, or whether the first difference number counter and the second difference number counter have the same value. To judge. If it is determined that the upper limit value is exceeded or the same value is exceeded, the process proceeds to step S435.

By determining the advantageous section clear counter value and/or the difference number counter value as described above, even if the counter value becomes an abnormal value (incorrect value) due to the influence of noise or the like, the advantageous section clear counter value Can be determined more accurately whether or not is "0" and/or whether or not the difference number counter value exceeds the upper limit value.
If the first advantageous zone clear counter does not match the second advantageous zone clear counter, or if the first difference number counter does not match the second difference number counter, for example, an error display is performed and the game progresses. An example is stopping (main processing).

(6) In the sub difference number management process of FIG. 56, it is determined in step S544 that the symbol combination corresponding to BB is stopped and displayed, and the process proceeds to step S545, in which it is determined that the sub difference number counter exceeds “2164(D)”. When the sub difference number counter is cleared, the BB game may output a special effect different from the normal BB game. It is possible to indicate to the player that the sub difference counter has been cleared by the special effect during the BB game.

Further, when the symbol combination corresponding to BB is stopped and displayed, the sub difference number counter is not judged, and in the BB game, each game, the sub difference number counter is, for example, "2000 (D)" (an example of a threshold value, It is not limited to the above.) may be determined. Then, when it is determined that the sub difference number counter exceeds "2000 (D)", the sub difference number counter is cleared, and a special effect (effect indicating that the sub difference number counter has been cleared) is given from the next game. You may output.

Furthermore, in the above case, when the power is cut off in a game in which the sub difference counter during BB game exceeds "2000 (D)" (the special effect has not been output yet), the power is restored from the power cut. The special effect may be output from the played game. In this case, at the time of returning from the power-off, it is sufficient to read the sub difference number counter value and the fact that the BB game is in progress, and determine whether to output the special effect.

Furthermore, when the power is cut off during the rotation of the reel 31 of the game in which the sub difference number counter during the BB game exceeds "2000 (D)", even if the special effect is output from the game that is restored from the power cut. Good. Therefore, in this case, when the power is not cut off, the special effect is output from the next game, but when the power is cut while the reel 31 is rotating, the special effect is output from the game. Become.

(7) A game is played with a prescribed number "2" during AT (the instruction function does not operate when the prescribed number is "2"), the push order bell is won, and the stop switch 42 is accidentally operated in the correct pushing order. , When there is a small winning payout and the difference counter exceeds "2400(D)", at the end of the game, an effect such as an image display such as "END" indicating the end of AT can be output. preferable. This is to prevent AT from ending in a game in which the correct pressing order is not notified and giving the player a feeling of strangeness.

(8) On the other hand, as described above, in order to prevent the AT from ending in a game in which the correct answer push order is not notified, for example, when the game is played with the specified number “2”, the push order bell is won. , Even if the stop switch 42 is operated in the correct push order, the payout number of the game is set to "2" or less (the difference number of the game is "0" or less) so that the AT does not end in the game. May be.

(9) As shown in FIGS. 56 and 57, the sub difference number counter continues counting even during the BB game. However, the present invention is not limited to this. When the BB is won during AT and the game shifts to the BB game, the sub difference number counter may not be updated (the update of the sub difference number counter is interrupted during the BB game). ..
In this case, for example, in FIG. 56, before step S531, it is determined whether or not the BB is in operation (determined by the operation state flag). Then, when the BB operation is in progress, the processing according to this flowchart is ended.
Further, when the sub difference number counter is not updated during the BB game, the processes of step S551 and steps S558 to S561 in FIG. 57 are unnecessary. Then, if “No” in the step S547, the process proceeds to a step S552.

B. Twelfth Embodiment (1) Similar to the eleventh embodiment, in FIG. 58, when the winning combination is not selected, the transitional lottery of the advantageous section (the processing relating to the advantageous section) is not executed. As mentioned above, the rules are taken into consideration. Therefore, if the rules are not taken into consideration, the transition lottery of the advantageous section may be executed when the winning combination is not won.
In addition, as shown in FIG. 58, the transition lottery of the advantageous section (the processing relating to the advantageous section) is performed only in one prescribed number (the prescribed number “3” in the example of FIG. 58) in one gaming state (RT). I decided to do it. This is done in consideration of the fact that, in accordance with the rule, the transition lottery of the advantageous section (the processing relating to the advantageous section) is defined as only one specified number in one gaming state (RT). Therefore, if this point is not taken into consideration, in one gaming state (RT), the transition lottery of the advantageous section may be executed with a plurality of prescribed numbers.

(2) In the twelfth embodiment, the specified number "2" is designated for non-RT and AT. However, when the game is the final game of the AT game, it is not necessary to specify the specified number.
(3) In the twelfth embodiment, it is assumed that a game is played inside the BB2, and it is irregular that the BB2 wins and shifts to the BB2 game. However, the present invention is not limited to this, and the specification may be such that after the AT is executed inside the BB2, when the AT end condition is satisfied, the BB2 is won and the BB2 game is executed. In this case, when the AT end condition is satisfied inside the BB2, after the game that satisfies the AT end condition is completed (all reels 31 are stopped, and a payout process is executed at the time of winning the small winning combination), Before the start of the next game (non-AT) (before the bet becomes possible), the specified number “2” is instructed to prompt the player to win BB2. In addition, in the twelfth embodiment, since the BB2 is won by the stipulated number “2”, the stipulated number for winning the BB2 is “2”. However, for example, when the BB that is won by the stipulated number “1” is provided. In the case of winning the BB, the specified number "1" is instructed.
Further, the BB game with such specifications may be a BB game in which medals increase or a BB game in which medals decrease.

(4) When instructing the prescribed number, it is executed in the game start set process (step S322 in FIG. 42). However, not limited to this, it may be executed in the game end check process (FIG. 50). For example, in the BB2 game, it is determined whether or not it is the final game of the BB2 game, and if it is the final game, the prescribed number of the next game is instructed during the game end check processing. However, when a small winning combination is won in the final game of the BB2 game and there is a payout, and when the payout number is displayed on the acquired number display LED 78, the specified number is instructed after the payout number is displayed. If the LED for instructing the specified number is a dedicated LED, it is possible to instruct the specified number for the next game on the dedicated LED while the payout amount is displayed on the acquired number display LED 78.
Furthermore, when executing the freeze in the final game of the BB2 game, when instructing the prescribed number of the next game at the time of ending the game, which timing is before executing the freeze, during executing the freeze, or after ending the freeze. May be

(5) As in the twelfth embodiment, the function of the 3 (MAX) bet switch 40b can be changed when the game can be executed with any one of the plurality of specified numbers. For example, in a game in the advantageous section, in a situation where it is advantageous to play the game with the specified number “3” (for example, in the case of inside BB2 in FIG. 58), the 3 (MAX) bet switch 40b is exclusively used for the 3 bet. You may set it to a button. That is, when the number of credits is "3", it is set to bet "3" when the 3 bet switch 40b is operated in a situation where it is advantageous to play the game with the specified number "3" in the advantageous section. To do. On the other hand, when the number of credits is "2", it is not possible to bet "2" even if the 3-bet switch 40b is operated in an advantageous section and in a situation where it is advantageous to play the game with the specified number "3". To set.

Alternatively, even if the player can play the game with the specified number “3”, if the credit amount is “2”, the player can bet “2” by operating the 3 bet switch 40b. Good. In particular, in the case of non-RT and AT in FIG. 58, it is preferable to set the bet “2” when the 3-bet switch 40b is operated when the credit amount is “2”.

(6) As in the twelfth embodiment, when most of the game section is set as the advantageous section, the instruction function can be activated at any timing. For example, a difference number counter (different from the difference number counter) capable of counting the minus of the difference number is provided, and the payout rate in a predetermined period is calculated. When the payout rate for a predetermined period reaches a predetermined lower limit value (the predetermined lower limit value is set higher than, for example, the lower limit value in the rule), the instruction function is activated to increase the payout rate. Good. When the payout rate has increased and has recovered to the reference value, the operation of the instruction function is terminated.
Such activation of the indicating function when the predetermined lower limit value is reached may or may not be included in “AT”. However, there is no change in operating the instruction function, and therefore, it corresponds to processing relating to the instruction function.

(7) In the twelfth embodiment, the LED for displaying the information corresponding to the specified number of instructions is the acquired number display LED 78. However, the present invention is not limited to this, and other existing LEDs may be set, or a dedicated LED for displaying information corresponding to the specified number of instructions may be separately provided.
When a dedicated LED for displaying information corresponding to the specified number of instructions is separately provided, even if the start switch 41 is operated after the information corresponding to the specified number of instructions is displayed in the game start set process, the specified number of instructions is operated. It is not necessary to delete the information corresponding to. Further, even if all reels 31 are stopped, a small winning combination is won, and medals are paid out, it is not necessary to delete the information corresponding to the prescribed number of instructions.
Also, when a dedicated LED for displaying information corresponding to the specified number of instructions is provided, the specified number of instructions is not confused with the number of payouts, error numbers, etc. You can For example, if the prescribed number of instructions is "2", it is possible to display "2".

(8) In the twelfth embodiment, an example in which the specified number “2” is instructed has been given, but depending on the specifications of the gaming machine, the specified number “1” may be specified or the specified number “3” may be specified. Conceivable. If the specification has the possibility of instructing any of the specified numbers “1” to “3”, the display of the acquired number display LED 78 when instructing the specified number “1” is set to “A1”, and the specified number is set. For example, the display for instructing "2" may be "A2", and the display for instructing the prescribed number "3" may be "A3".

C. Thirteenth Embodiment (1) In the front view of FIG. 59, the line L1 is set so as to pass through the centers of the four reels 31 and pass through the centers of the four stop switches 42. However, the present invention is not limited to this, and the entire four stop switches 42 may be arranged to the right of the position of FIG. 58, and for example, a part of the stop switch 42B may be arranged to intersect the line L1. On the contrary, the entire four stop switches 42 may be arranged to the left of the position of FIG. 58, and for example, a part of the stop switch 42C may be arranged so as to intersect the line L1.

(2) As shown in the front view of FIG. 59, Roman numerals from “1” to “4” are written below the four reels 31, but the Roman numeral portion may be a lamp. In this case, for example, when the stop switch to be operated next is 42C, the lamp of Roman numeral "3" is turned on.
Also, different colors may be assigned to the ranges in which Roman numerals from "1" to "4" are written, and the stop switches 42A to 42D may also be colored corresponding to Roman numerals "1" to "4". Can be mentioned. In the above example, the color of the stop switch 42A is white, the color of the stop switch 42B is blue, the color of the stop switch 42C is yellow, and the color of the stop switch 42D is red. In this case, the range of Roman numeral "1" is white, the range of Roman numeral "2" is blue, the range of Roman numeral "3" is yellow, and the range of Roman numeral "4" is red. To be

(3) Further, a portion including the periphery of the reel 31 may be configured by the image display device 23. Then, as described above, each stop switch 42 is given a different color. In this case, for example, when designating the stop switch 42B (blue) at the time of notifying the pressing order, the periphery of the reel 31B may be made to emit blue light.

(4) In the front view of FIG. 59, the interval W3 between the reels 31 is set longer than the interval W4 between the stop switches 42.
However, without being limited to this, the interval W3 between the reels 31 and the interval W4 between the stop switches 42 may be set to be substantially the same. Alternatively, the interval W4 between the stop switches 42 may be set longer than the interval W3 between the reels 31.

(5) In the thirteenth embodiment, as the pressing order bell, a maximum of 24 pressing orders can be provided. However, the present invention is not limited to this, and it is possible to provide the first stop pushing order bell. Here, in the prior art, the first stop pushing order bell has three options. On the other hand, in the thirteenth embodiment, it is possible to set four options. When the correct answer pressing order is displayed as an image when the first stop pressing order bell is won, for example, if the correct stop switch 42 is the stop switch 42C, “XX1×” may be displayed as an image.

Furthermore, it is possible to provide a first stop and a second stop push order bell (a push order bell in which the correct push order is set for the first stop and the second stop). For example, the first stop is set to the stop switch 42C, the second stop is set to the stop switch 42A, and the third stop and the fourth stop are set arbitrarily (any of the stop switches 42B and 42D is possible). In this case, the correct answer pressing order can be set to 12 options. Further, when displaying the correct pressing order as an image, in the above example, the image display may be “2×1×”. Then, after the operation of the stop switch 42C, it is possible to display an image such as "2×-×".

D. Others All of the embodiments and various modifications described in the present specification are not limited to be implemented alone, but may be implemented in appropriate combinations.

<Fourteenth Embodiment>
The fourteenth embodiment relates to the timing of display start and display end of the push order instruction information.
Hereinafter, 14th Embodiment (A)-(G) from which the timing of the display start or the display end of pushing order instruction information differs is demonstrated.

<Fourteenth Embodiment (A)>
60 and 61 are time charts for explaining the fourteenth embodiment (A).
FIG. 60 shows the display start and display timings of the push order instruction information when the start switch 41 is turned on (operated) after the minimum game time has elapsed, and FIG. 61 shows the start switch before the minimum game time has elapsed. The timing of the display start and the display end of the pushing order instruction information when 41 is turned on (operated) is shown.

Here, the hardware configuration in the fourteenth embodiment (A) is the same as the hardware configuration shown in FIGS. 31 to 35 of the eleventh embodiment.
In addition, the main processing (M_MAIN), the push order instruction number set (M_ORD_INF), the medal payout by winning (M_WIN_PAY), the interrupt processing (I_INTR), and the LED display control (I_LED_OUT) in the fourteenth embodiment (A) are the eleventh. The main processing (M_MAIN) of FIG. 41 of the embodiment, the pushing order instruction number set (M_ORD_INF) of FIG. 48, the payout of medals by winning in FIG. 49, the interrupt processing (I_INTR) of FIG. 53, and the LED display control (I_LED_OUT) of FIG. 55. ) Is the same.
Then, in the fourteenth embodiment (A), similarly to the eleventh embodiment, when the push order bell is won during AT, the push order instruction information is displayed on the acquired number display LED 78.

If the input port reading process is executed in step S457 of the interrupt process (I_INTR) of FIG. 53 and the start switch 41 is turned on at this time, then “Yes” in step S278 of the main process (M_MAIN) of FIG. 41. Becomes
Further, as shown in FIG. 41, when "Yes" is determined in the step S278, after that, the winning combination lottery process (step S282), the advantageous zone transition lottery process (step S283), and the pushing order instruction number set (M_ORD_INF) (step S284). ) Is executed.

Furthermore, as shown in FIG. 48, in the push order instruction number set (M_ORD_INF), when the condition for operating the instruction function is satisfied, that is, when a winning combination having an advantageous push order such as a push order bell in AT is won. , Generates a push order instruction number corresponding to the winning number, and stores it as the acquired number data. Then, by the LED display control (I_LED_OUT) during the interrupt process (I_INTR) executed after this process, the pushing order instruction information (for example, "=1") is displayed on the acquired number display LED 78.

Further, in the fourteenth embodiment (A), the interrupt process (I_INTR) is executed every 2.235 ms, as in the eleventh embodiment. Furthermore, the dynamic lighting of the digits 1 (1a and 1b) to 5 (5a and 5b) is performed so that one cycle is generated by 5 interrupts.
Therefore, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, the start switch 41 is turned on (operated) before the minimum game time has elapsed, or the start switch 41 has elapsed after the minimum game time has elapsed. Regardless of whether the start switch 41 is turned on (operated) or before the start switch 41 is turned on (operated) and before the rotation of the reel 31 is started, more specifically, the pushing order instruction number is stored as the acquired number data. Within 5 interrupts (2.235×5=11.175 ms), the display of the push order instruction information on the acquired number display LED 78 is started.

In addition, after the push order instruction number is stored as the acquired number data, the push order instruction information may be displayed on the acquired number display LED 78 at the first interrupt, or the push order instruction may be displayed on the acquired number display LED 78 at the fifth interrupt. Information may be displayed.
Although not shown in FIG. 41, the control command set 1 is executed between the push order instruction number set (M_ORD_INF) in step S284 and the reel rotation start preparation in step S285. In the control command set 1 between the pressing order instruction number set and the reel rotation start preparation, the effect group number or the pressing order instruction number is stored in the control command buffer as a control command. Then, the control command stored in the control command buffer is transmitted to the sub control substrate 80 by the control command transmission (step S464) during the interrupt process (I_INTR) executed after this process.

Further, in the fourteenth embodiment (A), the control command is composed of a first control command and a second control command. Both the first control command and the second control command are 1-byte data. The first control command is data indicating the type of control command, and the second control command is data indicating the parameter (variable). Then, one control command is configured by 2-byte data of the first control command and the second control command.
Furthermore, in the fourteenth embodiment (A), two sets of 8-bit parallel communication lines are used, one parallel communication line transmits the first control command to the sub-control board 80, and the other parallel communication line uses the second parallel communication line. 2 Sends a control command to the sub control board 80. As a result, a control command composed of 2-byte data can be transmitted to the sub-control board 80 with a single interrupt process.

Furthermore, in the fourteenth embodiment (A), a 64-byte storage area is secured in the RWM 53 as a control command buffer. As described above, one control command is configured by the 2-byte data of the first control command and the second control command, so that 32 control commands can be stored in the control command buffer. Then, by transmitting the control command during the interrupt process, the untransmitted control commands stored in the control command buffer are transmitted to the sub-control board 80 in the stored order.
When the control command is stored when the control command buffer is empty, the control command is transmitted to the sub-control board 80 by transmitting the control command during the interrupt process that comes next at that time.

As described above, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, the start switch 41 is turned on (operated) before the minimum game time elapses, or after the minimum game time elapses. Regardless of whether the start switch 41 is turned on (operated) or before the start switch 41 is turned on (operated) and before the rotation of the reel 31 is started, more specifically, the pressing order instruction number is stored in the control command buffer. Therefore, the push order instruction number is transmitted to the sub control board 80 in about 1 interruption (2.235 ms).

In addition, in the fourteenth embodiment (A), the sub control board 80 includes a first sub control board (sub main control board) and a second sub control board (sub sub control board). The first sub-control board and the second sub-control board are control boards belonging to a lower level of the main control board 50, and control selection and output of effects during a game and a game standby. The second sub control board is a control board that belongs to a lower level of the first sub control board. Then, the main control board 50 transmits a control command to the first sub control board in one direction, and the first sub control board and the second sub control board perform bidirectional communication.

Further, the first sub control board determines, at what timing and at what effect, based on the control command transmitted from the main control board 50. Then, the first sub-control board transmits a control command relating to the determined effect to the second sub-control board.
Furthermore, production peripheral devices such as the production lamp 21, the speaker 22, and the image display device 23 are electrically connected to the second sub-control board. Then, the second sub control board selects an effect based on the control command transmitted from the first sub control board, and controls so that various effects are output from the peripheral device for effect.

Specifically, when the first sub control board receives the control command transmitted from the main control board 50, the first sub control board stores (stores) the received control command in a predetermined storage area.
Further, the first sub-control board executes sub-main processing every 16 ms, and when the control command is analyzed in the loop processing during this sub-main processing, and as a result, it is determined that the control command is related to the image, Stores the image command according to the analysis result in the command buffer.
Further, the first sub-control board transmits the image command stored in the command buffer to the second sub-control board in the command transmission process (executed before the loop process) during the next sub-main process.

Therefore, 32 ms (=sub-main processing cycle) from the time when the main control board 50 transmits the pressing order instruction number as the control command to the first sub control board until the second sub control board receives the image command. It takes about 16 ms×2).
Then, the second sub control board executes a drawing process based on the received image command and displays an image on the image display device 23.
In addition, in the fourteenth embodiment (A), the second sub control board executes the drawing process at 30 fps (frames per second). Therefore, it takes about 33.33 ms to display one image on the image display device 23.

As described above, after the main control board 50 transmits the pressing order instruction number as the control command to the first sub control board, the second sub control board displays an image instructing the pressing order (push order instruction image) on the image display device. It takes about 65.33 ms (=32 ms+33.33 ms) to be displayed on 23.
Therefore, in the fourteenth embodiment (A), when the start switch 41 is turned on (operated) after the minimum game time has elapsed, as shown in FIG. 60, the reel 31 can be stopped after the rotation of the reel 31 is started. Before that, that is, before the rotation of the reel 31 reaches a constant speed and the operation of the stop switch 42 is ready to be accepted, the display of the pressing order instruction image on the image display device 23 is started.

On the other hand, for example, when the start switch 41 is turned on (operated) 1 second before the minimum game time elapses, it takes about 1 second from the start (operation) of the start switch 41 to the start of rotation of the reel 31. Therefore, as shown in FIG. 61, before the rotation of the reel 31, the display of the push order instruction image on the image display device 23 is started.
Further, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, the start switch 41 is turned on (operated) before the minimum game time elapses, or the start switch 41 is activated after the minimum game time elapses. Regardless of whether it is turned on (operated), the display of the pushing order instruction information on the acquired number display LED 78 is started first, and then the display of the pushing order instruction image on the image display device 23 is started.

Although not shown in FIG. 41, the control command set 1 is executed between the reel stop acceptance check in step S287 and the all reel stop check in step S288. In the control command set 1 between the reel stop acceptance check and the all reel stop check, the control command regarding the operation of the stop switch 42 and the control command regarding the stop position of the reel 31 are stored in the control command buffer. Then, the control command stored in the control command buffer is transmitted to the sub control board 80 by the control command transmission (step S464) during the interrupt processing (I_INTR) executed after this processing.

Furthermore, the first sub-control board analyzes the received control command and, as a result, determines that it is a control command related to the operation of the first stop switch 42 (stop switch 42 corresponding to the reel 31 that first stops). In this case, the image command corresponding to the operation of the first stop switch 42 is transmitted to the second sub control board.
Similarly, when it is determined that the control command is related to the operation of the second stop switch 42 (the stop switch 42 corresponding to the reel 31 that stops second), the image command corresponding to the operation of the second stop switch 42 is changed to the first command. When the control command is transmitted to the second sub-control board and is a control command related to the operation of the third stop switch 42 (the stop switch 42 corresponding to the reel 31 that is stopped last), the third stop switch 42 is operated. The image command is transmitted to the second sub control board.

Then, when the second sub-control board receives the image command corresponding to the operation of the first stop switch 42, the image corresponding to the operation of the first stop switch 42 (for example, urges the operation of the second stop switch 42). The pressing order instruction image) is displayed on the image display device 23.
Similarly, when an image command corresponding to the operation of the second stop switch 42 is received, an image corresponding to the operation of the second stop switch 42 (for example, a pressing order instruction image for prompting the operation of the third stop switch 42) is displayed. The image is displayed on the image display device 23.

When the image command corresponding to the operation of the third stop switch 42 is received, for example, the display of the pressing order instruction image is ended, and the image corresponding to the operation of the third stop switch 42 (for example, all reels 31 stop The image according to the state) is displayed on the image display device 23.
Therefore, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, after the third stop switch 42 is turned on, the display of the pressing order instruction image on the image display device 23 ends.

Also, as shown in FIG. 41, when all reels 31 are stopped (“Yes” in step S289), the acquired number data is cleared (step S290). For example, assume that the push order instruction information (for example, “=1”) is displayed on the acquired number display LED 78 at the time of winning the push order bell during AT. In this case, the display of the acquired number display LED 78 becomes "00" by the interrupt processing executed after the processing of step S290.
Therefore, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, when all reels 31 are stopped, the display of the pushing order instruction information on the acquired number display LED 78 ends.
Further, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, the display of the push order instruction image on the image display device 23 is completed first, and then the push order instruction on the acquired number display LED 78 is performed. The information display ends.

Also, as shown in FIG. 41, in step S294, payout of medal (M_WIN_PAY) by winning is executed. Further, as shown in FIG. 49, "1" is added to the acquired number data in step S399 during payout of a medal (M_WIN_PAY) by winning. As a result, the display of the acquired number display LED 78 is “+1” by the interrupt processing executed after the processing of step S399. For example, the display of the acquired number display LED 78 changes from "00" to "01".
Therefore, in the fourteenth embodiment (A), as shown in FIGS. 60 and 61, when the medals are paid out, the acquired number display LED 78 displays the number of acquired medals.

In the fourteenth embodiment (A), when the push order bell is won during AT and the push order instruction information (for example, “=1”) is displayed on the acquired number display LED 78, all reels 31 are stopped. Then, the acquired number data is cleared and the display of the acquired number display LED 78 becomes "00". After that, the display of the acquired number display LED 78 remains "00" until the medal is paid out. Then, for example, when there are 10 payouts, when the medals are paid out, the display of the number-of-acquisition display LED 78 is "00"→"01"→"02"→... →"09"→"10". Count up.

As described above, in the fourteenth embodiment (A), when the combination lottery process (step S282) and the advantageous zone transition lottery process (step S283) are executed, the push order instruction number set (step S284) is then executed. To do.
Therefore, as shown in FIGS. 60 and 61, the start switch 41 is on (operation) regardless of whether the start switch 41 is on (operation) before or after the minimum game time has elapsed. After that, and before the start of the rotation of the reel 31, it is possible to start displaying the pushing order instruction information on the acquired number display LED 78. That is, after the start switch 41 is turned on (operated), the display of the pushing order instruction information on the acquired number display LED 78 can be started immediately.

<Fourteenth Embodiment (B)>
In the fourteenth embodiment (B), the display start timing of the pushing order instruction information on the acquired number display LED 78 is different from that of the fourteenth embodiment (A), and the pushing order instruction information is displayed at the start of rotation of the reel 31. Is what starts.
FIG. 62 is a flowchart showing the main processing (M_MAIN) in the fourteenth embodiment (B), which is a flowchart corresponding to FIG. 41 of the eleventh embodiment.
In the flowchart of the fourteenth embodiment (B) shown in FIG. 62, steps different from those in FIG. 41 are underlined in step numbers, and steps identical to those in FIG. 41 are given identical step numbers. ..

In FIG. 41, the processing is executed in the order of pressing order instruction number set, reel rotation start preparation, and reel rotation start. However, in the fourteenth embodiment (B), as shown in FIG. 62, as shown in FIG. The processing is executed in the order of number set and reel rotation start.
That is, in the fourteenth embodiment (B), the order of step S284 and step S285 is exchanged with that of FIG. 41, and after the reel rotation start preparation is executed, the pushing order instruction number set is executed.

If the input port reading process is performed in step S457 of the interrupt process (I_INTR) of FIG. 53 and the start switch 41 is turned on at this time, then “Yes” in step S278 of the main process (M_MAIN) of FIG. Becomes
Further, as shown in FIG. 62, if “Yes” in the step S278, then the winning combination lottery process (step S282), the advantageous zone transition lottery process (step S283), the control command set 1 (step S601), the reel rotation start Preparation (step S285) and push order instruction number set (M_ORD_INF) (step S284) are executed.

In step S601, the control command set 1 is executed. In this control command set 1, the effect group number or the pressing order instruction number is stored in the control command buffer as a control command. Then, after step S601, the process proceeds to step S285.
In step S285, the reel rotation start preparation is executed. In this reel rotation start preparation, first, it is determined whether or not the timer value of the minimum game time (the minimum time from the start of rotation of the reel 31 to the start of rotation of the reel 31 in the next game) is "0".

The RWM 53 has an area for storing the timer value of the minimum game time. The initial value of the timer value is “1834(D) (2.235 ms×1834≈4099 ms)”. Furthermore, the timer value is decremented by "1" every interrupt processing (2.235 ms). When it is determined that the timer value is not "0", it is determined again whether the timer value is "0". When it is determined that the timer value is "0", the initial value of the timer value is reset. Set and proceed to step S284.
In this way, in the reel rotation start preparation in step S285, it is determined whether or not the minimum game time has elapsed, and when it is determined that the minimum game time has elapsed, the process proceeds to step S284.

Further, as shown in FIG. 62, in the fourteenth embodiment (B), when the reel stop acceptance check of step S287 is executed, the routine proceeds to step S602.
In step S602, the control command set 1 is executed. In the control command set 1, the control command related to the operation of the stop switch 42 and the control command related to the stop position of the reel 31 are stored in the control command buffer. Then, after step S602, the process proceeds to step S288.
Executing the control command set 1 between the reel stop acceptance check in step S287 and the all reel stop check in step S288 is as described in the fourteenth embodiment (A).
Other than the above, it is the same as the flowchart of FIG. 41 of the eleventh embodiment.

63 and 64 are time charts for explaining the fourteenth embodiment (B).
FIG. 63 shows the timing of starting and ending the display of the pushing order instruction information when the start switch 41 is operated after the minimum game time has elapsed, and FIG. 64 shows that the start switch 41 has been operated before the minimum game time has elapsed. The timing of the display start and the display end of the pressing order instruction information when the button is pressed is shown.

As described above, in the fourteenth embodiment (B), when the advantageous section shift lottery process of step S283 is executed, the process proceeds to step S601 and the control command set 1 is executed. In this control command set 1, the effect group number or the pressing order instruction number is stored in the control command buffer as a control command. Then, the effect group number or the pressing order instruction number stored in the control command buffer is transmitted to the sub control board 80 by the interrupt processing executed after this processing.

Therefore, in the fourteenth embodiment (B), as shown in FIGS. 63 and 64, the start switch 41 is operated before the minimum game time elapses, or the start switch 41 is operated after the minimum game time elapses. Regardless of whether or not the start switch 41 is turned on (operated) and before the rotation of the reel 31 is started, more specifically, one interruption (2. In about 235 ms), the push order instruction number is transmitted to the sub control board 80 (first sub control board).

Further, in the fourteenth embodiment (B), when the control command set 1 in step S601 is executed, the reel rotation start preparation is then executed in step S285, and then the pushing order instruction number set in step S284 is executed.
Therefore, in the fourteenth embodiment (B), as shown in FIGS. 63 and 64, the start switch 41 is turned on (operated) before the minimum game time elapses, or the start switch 41 is elapsed after the minimum game time elapses. Regardless of whether or not is turned on (operated), the display of the pushing order instruction information on the acquired number display LED 78 is started when the reel 31 starts to rotate.

Further, as described in the fourteenth embodiment (A), the main control board 50 transmits the pressing order instruction number to the first sub control board, and then the second sub control board instructs the image display device 23 to perform the pressing order. It takes about 65.33 ms to display an image. Therefore, in the fourteenth embodiment (B), when the start switch 41 is turned on (operated) after the minimum game time has elapsed, as shown in FIG. 63, after the rotation of the reel 31 is started and the reel 31 is stopped. Before it becomes possible, the display of the push order instruction image on the image display device 23 is started.
On the other hand, for example, when the start switch 41 is turned on (operated) 1 second before the minimum game time elapses, it takes about 1 second from the start (operation) of the start switch 41 to the start of rotation of the reel 31. Therefore, as shown in FIG. 64, the display of the pressing order instruction image on the image display device 23 is started before the rotation of the reel 31 is started.

Furthermore, when the start switch 41 is turned on (operated) after the minimum game time has elapsed, as shown in FIG. 63, the display of the push order instruction information on the acquired number display LED 78 is started first, and then the image is displayed. The display of the pressing order instruction image on the display device 23 is started.
On the other hand, when the start switch 41 is turned on (operated) before the minimum game time elapses, as shown in FIG. 64, first, the display of the push order instruction image on the image display device 23 is started, and thereafter. Then, the display of the pushing order instruction information on the acquired number display LED 78 is started.
That is, depending on whether the operation time of the start switch 41 is before or after the lapse of the minimum game time, the display of the pressing order instruction information on the acquired number display LED 78 and the pressing order instruction to the image display device 23 are started. The order of the display start of the image is switched.

Here, in the fourteenth embodiment (A), regardless of whether the start switch 41 is turned on (operated) before the minimum game time elapses or the start switch 41 is turned on (operated) after the minimum game time elapses. After the start switch 41 is turned on (operated) and before the rotation of the reel 31 is started, the pressing order instruction information is displayed on the acquired number display LED 78. That is, immediately after the start switch 41 is turned on (operated), the display of the pushing order instruction information on the acquired number display LED 78 is started.

However, if the display start timing of the push order instruction information on the acquired number display LED 78 is too early, the start switch 41 is turned on because the winning combination having an advantageous push order such as the push order bell is selected in the combination lottery (internal drawing). After (operation), the player immediately understands.
Although this does not have an advantageous pushing order, it may discourage a player who has been waiting for the winning of a rare role, which is a condition for determining the addition of the number of AT games.

Therefore, in the fourteenth embodiment (B), when it is determined that the minimum game time has elapsed, the pushing order instruction number is stored as the winning number data, so that when the reel 31 starts to rotate, the pushing number indicating LED 78 is pushed. Start displaying the normal instruction information.
As a result, when the start switch 41 is turned on (operated) before the minimum game time elapses, the display start timing of the push order instruction information on the acquired number display LED 78 can be delayed until the minimum game time elapses. It is possible to prevent the player who has been waiting for the winning of the rare role from being discouraged immediately after the operation of the start switch 41.

Also, when the start switch 41 is turned on (operated) after the minimum game time has elapsed, it is determined that the minimum game time has elapsed, and the push order instruction number is stored as the acquired number data, and then 5 interrupts (2.235). The display of the push order instruction information on the acquired number display LED 78 is started within (×5=11.175 ms).
Furthermore, in the fourteenth embodiment (B), the pressing order instruction number is stored in the control command buffer and stored in the sub control board 80 (first sub control board) before the pressing order instruction number is stored as the acquired number data. About 65.33 ms from the time the main control board 50 sends the pressing order instruction number to the first sub control board until the second sub control board displays the pressing order instruction image on the image display device 23. Takes time.

As described above, the time required to store the pressing order instruction number as the acquisition number data and display the pressing order instruction information on the acquisition number display LED 78 is "X", and the main control board 50 displays the pressing order instruction number. When the time required for the second sub-control board to display the pressing order instruction image on the image display device 23 after the transmission to the first sub-control board is “Y”, “X<Y” is satisfied. Is set to.
When the interrupt processing cycle is "T" and the number of digits to be dynamically lighted by the interrupt processing is "N", the pressing order instruction number is stored as the acquired number data, and then the acquired number display LED 78 is pressed. It takes a maximum of “T×N” time to display the forward instruction information. Therefore, the setting is made so as to satisfy “T×N<Y”.
As a result, when the start switch 41 is turned on (operated) after the minimum game time has elapsed, the display of the push order instruction information on the acquired number display LED 78 is started first, and then the push order on the image display device 23. The display of the instruction image is started.

<Fourteenth Embodiment (C)>
The fourteenth embodiment (C) is different from the fourteenth embodiment (A) and (B) in the display end timing of the pushing order instruction information on the acquired number display LED 78, and the pushing order instruction information at the time of paying out medals. The display of is ended.
FIG. 65 is a flowchart showing the main processing (M_MAIN) in the fourteenth embodiment (C), and is a flowchart corresponding to FIG. 41 of the eleventh embodiment.
In the flowchart of the fourteenth embodiment (C) shown in FIG. 65, steps different from those in FIG. 41 are underlined in step numbers, and steps identical to those in FIG. 41 are given the same step numbers. ..

In FIG. 41, when it is determined in step S289 that all reels 31 have stopped, the process proceeds to step S290 and the acquired number data is cleared, but in the fourteenth embodiment (C), as shown in FIG. 65, in step S289, When it is determined that all reels 31 have stopped, the process proceeds to step S291, and display determination of symbols is performed without clearing the acquired number data.
Also, in the fourteenth embodiment (C), the medal payout (M_WIN_PAY) due to winning is different from that of the eleventh embodiment shown in FIGS. 41 and 49.

If the input port reading process is performed in step S457 of the interrupt process (I_INTR) in FIG. 53 and the start switch 41 is turned on at this time, then “Yes” in step S278 of the main process (M_MAIN) in FIG. Becomes
Further, as shown in FIG. 65, if “Yes” in the step S278, then the winning combination lottery process (step S282), the advantageous zone transition lottery process (step S283), and the pushing order instruction number set (M_ORD_INF) (step S284) , Control command set 1 (step S601), and reel rotation start preparation (step S285) are executed.
Note that step S601 is the same as in the fourteenth embodiment (B).

Also, in FIG. 65, the control command set 1 (step S602) is executed after the reel stop acceptance check (step S287), and then the all reel stop check (step S288) is executed in the fourteenth embodiment. It is similar to FIG. 62 of FIG.
Furthermore, as shown in FIG. 65, when it is determined in step S289 that all reels 31 have stopped, the process proceeds to step S291 to make a symbol display determination. That is, in the fourteenth embodiment (C), the acquired number data is maintained without being cleared after all reels 31 are stopped.

FIG. 66 is a flowchart showing medal payout (M_WIN_PAY) by winning in the fourteenth embodiment (C), which is a flowchart corresponding to FIG. 49 of the eleventh embodiment.
In the flowchart of the fourteenth embodiment (C) shown in FIG. 66, steps different from FIG. 49 are underlined in step numbers, and steps identical to FIG. 49 are given identical step numbers. ..

As shown in FIG. 66, in the fourteenth embodiment (C), when the payout amount data is acquired in step S391, the process proceeds to step S611, the payout amount data is stored as the acquired number data, and then the process proceeds to step S392. That is, in the fourteenth embodiment (C), the payout amount data is stored as the acquisition amount data between step S391 and step S392.
Further, as shown in FIG. 66, in the fourteenth embodiment (C), when the one-medal payout process is executed in step S398, the process proceeds to step S400, and "1" is subtracted from the payout amount data. Therefore, in the fourteenth embodiment (C), unlike FIG. 49 of the eleventh embodiment, "1" is not added to the acquired number data between step S398 and step S400.

67 and 68 are time charts for explaining the fourteenth embodiment (C).
67 shows the display start and display timing of the push order instruction information when the start switch 41 is turned on (operated) after the minimum game time has elapsed, and FIG. 68 shows the start switch before the minimum game time has elapsed. The timing of the display start and the display end of the push order instruction information when 41 is turned on (operated) is shown.
As described above, in the fourteenth embodiment (C), the acquired number data is maintained without being cleared even after all the reels 31 are stopped. Therefore, as shown in FIGS. 67 and 68, even after all the reels 31 are stopped, the acquisition order display LED 78 continues to display the pushing order instruction information (for example, “=1”).

Further, in the fourteenth embodiment (C), when the payout amount data is stored as the acquisition amount data in step S611 of FIG. 66, the LED display control (I_LED_OUT) during the interrupt process (I_INTR) executed after this process is performed. As a result, the number of medals acquired (for example, “10” when paying out 10 medals) is displayed on the acquired number display LED 78.
Therefore, in the fourteenth embodiment (C), as shown in FIG. 67 and FIG. 68, the pushing order instruction information (for example, “=1”) is displayed on the acquired number display LED 78 until the payout of medals. Subsequently, when the medals are paid out, the display of the acquisition number display LED 78 is switched from the push order instruction information to the acquisition number (for example, "=1" to "10").
The timing of starting display of the number of medals acquired, the timing of transmitting the pressing order instruction number as a control command, and the timing of starting and displaying the pressing order instruction image on the image display device 23 will be described in the fourteenth embodiment ( The same as in A).

In addition, in the fourteenth embodiment (C), the number-of-wins data is maintained without being cleared even after all reels 31 are stopped, and the number-of-payouts is obtained as the number-of-wins data in step S611 of the medal payout (M_WIN_PAY) by winning in FIG. Store data.
Therefore, as shown in FIGS. 67 and 68, even after all the reels 31 are stopped, it is possible to continue to display the push order instruction information on the acquired number display LED 78.
Further, until the payout of medals, the pressing order instruction information is continuously displayed on the acquisition number display LED 78, and when the medals are paid out, the display of the acquisition number display LED 78 is switched from the pressing order instruction information to the acquired number of pieces. Although the LED 78 is used as a display for both the pressing order instruction information and the acquired number, the display of the acquired number can be prevented.

<Fourteenth Embodiment (D)>
In the fourteenth embodiment (D), the display start timing of the push order instruction information on the acquired number display LED 78 is different from that of the fourteenth embodiment (A) to (D), and the reel 31 can be stopped. Occasionally, the display of the push order instruction information is started.
69 is a flowchart showing a main process (M_MAIN) in the fourteenth embodiment (D), which corresponds to FIG. 41 of the eleventh embodiment.
In the flowchart of the fourteenth embodiment (D) shown in FIG. 69, steps different from FIG. 41 are underlined in step numbers, and steps identical to FIG. 41 are given identical step numbers. ..

As shown in FIG. 69, in the fourteenth embodiment (D), when the rotation of the reel 31 is started in step S286, the process proceeds to step S604, and it is determined whether or not the reel 31 can be stopped. That is, it is determined whether or not the rotation of the reel 31 has reached a constant speed and the operation of the stop switch 42 has become acceptable. When it is determined that the reel 31 can be stopped, the process proceeds to step S284, and the push order instruction number set (M_ORG_INF) is executed.
The contents of the processing in the pressing order instruction number set (M_ORG_INF) in step S284 are the same as in the eleventh embodiment and the fourteenth embodiments (A) to (C).
The contents of the processing in the control command set 1 in steps S601 and S602 are the same as in the fourteenth embodiment (B) and (C).

70 and 71 are time charts for explaining the fourteenth embodiment (D).
70 shows the display start and display timing of the push order instruction information when the start switch 41 is turned on (operated) after the minimum game time has elapsed, and FIG. 71 shows the start switch before the minimum game time has elapsed. The timing of the display start and the display end of the pushing order instruction information when 41 is turned on (operated) is shown.
As described above, in the fourteenth embodiment (D), when the reel 31 can be stopped, the pushing order instruction number set is executed, so as shown in FIGS. 70 and 71, start before the minimum game time elapses. When the reel 31 can be stopped regardless of whether the switch 41 is turned on (operated) or the start switch 41 is turned on (operated) after the minimum game time has elapsed, the pushing order instruction information is displayed on the acquired number display LED 78. Is started.

Also in the fourteenth embodiment (D), as in the fourteenth embodiment (A) to (C), when the start switch 41 is turned on (operated) after the minimum game time has elapsed, it is shown in FIG. 70. As described above, after the rotation of the reel 31 is started and before the reel 31 can be stopped, the pressing order instruction image is started to be displayed on the image display device 23, and the start switch 41 is turned on before the minimum game time elapses (operation. 71), the display of the pressing order instruction image on the image display device 23 is started before the rotation of the reel 31 is started, as shown in FIG.
Therefore, also in the fourteenth embodiment (D), as in the fourteenth embodiment (A) to (C), the start switch 41 is on (operated) before or after the minimum game time has elapsed. Regardless of, the display of the push order instruction image on the image display device 23 is started before the reel 31 can be stopped.

Furthermore, in the fourteenth embodiment (D), when the reel 31 can be stopped regardless of whether the start switch 41 is on (operated) before or after the minimum game time has elapsed. The display of the pushing order instruction information on the acquired number display LED 78 is started.
Therefore, in the fourteenth embodiment (D), as shown in FIGS. 70 and 71, regardless of whether the start switch 41 is on (operated) before or after the minimum game time has elapsed. The display of the push order instruction image on the image display device 23 is started first, and then the display of the push order instruction information on the acquired number display LED 78 is started.

Further, in the fourteenth embodiment (D), the display start timing of the pushing order instruction information on the acquired number display LED 78 can be delayed until the reel 31 can be stopped. Therefore, similar to the fourteenth embodiment (B). It is possible to prevent the player who has been waiting for the winning of the rare role from being discouraged immediately after the operation of the start switch 41.
Furthermore, in the fourteenth embodiment (D), although the display start timing of the push order instruction information on the acquired number display LED 78 is delayed, when the reel 31 can be stopped, the push order instruction information is displayed on the acquired number display LED 78. Therefore, the player can be informed of the push order instruction information before the player operates the stop switch 42.

<Fourteenth Embodiment (E)>
In the fourteenth embodiment (E), similarly to the fourteenth embodiment (B), the pushing order instruction information is started to be displayed at the start of the rotation of the reel 31, and as in the fourteenth embodiment (C), the payout of medals is performed. The display of the push order instruction information is sometimes ended.
FIG. 72 is a flowchart showing a main process (M_MAIN) in the fourteenth embodiment (E), which is a flowchart corresponding to FIG. 62 of the fourteenth embodiment (B) and FIG. 65 of the fourteenth embodiment (C). ..
In FIG. 72, steps S271 to S286 are the same as FIG. 62 of the fourteenth embodiment (B), and steps S287 to S303 are the same as FIG. 65 of the fourteenth embodiment (C).

73 and 74 are time charts for explaining the fourteenth embodiment (E).
FIG. 73 shows the timing of the display start and the display end of the push order instruction information when the start switch 41 is turned on (operated) after the minimum game time has elapsed, and FIG. 74 shows the start switch before the minimum game time has elapsed. The timing of the display start and the display end of the pushing order instruction information when 41 is turned on (operated) is shown.
As shown in FIGS. 73 and 74, in the fourteenth embodiment (E), similarly to FIGS. 63 and 64 of the fourteenth embodiment (B), when the reel 31 starts to rotate, the pushing order of the acquired number display LED 78. The display of the instruction information is started, and similarly to FIGS. 67 and 68 of the fourteenth embodiment (C), when the medals are paid out, the display of the pushing order instruction information on the acquired number display LED 78 is ended.

Regarding the timing of starting display of the number of medals acquired, the timing of transmitting the pressing order instruction number as a control command, and the timing of starting and displaying the pressing order instruction image on the image display device 23, the fourteenth embodiment (B) will be described. ) Is the same.
Further, in the fourteenth embodiment (E), as in the fourteenth embodiment (B), when it is determined that the minimum game time has elapsed, the pushing order instruction number is stored as the acquired number data, so that the reel 31 At the start of rotation, the display of the push order instruction information on the acquired number display LED 78 is started.
Therefore, when the start switch 41 is turned on (operated) before the minimum game time elapses, the display start timing of the push order instruction information on the acquired number display LED 78 can be delayed until the minimum game time elapses. The player who has been waiting for the winning of the rare role can be prevented from being discouraged immediately after the start switch 41 is operated.

Further, in the fourteenth embodiment (E), similarly to the fourteenth embodiment (C), even after all the reels 31 are stopped, the acquired number data is maintained without being cleared, and the medal payout (M_WIN_PAY) by the winning in FIG. In step S611, the payout amount data is stored as the acquisition amount data.
Therefore, even after all the reels 31 are stopped, the pushing order instruction information can be continuously displayed on the acquired number display LED 78 until the medal is paid out, and further, the display of the acquired number display LED 78 is displayed when the medal is paid out. Since the pressing order instruction information is switched to the acquired number, the acquired number display LED 78 is used as a display for both the pressing order instruction information and the acquired number, but the display of the acquired number can be prevented.

<Fourteenth Embodiment (F)>
FIG. 75 is a front view showing the outline of the configuration including the reel 31, the stop switch 42, and the operation instruction lamp 25 in the fourteenth embodiment (F).
As shown in FIG. 75, in the fourteenth embodiment (F), a stop instruction lamp 25 is provided below each reel 31. The stop instruction lamp 25 indicates the reel 31 to be stopped and is composed of an LED lamp.

The stop instruction lamp 25, which is provided below the left reel 31 and lights up when instructing to stop the left reel 31, is the left stop instruction lamp 25.
Similarly, the stop instruction lamp 25, which is provided below the middle reel 31 and lights up when instructing to stop the middle reel 31, is the middle stop instruction lamp 25.
Further, the stop instruction lamp 25, which is provided below the right reel 31 and lights up when instructing to stop the right reel 31, is the right stop instruction lamp 25.
Then, the sub control board 80 controls turning on/off of each stop instruction lamp 25.

Here, the sub control board 80 includes a first sub control board and a second sub control board, and the stop instruction lamp 25 is electrically connected to the second sub control board.
Then, the second sub control board controls turning on/off of each stop instruction lamp 25 and displays an image on the image display device 23 based on the control command transmitted from the first sub control board.

Specifically, when the condition for operating the instruction function is satisfied, that is, when a winning combination having an advantageous pressing order such as a pressing order bell is selected in the AT, the main control board 50 controls the main processing (M_MAIN). In the command set 1, the push order instruction number as a control command is stored in the control command buffer.
Then, the main control board 50 transmits the control command stored in the control command buffer to the first sub-command by the control command transmission (step S464) during the interrupt process (I_INTR) executed after this process. Send to control board.

Further, when the first sub control board receives the control command transmitted from the main control board 50, the first sub control board stores (saves) the received control command in a predetermined storage area.
Furthermore, the first sub-control board executes the sub-main processing every 16 ms, analyzes the control command in the loop processing during this sub-main processing, and as a result determines that it is the push order instruction number. The lamp control command and the image command corresponding to the analysis result are stored in the command buffer.

Further, the first sub-control board transmits the lamp control command and the image command stored in the command buffer to the second sub-control board in the command transmission process during the next sub-main process.
Therefore, as in the fourteenth embodiment (A), the main control board 50 transmits the pressing order instruction number as the control command to the first sub control board, and then the second sub control board displays the lamp control command and the image. It takes about 32 ms (=sub-main processing cycle 16 ms×2) to receive the command.

Then, the second sub-control board executes the control of turning on/off the (left, middle, right) stop instruction lamp 25 based on the received lamp control command, and performs the drawing process based on the received image command. Then, the image is displayed on the image display device 23.
For example, when the lamp control command and the image command indicating the first left stop are received, the second sub control board turns on the left stop instruction lamp 25 and turns off the middle stop instruction lamp 25 and the right stop instruction lamp 25. At the same time, an image prompting the operation of the left stop switch 42 is displayed on the image display device 23.

In addition, in the fourteenth embodiment (F), the second sub-control board executes an interrupt process every 1 ms, and in this interrupt process, controls the turning on/off of each stop instruction lamp 25.
Therefore, the second sub-control board takes about 1 ms from receiving the lamp control command transmitted from the first sub-control board to turning on the stop instruction lamp 25 corresponding to the reel 31 to be stopped. It costs.

Further, as described above, it takes about 32 ms from when the main control board 50 transmits the control command to the first sub control board until the second sub control board receives the lamp control command.
Therefore, it takes about 33 ms (=32 ms+1 ms) from when the main control board 50 transmits the control command to the first sub control board until the second sub control board turns on the stop instruction lamp 25.

Also in the fourteenth embodiment (F), as in the fourteenth embodiment (A), the second sub-control board executes the drawing process at 30 fps (frames per second), so that one image is displayed. It takes about 33.33 ms to display on the device 23.
Therefore, also in the fourteenth embodiment (F), as in the fourteenth embodiment (A), after the main control board 50 transmits the control command to the first sub control board, the second sub control board displays the image. It takes about 65.33 ms (=32 ms+33.33 ms) to display the pressing order instruction image on the display device 23.
As described above, in the fourteenth embodiment (F), the stop instruction lamp 25 is turned on first, and then the push order instruction image is displayed on the image display device 23.

76 and 77 are time charts for explaining the fourteenth embodiment (F).
FIG. 76 shows the display start and display timing of the push order instruction information when the start switch 41 is turned on (operated) after the minimum game time has elapsed, and FIG. 77 shows the start switch before the minimum game time has elapsed. The timing of the display start and the display end of the pressing order instruction information when 41 is turned on (operated) is shown.

Although not shown, also in the fourteenth embodiment (F), similarly to the fourteenth embodiment (B), after the reel rotation start preparation is executed, the pushing order instruction number set is executed.
Therefore, as shown in FIGS. 76 and 77, also in the fourteenth embodiment (F), as in the fourteenth embodiment (B), is the operation time of the start switch 41 before the elapse of the minimum game time? Alternatively, regardless of whether or not the time has elapsed, when the reel 31 starts to rotate, the display of the pushing order instruction information on the acquired number display LED 78 is started.

Although not shown, in the fourteenth embodiment (F), when the third stop switch 42 is detected to be turned on, the acquired number data is cleared. Then, due to the interrupt processing executed after this processing, the display of the acquired number display LED 78 becomes "00".
Therefore, in the fourteenth embodiment (F), as shown in FIGS. 76 and 77, when the third stop switch 42 is turned on (operated), the display of the pushing order instruction information on the acquired number display LED 78 ends.
The timing for starting the display of the number of medals acquired and the timing for transmitting the pressing order instruction number as the control command are the same as in the fourteenth embodiments (A) to (E).

Further, as described above, it takes about 33 ms from when the main control board 50 transmits the control command to the first sub control board until the second sub control board lights the stop instruction lamp 25. It takes about 65.33 ms from when the main control board 50 transmits the control command to the first sub control board until the second sub control board displays the pressing order instruction image on the image display device 23.

Therefore, when the start switch 41 is turned on (operated) after the lapse of the minimum game time, as shown in FIG. 76, first, after the reel 31 starts rotating and before the reel 31 can be stopped, it is first stopped. The instruction lamp 25 is turned on, and then the push order instruction image is displayed on the image display device 23.
On the other hand, for example, when the start switch 41 is turned on (operated) 1 second before the minimum game time elapses, it takes about 1 second from the start (operation) of the start switch 41 to the start of rotation of the reel 31. Therefore, as shown in FIG. 77, before the reel 31 starts to rotate, the stop instruction lamp 25 is first turned on, and then the push order instruction image is displayed on the image display device 23.

Further, when the start switch 41 is turned on (operated) after the minimum game time has elapsed, first, as shown in FIG. 76, the push order instruction information is displayed on the acquired number display LED 78, and then the stop instruction lamp 25 Lights up, and finally, the push order instruction image is displayed on the image display device 23.
On the other hand, when the start switch 41 is turned on (operated) before the minimum game time elapses, as shown in FIG. 77, the stop instruction lamp 25 is first turned on, and then the image display device 23 is pressed. The order instruction image is displayed, and finally, the push order instruction information is displayed on the acquired number display LED 78.

Further, in the fourteenth embodiment (F), like the fourteenth embodiment (B) and (E), when it is determined that the minimum game time has elapsed, the pushing order instruction number is stored as the acquired number data. Thus, at the start of rotation of the reel 31, the display of the pushing order instruction information on the acquired number display LED 78 is started.
Therefore, when the start switch 41 is turned on (operated) before the minimum game time elapses, the display start timing of the push order instruction information on the acquired number display LED 78 can be delayed until the minimum game time elapses. The player who has been waiting for the winning of the rare role can be prevented from being discouraged immediately after the start switch 41 is operated.

As shown in FIGS. 76 and 77, regardless of whether the start switch 41 is turned on (operated) before or after the minimum game time has elapsed, the stop instruction lamp 25 is turned on first. After that, the pressing order instruction image is displayed on the image display device 23.
Both the stop instruction lamp 25 and the image display device 23 are controlled by the second sub-control board. However, since the drawing process needs to be executed in order to display an image on the image display device 23, the stop instruction lamp is correspondingly increased. 25 turns on faster.

<Fourteenth Embodiment (G)>
The fourteenth embodiment (G) is provided with a dedicated 7-segment display (7-segment) for displaying the pushing order instruction information, and the display end timing of the pushing order instruction information is the fourteenth embodiment (F). Other than that, the other points are the same as those in the fourteenth embodiment (F).
The dedicated 7-segment display for displaying the push order instruction information is referred to as a push order instruction LED.
In addition, in the fourteenth embodiment (G), the RWM 53 has a storage area for pressing order instruction data. The push order instruction data is data for displaying the push order instruction information on the push order instruction LED.

78 and 79 are time charts for explaining the fourteenth embodiment (G).
78 shows the display start and display timing of the push order instruction information when the start switch 41 is turned on (operated) after the minimum game time has elapsed, and FIG. 79 shows the start switch before the minimum game time has elapsed. The timing of the display start and the display end of the pushing order instruction information when 41 is turned on (operated) is shown.

Also in the fourteenth embodiment (G), similarly to the fourteenth embodiments (B) and (F), after the reel rotation start preparation is executed, the pushing order instruction number set is executed.
Therefore, as shown in FIGS. 78 and 79, also in the fourteenth embodiment (G), as in the fourteenth embodiment (B) and (F), when the start switch 41 is on (operated), the minimum game is played. Whether or not the time has elapsed or after the time has elapsed, when the rotation of the reel 31 is started, the display of the push order instruction information is started.
In the fourteenth embodiment (G), the push order instruction number is set in the storage area of the push order instruction data of the RWM 53. As a result, in the interrupt process executed after this process, the push order instruction information is displayed on the push order instruction LED.

In addition, in the fourteenth embodiment (A) to (F), since the push order instruction information is displayed on the acquired number display LED 78, the acquired number data is cleared on the acquired number display LED 78 by clearing the acquired number data before the medal is paid out. It was possible to display the number of medals acquired.
On the other hand, in the fourteenth embodiment (G), even when paying out medals, the pushing order instruction data is maintained without being cleared. Therefore, as shown in FIG. 78 and FIG. The push order instruction information (for example, "=1") is continuously displayed on the order instruction LED.

Further, in the fourteenth embodiment (G), when the payout of medals is completed, the pushing order instruction data is cleared. Then, due to the interrupt processing executed after this processing, the display of the push order instruction LED becomes "00".
Therefore, in the fourteenth embodiment (G), as shown in FIGS. 78 and 79, the display of the pushing order instruction information on the pushing order instruction LED is finished after the payout of the medals.

As described above, in the fourteenth embodiment (G), the pushing order instruction information is not displayed on the acquisition number display LED 78 but is displayed on the dedicated pushing order instruction LED. Therefore, the pushing order instruction information is displayed when the medals are paid out. Even if it continues, it is possible not to interfere with the display of the number of medals acquired.
It should be noted that the display start timing of the number of medals obtained, the transmission timing of the push order instruction number as a control command, the display start and display end timing of the operation instruction lamp 25, and the display start of the push order instruction image on the image display device 23. The timing for ending display is the same as in the fourteenth embodiment (F).

<Summary of 14th Embodiment>
From the time the start switch 41 is turned on (operated) until the time when the reel 31 can be stopped (the rotation of the reel 31 reaches a constant speed and the operation of the stop switch 42 can be accepted), the pushing order instruction information is displayed. If shown, it is possible to inform the player of the correct pressing sequence before the player turns on (operates) the stop switch 42.
Therefore, the timing to start displaying the push order instruction information is
1) When the start switch 41 is turned on (operated) 2) After the start switch 41 is turned on (operated) and before the rotation of the reel 31 is started 3) When the rotation of the reel 31 is started 4) After the rotation of the reel 31 And before the reel 31 can be stopped 5) When the reel 31 can be stopped.

When displaying the push order instruction information on the acquired number display LED 78, if the display of the push order instruction information is completed from the time when the third stop switch 42 is turned on (operated) to the time when the medals are paid out, the medals are displayed. It is possible not to interfere with the display of the acquired number of sheets.
Therefore, the timing for ending the display of the push order instruction information is
1) When the third stop switch 42 is turned on (operated) 2) When the third stop switch 42 is turned off after being turned on (when the player releases the third stop switch 42)
3) When all reels 31 are stopped. 4) When paying out medals.
When the push order instruction information is displayed on the dedicated push order display LED, the display of the push order instruction information may be continued when the medals are paid out, and the display of the push order instruction information may be ended after the medals are paid out. ..

Further, by the time the sub-control board 80 (second sub-control board) displays the pressing order instruction image on the image display device 23, the control commands are generated in the main control board 50, and the main control board 50 to the sub-control board 80. Since a control command is transmitted to the sub-control board 80, a control command is received and analyzed by the sub-control board 80, and drawing processing and display are performed on the sub-control board 80 (second sub-control board), a certain time is required.
Therefore, even when the main control board 50 simultaneously displays the push order instruction information on the acquired number display LED 78 and transmits the control command to the sub control board 80, the push order instruction image is displayed on the image display device 23. Will be delayed.

Further, depending on whether the start switch 41 is turned on (operated) before or after the minimum game time has elapsed, the reel 31 starts to rotate and the push order instruction image starts to be displayed on the image display device 23. The order of may change.
Therefore, as the timing of starting the display of the push order instruction image on the image display device 23,
1) After the start switch 41 is turned on (operated) and before the rotation of the reel 31 is started. 2) After the rotation of the reel 31 and before the reel 31 can be stopped.

In addition, even after the main control board 50 transmits the control command to the sub control board 80 and before the sub control board 80 (second sub control board) finishes displaying the pressing order instruction image on the image display device 23. , Takes a certain amount of time.
Therefore, the timing of ending the display of the pressing order instruction image on the image display device 23 is after the third stop switch 42 is turned on (operated).
Then, the display start timing of the push order instruction information on the acquired number display LED 78, the display end timing of the push order instruction information on the acquired number display LED 78, the display start timing of the push order instruction image on the image display device 23, and the push order. The display end timing of the instruction image on the image display device 23 is not limited to the combination shown in the fourteenth embodiments (A) to (G), and can be set in an appropriate combination.

In the game in which the pushing order instruction information is displayed on the acquired number display LED 78, even if a mistake in the pushing order occurs in the middle of the game, the pushing order instruction information is displayed until a predetermined time after the third stop switch 42 is turned on (operated). May be continued to be displayed as it is, or the display of the push-order instruction information may be terminated at the time when the push-order error occurs.
Similarly, in the game in which the push order instruction image is displayed on the image display device 23, even if a push order error occurs in the middle, the push order instruction is given until a predetermined time after the third stop switch 42 is turned on (operated). The image may continue to be displayed as it is, or the display of the push-order instruction image may be terminated when a push-order error occurs.

Further, at the time of replay winning when three coins are inserted, three medals are automatically bet and the game can be started. Therefore, one bet display LED 79a, two bet display LED 79b, three bet display LED 79c, game start display LED 79d, and replay display The LED 79f lights up.
At this time, when the third stop switch 42 is operated and the symbol combination corresponding to the replay is stopped and displayed, first, the 1 bet display LED 79a is turned on, and the 2 bet display LED 79b, the 3 bet display LED 79c, the game start display. The LED 79d and the replay display LED 79f are turned off.

After that, the 2 bet display LED 79b and the 3 bet display LED 79c are sequentially turned on, and finally the 1 bet display LED 79a, the 2 bet display LED 79b, the 3 bet display LED 79c, the game start display LED 79d, and the replay display LED 79f are turned on.
Then, in the replay prize when three coins are inserted, when the 1 bet display LED 79a is turned on and the 2 bet display LED 79b, the 3 bet display LED 79c, the game start display LED 79d, and the replay display LED 79f are turned off, the pressing order The display of the instruction information on the acquired number display LED 78 may be terminated.

Further, at the time of winning a small winning combination, when the third stop switch 42 is turned on, when the third stop switch is turned off, when all reels 31 are stopped, or when medals are paid out, the display of the push order instruction information on the acquired number display LED 78 is ended. When the replay is won, the 1 bet display LED 79a is turned on, and the 2 bet display LED 79b, the 3 bet display LED 79c, the game start display LED 79d, and the replay display LED 79f are turned off. The display of the instruction information may be ended.
That is, the display end timing of the push order instruction information may be different between the small winning combination and the replay winning combination.
Of course, the display end timing of the push order instruction information may be the same for the small winning combination and the replay winning.

Although the fourteenth embodiment of the present invention has been described above, the present invention is not limited to the above-described contents, and the following modifications are possible.
(1) In the fourteenth embodiment (A), two sets of 8-bit parallel communication lines are used, one parallel communication line transmits the first control command to the sub-control board 80, and the other parallel communication line transmits the first control command. By transmitting the two control commands to the sub control board 80, the control command composed of 2 bytes of data can be transmitted to the sub control board 80 by one interrupt process.

However, the present invention is not limited to this, and for example, only one set of 8-bit parallel communication lines may be used to transmit a control command composed of 2-byte data to the sub-control board 80.
In this case, the first control command and the second control command may be sequentially transmitted by transmitting the control command during one interrupt process. As a result, a control command composed of 2-byte data can be transmitted to the sub control board 80 by one interrupt process.

Further, the first control command may be transmitted by transmitting the control command during one interrupt processing, and the second control command may be transmitted by transmitting the control command during the next interrupt processing. As a result, a control command composed of 2-byte data may be transmitted to the sub control board 80 by two interrupt processes.
Furthermore, the control command may be transmitted from the main control board 50 to the sub control board 80 by serial communication, not limited to parallel communication.
Further, the control command may be transmitted from the main control board 50 to the sub control board 80 by electrical connection, or the control command may be transmitted from the main control board 50 to the sub control board 80 by connection using an optical communication means. Good.

(2) In the fourteenth embodiment (A), the main control board 50 transmits the pressing order instruction number as a control command to the sub control board 80 (first sub control board), and the sub control board 80 (second sub control). The board) executes the drawing process based on the received press order instruction number and displays the press order instruction image on the image display device 23.
However, not limited to this, for example, the main control board 50 transmits the condition device number to the sub control board 80 (first sub control board) as a control command, and the sub control board 80 (second sub control board) The drawing process may be executed based on the received condition device number to display the push order instruction number on the image display device 23.

Further, for example, the main control board 50 transmits the effect group number as a control command to the sub control board 80 (first sub control board), and the sub control board 80 (second sub control board) receives the received effect group number. It is also possible to execute the drawing process based on the above and display the pressing order instruction number on the image display device 23.
(3) The first to fourteenth embodiments and the various modifications shown in the first to fourteenth embodiments are not limited to being performed alone, but can be appropriately combined and implemented.

<Fifteenth Embodiment>
The fifteenth embodiment relates to the timing of the addition process of medals inserted from the medal insertion slot 47.
The fifteenth embodiments (A) to (C) in which the timing of the medal addition processing is different will be described below.

<Fifteenth Embodiment (A)>
The structure of the medal selector in the fifteenth embodiment (A) is similar to the structure of the medal selector shown in FIG. 2 of the first embodiment.
That is, when a medal is inserted from the medal insertion slot 47, the medal flows down the medal passage in the medal selector. On the medal passage in the medal selector, a passage sensor 46, an insertion sensor 44a, and an insertion sensor 44b are provided from the upstream side. A blocker 45 is provided between the passage sensor 46 and the input sensor 44a.

The medals inserted from the medal insertion slot 47 first pass through the passage sensor 46 and then reach the position of the blocker 45. When the blocker 45 is on, the medals flowing down the medal passage pass through the blocker 45 and then reach the positions of the insertion sensors 44a and 44b.
The input sensors 44a and 44b are installed at a predetermined distance.
Before the medal reaches the positions of the insertion sensors 44a and 44b, the insertion sensors 44a and 44b are both off.
When a medal flows down the medal passage, first, the insertion sensor 44a is turned on and the insertion sensor 44b remains off.

When a medal further flows down the medal passage, the insertion sensor 44a remains on and the insertion sensor 44b changes from off to on.
After that, when a medal further flows down the medal passage, the insertion sensor 44a is turned off and the insertion sensor 44b remains on.
After that, when medals further flow down the medal passage, the insertion sensor 44a remains off and the insertion sensor 44b changes from on to off.
Then, the medals that have passed through the insertion sensors 44a and 44b reach the hopper 35.

FIG. 80 is a diagram showing execution timing of medal addition processing in the fifteenth embodiment (A).
At timing (a) in FIG. 80, the closing sensors 44a and 44b are both off.
At the timing of (b) in FIG. 80, the closing sensor 44a is on and the closing sensor 44b is off.
The state (b) in FIG. 80 corresponds to the state (a) in FIG. 4 in the first embodiment (B).
Further, when the state of (b) in FIG. 80 continues for a predetermined time or more, the main control board 50 determines that there is a medal passing error, and sends an error command to the sub control board 80. Then, when the sub control board 80 receives the error command, the sub control board 80 outputs an error sound from the speaker 22.

At timing (c) in FIG. 80, the closing sensors 44a and 44b are both on.
The state (c) in FIG. 80 corresponds to the state (b) or (c) in FIG. 4 in the first embodiment (B).
If the state of (c) in FIG. 80 continues for a predetermined time or longer, the main control board 50 determines that there is a medal passing error and the sub control board 80 outputs an error, as in the case of (b) in FIG. Send a command. Then, when the sub control board 80 receives the error command, the sub control board 80 outputs an error sound from the speaker 22.

At the timing of (d) in FIG. 80, the closing sensor 44a is off and the closing sensor 44b is on.
The state (d) in FIG. 80 corresponds to the state (d) in FIG. 4 in the first embodiment (B).
Further, if the state of (d) in FIG. 80 continues for a predetermined time or more, the main control board 50 determines that there is a medal passing error, as in the cases of (b) and (c) in FIG. The error command is transmitted to the board 80. Then, when the sub control board 80 receives the error command, the sub control board 80 outputs an error sound from the speaker 22.

At timing (e) in FIG. 80, the closing sensors 44a and 44b are both off.
The state (e) in FIG. 80 corresponds to the state (e) in FIG. 4 in the first embodiment (B).
Further, in the state of (e) in FIG. 80, the main control board 50 determines that a medal has been inserted, and executes the "1" addition process (bet process or credit process) of the medal.
Here, when the bet number is less than the specified number at the time of the state of (e) in FIG. 80, the main control board 50 executes the bet number “1” addition process. For example, when the specified number in the game is “3” and the bet number at that time is “1”, the bet number is changed from “1” to “2” by the addition process of the bet number. To update.

Further, when the state of (e) in FIG. 80 is reached, when the bet amount has already reached the prescribed number, and the credit amount has not reached the maximum number of “50”, the main control is performed. The board 50 executes a process of adding “1” to the number of credits. For example, when the number of credits at that time is “20”, the number of credits is updated to “21”.
Further, in the state of (e) in FIG. 80, the main control board 50 transmits a closing command to the sub control board 80. Then, when the sub-control board 80 receives the closing command, the sub-control board 80 outputs the closing sound from the speaker 22.
When a medal passing error occurs before the state of (e) in FIG. 80 is reached, the main control board 50 does not execute the medal “1” addition process and does not transmit the throwing command.

Further, when a plurality of medals are inserted from the medal insertion slot 47, (a) to (e) in FIG. 80 are repeated.
When the bet number reaches the specified number by executing the bet number “1” addition process in the state (e) in FIG. 80, the main control board 50 operates the start switch 41. In a state in which the game can be accepted (a game can be started), the game start display LED 79d is turned on.

<Fifteenth Embodiment (B)>
The fifteenth embodiment (B) is different from the fifteenth embodiment (A) in the execution timing of the medal “1” addition process.
The structure of the medal selector in the fifteenth embodiment (B) is also similar to the structure of the medal selector shown in FIG. 2 of the first embodiment.

FIG. 81 is a diagram showing execution timing of medal addition processing in the fifteenth embodiment (B).
Since (a) to (c) in FIG. 81 are the same as (a) to (c) in FIG. 80, description thereof will be omitted, and (d) and (e) in FIG. Since it is different from (d) and (e) in FIG. 80, it will be described below.

At the timing of (d) in FIG. 81, the closing sensor 44a is off and the closing sensor 44b is on.
The state (d) in FIG. 81 corresponds to the state (d) in FIG. 4 in the first embodiment (B).
Then, in the fifteenth embodiment (B), in the state of (d) in FIG. 81, the main control board 50 determines that a medal has been inserted, and performs a “1” addition process for the medal (a bet process or a credit process. ) Is executed. At this time, when the bet number is less than the specified number, the bet number “1” is added, and when the bet number has already reached the specified number, the credit number becomes the maximum number “50”. When the number of credits has not been reached, the process of adding "1" to the number of credits is executed, as in the fifteenth embodiment (A).

Further, in the fifteenth embodiment (B), in the state of (d) in FIG. 81, the main control board 50 sends a close command to the sub control board 80. Then, when the sub-control board 80 receives the closing command, the sub-control board 80 outputs the closing sound from the speaker 22.
However, in the fifteenth embodiment (B), when the state of (d) in FIG. 81 continues for a predetermined time or longer, the main control board 50 determines that there is a medal passing error, and sends an error command to the sub control board 80. .. Then, when the sub control board 80 receives the error command, the sub control board 80 outputs an error sound from the speaker 22.

For this reason, in the fifteenth embodiment (B), there is a case where after performing the medal “1” addition process and outputting the insertion sound, it is determined that there is a medal passing error and an error sound is output.
In this way, when the state of (d) in FIG. 81 is reached, the medal “1” addition process is executed and the insertion sound is output, and thereafter, the state of (d) in FIG. 81 is kept for a predetermined time or longer. When the error sound is continuously output, the insertion sound is output and then the error sound is output. Therefore, even if an error occurs, the player can be notified by the insertion sound that the medal has been inserted. ..
When a medal passing error occurs in the state of (b) or (c) in FIG. 81, the main control board 50 does not execute the medal “1” addition process and does not transmit the throwing command.

At timing (e) in FIG. 81, the closing sensors 44a and 44b are both off.
Further, when a plurality of medals are inserted from the medal insertion slot 47, (a) to (e) in FIG. 81 are repeated.
When the bet number reaches the specified number by executing the bet number “1” addition process, the main control board 50 operates the start switch 41 in the state of (e) in FIG. 81. The game start display LED 79d is turned on in a state in which the game can be accepted.
Therefore, in the fifteenth embodiment (B), the medal "1" addition process is executed, the timing for outputting the insertion sound and the operation of the start switch 41 are made acceptable, and the game start display LED 79d is turned on. The timing is different.

Here, as described in the fifteenth embodiment (A), the medal “1” addition process is performed at the timing (e) in FIG. 80 (when both the insertion sensors 44a and 44b are turned off). It is common to do this.
However, when the medal flows down the medal passage to the position of (d) in FIG. 81, the medal has already passed through the blocker 45 and therefore enters the hopper 35.
Therefore, in the fifteenth embodiment (B), at the timing of (d) in FIG. 81 (when the insertion sensor 44b remains on and the insertion sensor 44a is switched from on to off), the medal “1” is obtained. Executes addition processing. As a result, it is possible to prevent so-called swallowing of medals, that is, medals enter the hopper 35 even if the medal addition process is not executed.

Further, in the fifteenth embodiment (B), as described above, when the state of (d) in FIG. 81 continues for a predetermined time or longer, the main control board 50 determines that a medal passing error has occurred and causes the sub-control board 80 to display. The error command is transmitted, and the sub control board 80 outputs an error sound from the speaker 22. In this case, when the error sound is output, the medal addition process has already been executed and the insertion sound has been output. Therefore, the error is canceled and the medals jammed in the medal selector may be inserted into the hopper 35. As a result, it is possible to prevent the player from being disadvantaged.

When the medals are continuously inserted from the medal insertion slot 47 and the maximum number of credits reaches “50”, the 51st medal is removed from the medal passage at the position of the blocker 45. It is returned from the medal payout opening 16.
At this time, when the 50th medal is in the state of (d) in FIG. 81 (the insertion sensor 44a is off and the insertion sensor 44b is on), the credit number "1" is added, and the blocker is added. Turn off 45. As a result, the 51st medal can be reliably returned from the medal payout opening 16 without being swallowed.

Further, in the fifteenth embodiment (B), when the bet number reaches the specified number by executing the bet number “1” addition process in the state of (d) in FIG. 81, the start switch 41 is operated. Is ready to be accepted. At this time, when the start switch 41 is operated, the main control board 50 sends a start command to the sub control board 80. Then, upon receiving the start command, the sub control board 80 outputs a sound effect from the speaker 22.

Here, as in the fifteenth embodiment (A), at the timing (e) in FIG. 80, when the operation of the start switch 41 is made acceptable and the closing command is transmitted to the sub control board 80, There is a possibility that the closing sound and the sound effect based on the operation of the start switch 41 overlap.
Therefore, in the fifteenth embodiment (B), a closing command is transmitted to the sub control board 80 at the timing (d) in FIG. 81, and the start switch 41 is operated at the timing (e) in FIG. 81. Ready to accept. As a result, the closing sound and the sound effect based on the operation of the start switch 41 can be prevented from overlapping.

<Fifteenth Embodiment (C)>
The fifteenth embodiment (C) is the same as the fifteenth embodiment (B) in the execution timing of the medal “1” addition process, but the output timing of the insertion sound is the same as that of the fifteenth embodiment (B). It is different.
The structure of the medal selector in the fifteenth embodiment (C) is also similar to the structure of the medal selector shown in FIG. 2 of the first embodiment.

FIG. 82 is a diagram showing execution timing of medal addition processing in the fifteenth embodiment (C).
Since (a) to (c) in FIG. 82 are the same as (a) to (c) in FIGS. 80 and 81, description thereof will be omitted, and (d) and (e) in FIG. Is different from (d) and (e) in FIGS. 80 and 81, and will be described below.

At timing (d) in FIG. 82, the closing sensor 44a is off and the closing sensor 44b is on.
The state (d) in FIG. 82 corresponds to the state (d) in FIG. 4 in the first embodiment (B).
Then, in the fifteenth embodiment (C), when the state of (d) in FIG. 82 is reached, the main control board 50 determines that a medal has been inserted, and performs the “1” addition process for the medal (bet process or credit process. ) Is executed. At this time, when the bet number is less than the specified number, the bet number “1” is added, and when the bet number has already reached the specified number, the credit number becomes the maximum number “50”. When the number of credits has not been reached, the process of adding "1" to the number of credits is executed in the same manner as in the fifteenth embodiment (A) and (B).

However, in the fifteenth embodiment (C), unlike the fifteenth embodiment (B), at the timing of (d) in FIG. 82, the main control board 50 does not transmit the closing command to the sub control board 80.
Then, in the fifteenth embodiment (C), the main control board 50 transmits a closing command to the sub control board 80 at the timing of (e) in FIG. 82. Then, when the sub-control board 80 receives the closing command, the sub-control board 80 outputs the closing sound from the speaker 22.

Here, it is assumed that the state (d) in FIG. 82 continues for a predetermined time or more, the main control board 50 determines that the medal passing error has occurred, and transmits an error command to the sub control board 80. Then, it is assumed that the sub control board 80 outputs an error sound from the speaker 22.
In this case, the medal “1” addition process is executed, but the insertion sound is not output, but the error sound is output. Thereby, the error notification can be prioritized.

Then, when the error is released, the main control board 50 transmits a closing command to the sub control board 80, and the sub control board 80 outputs a closing sound from the speaker 22 based on the received closing command. As a result, it is possible to inform the player that a medal has been inserted, so that the player can be relieved.
Further, in the state of (e) in FIG. 82, when the bet number reaches the specified number by executing the bet number “1” addition process, the operation of the start switch 41 can be accepted. Turning on the game start display LED 79d is the same as in the fifteenth embodiment (A) and (B).

<Sixteenth Embodiment>
The sixteenth embodiment relates to a chute passage 48 for guiding the medals that have passed through the insertion sensors 44a and 44b of the medal selector to the hopper 35, and a chute sensor 49 provided in the middle of the chute passage 48.
FIG. 83 is a view showing the medal selector, the chute passage 48, and the chute sensor 49. The medal M inserted from the medal insertion port 47 passes through the insertion sensor 44a, the insertion sensor 44b, and the chute sensor 49, and the hopper. It is a schematic diagram which shows a mode to 35.

The chute passage 48 is a passage for guiding the medal M passing through the insertion sensors 44a and 44b of the medal selector to the hopper 35, and is connected to the downstream side of the medal passage of the medal selector. Then, the medal M inserted from the medal insertion slot 47 reaches the hopper 35 through the medal passage of the medal selector and the chute passage 35.

The shoot sensor 49 is a sensor provided for determining whether or not there is a jammed medal or a goto action, and is configured by using an optical sensor having a light emitting/receiving unit, and is arranged at a predetermined position in the middle of the chute passage 48. And is electrically connected to the main control board 50.
Since the chute passage 48 is a passage for guiding the medal M, which has passed through the insertion sensors 44a and 44b, to the hopper 35, the chute sensor 49 is arranged downstream of the insertion sensors 44a and 44b.

In the sixteenth embodiment, the insertion monitoring counter adds “1” when the insertion sensors 44a and 44b detect the passage of the medal M (when both the insertion sensors 44a and 44b are turned off→on→off). This is a counter that is decremented by "+1") and decremented by "1"("-1") when the shoot sensor 49 detects passage of the medal M. Therefore, the injection monitoring counter repeats "1" and "0" in the normal state.
The timing of adding “1” to the closing monitoring counter is the timing at which the closing sensor 44b is turned off (the timing shown in FIGS. 4 and 80 to 82(e)).
Further, the timing of adding “1” to the closing monitoring counter is not limited to the timing at which the closing sensor 44b is turned on, but for example, the timing at which the closing sensor 44a is turned on (see FIG. 4 and FIGS. (B) timing) or the timing at which the closing sensor 44a changes from on to off (timing at (c) in FIGS. 4 and 80 to 82), and the timing at which the closing sensor 44b changes from off to on. (The timing of (d) of FIG. 4 and FIGS. 80 to 82) may be used. This is because if the medal M reaches these timings, it is considered that the medal M will enter the hopper 35.
Further, when the medal M passes through the shoot sensor 49, the shoot sensor 49 is turned off→on→off, but the timing of subtracting “1” from the throw-in monitoring counter is the timing at which the shoot sensor 49 is turned off. is there.

When the insertion sensors 44a and 44b detect the passage of the medal M (insertion monitoring counter=“+1”) and the shoot sensor 49 does not detect the passage of the medal M, the insertion sensors 44a and 44b detect the medal M. When it is further detected that the coin has passed, the insertion monitoring counter becomes “+2”, and the main control board 50 determines that there is a medal passing error.
Furthermore, when the insertion sensors 44a and 44b do not detect the passage of the medal M and only the shoot sensor 49 detects the passage of the medal M, the insertion monitoring counter becomes "-1", and the main control board 50 sets the medal. Judge as a passage error.

The main control board 50 determines that the medal passing error is not limited to when the insertion monitoring counter is "+2" and "-1". For example, the main control board 50 may determine a medal passing error when the insertion monitoring counter has a predetermined value of “+2” or more and a predetermined value of “−1” or less.
Further, when the shoot sensor 49 detects the medal M and continues to detect the medal M even after a predetermined time elapses, the main control board 50 determines that there is a medal retention error. Then, when the main control board 50 determines that there is a medal retention error, it stops the progress of the game until the error is released.

As shown in FIG. 83, the medals M inserted from the medal insertion slot 47 reach the hopper 35 through the medal passage and the chute passage 48. At this time, it passes through the closing sensor 44a, the closing sensor 44b, and the chute sensor 49.
Here, it is assumed that the medal M is blocked at the tip of the chute passage 48. In FIG. 83, the position of M1 indicates the position of the medal M placed in the medal insertion slot 47, the position of M2 indicates the position of the medal M blocked at the tip of the chute passage 48, and the position of M3 indicates the shoot. The position of the second medal M from the tip of the passage 48 is shown, and the position of M4 shows the position of the third medal M from the tip of the chute passage 48.

As shown in FIG. 83, in the sixteenth embodiment, when the medal M is jammed at the tip of the chute passage 48, the chute is placed at a position where the third medal M (M4) can be detected from the tip of the chute passage 48. The sensor 49 is arranged.
Therefore, when the medal M is clogged at the tip of the chute passage 48, the third medal M (M4) from the tip of the chute passage 48 is detected by the chute sensor 49, and if this state continues for a predetermined time or longer, the main control board 50 determines that it is a medal retention error, and stops the progress of the game until the error is released.

For example, it is assumed that three medals M are inserted from the medal insertion slot 47 when the defined number is “3” and the bet number and the credit number are both “0”. In this case, when the insertion sensors 44a and 44b detect the passage of the third medal M, the main control board 50 brings the operation of the start switch 41 into a state in which the operation can be accepted (the game can be started) and the game start display LED 79d. Light up. At this time, when the first medal M (M2) is blocked at the tip of the chute passage 48, the third medal M (M4) is detected by the chute sensor 49. Then, if this state continues for a predetermined time or more, the main control board 50 determines that there is a medal retention error and stops the progress of the game. As a result, it is possible to prevent the player from playing the game when the shoot passage 48 is filled with the medals M.

The position of the chute sensor 49 is not limited to the position where the third medal M (M4) from the tip of the chute passage 48 can be detected when the medal M is jammed at the tip of the chute passage 48. If the prescribed number is “N”, the chute sensor 49 may be arranged at a position where the Nth medal M can be detected from the tip of the chute passage 48 when the tip of the chute passage 48 is clogged with medals M. .. As a result, it is possible to prevent the player from playing the game when the shoot passage 48 is filled with the medals M.

<17th Embodiment>
The seventeenth embodiment relates to a payout medal passage 134 that guides the medals ejected from the ejection unit 103 of the medal payout device 15 to the medal payout opening 16.
84 is a front view of the passage forming member 130, FIG. 85 is a rear view of the passage forming member 130, FIG. 86 is a left side view of the passage forming member 130, and FIG. It is an AA arrow sectional view.

The slot machine 10 includes a box-shaped cabinet 13 having an open front surface, and a front door 12 that closes the opening of the cabinet 13.
A medal payout device 15 is arranged below the inside of the cabinet 13.
Furthermore, a medal insertion slot 47, a start switch 41, a stop switch 42, etc. are arranged in the center of the front surface of the front door 12, and a medal selector is provided on the rear surface of the front door 12 corresponding to the medal insertion slot 47. Are arranged.
Further, a medal payout opening 16 is provided in the lower part of the front door 12, and a medal tray for receiving the medals paid out from the medal payout opening 16 is provided in the lower front part of the front door 12, and the back surface of the front door 12 is provided. A passage forming member 130 is attached to the lower portion.

Further, as shown in FIGS. 84 and 85, the passage forming member 130 is formed in a bent shape, and by being attached to a predetermined position on the lower rear surface of the front door 12, the return medal passage 132 and the payout medal passage 132. It is a member forming 134.
Furthermore, the return medal passage 132 is a passage for guiding a medal, which is not permitted to be inserted by the blocker 45 of the medal selector, to the medal payout opening 16.
Further, the payout medal passage 134 is a passage for guiding the medals ejected from the ejection unit 103 of the medal payout device 15 to the medal payout opening 16.
The return medal passage 132 and the payout medal passage 134 merge into one passage on the way.

Further, as shown in FIGS. 84 and 85, an upper medal receiving opening 131 is provided above the passage forming member 130. The upper medal receiving opening 131 is an opening for receiving medals which are not permitted to be inserted by the blocker 45, and is an opening at the upstream end of the return medal passage 132, and closes the front door 12. It is formed so as to be located below the blocker 45 of the medal selector in the open state.
Then, the medals which are not allowed to be inserted by the blocker 45 are guided through the return medal passage 132 after passing through the upper medal receiving opening 131, pass through the medal payout opening 16 and are stored in the medal receiving tray.

Further, as shown in FIGS. 84 and 85, a lower medal receiving port 133 is provided at a position below the center of the passage forming member 130 and to the left when viewed from the front (to the right when viewed from the back). ing. The lower medal receiving opening 133 is an opening for receiving the medals ejected from the discharging portion 103 of the medal payout device 15, and is an opening at the upstream end of the payout medal passage 134. It is formed so as to be positioned in front of the discharge portion 103 of the medal payout device 15 with the 12 closed.
Then, the medals ejected from the ejection portion 103 of the medal payout device 15 are guided by the payout medal passage 134 after passing through the lower medal receiving port 133, pass through the medal payout port 16, and are stored in the medal receiving tray. ..

Further, as shown in FIGS. 86 and 87, the lower medal receiving port 133 is formed on the back side of the passage forming member 130, and the front side of the passage forming member 130 constitutes the back side of the front door 12. Plates are arranged. In this way, there is a distance corresponding to the depth of the passage forming member 130 from the lower medal receiving opening 133 to the back surface of the front door 12.
Here, the medal M ejected from the ejection portion 103 of the medal payout device 15 passes through the lower medal receiving opening 133, passes through the payout medal passage 134, and is located at a position facing the lower medal receiving opening 133 on the back surface of the front door 12. It hits and bounces back. At this time, if the distance from the lower medal receiving port 133 to the back surface of the front door 12 is short, the medal M hit against the back surface of the front door 12 and rebounded, and the medal M is ejected from the ejection portion 103 of the medal payout device 15 next to the medal M. There is a possibility of collision with the medal M.

Therefore, in the seventeenth embodiment, as shown in FIG. 87, when the distance from the lower medal receiving opening 133 to the back surface of the front door 12 is "L1" and the diameter of the medal M is "D", "L1" ≧2D” is set.
That is, the distance “L1” from the lower medal receiving opening 133 to the back surface of the front door 12 is set to be twice or more the diameter “D” of the medal M.
As a result, the medal M hit against the back surface of the front door 12 and bounced off, and the medal M ejected from the ejection unit 103 of the medal payout device 15 next to the medal M are less likely to collide with each other.

That is, the medals M ejected from the ejection unit 103 of the medal payout device 15 are directed toward the back surface of the front door 12 (rightward in FIG. 87) while falling downward due to gravity. Therefore, the medal M ejected from the ejection unit 103 of the medal payout device 15 hits the back surface of the front door 12 at a position lower than the ejected position. Further, the medal M that hits the back surface of the front door 12 and bounces back toward the lower medal receiving port 133 (leftward in FIG. 87) while falling downward due to gravity.
Then, if the distance “L1” from the lower medal receiving port 133 to the back surface of the front door 12 is set to be twice or more the diameter “D” of the medal M, it is ejected from the ejection portion 103 of the medal payout device 15. And a medal M heading toward the back surface of the front door 12 and a medal M hitting the back surface of the front door 12 and bouncing back toward the lower medal receiving opening 133 can be sufficiently secured, and both medals M collide with each other. It can be made difficult.

Further, when the medals M are ejected one after another from the ejection portion 103 of the medal payout device 15 at short intervals, even if the distance “L1” from the lower medal receiving port 133 to the back surface of the front door 12 is equal to the diameter “D” of the medal M, Even if the number is set to be twice or more, there is a possibility that the medal M ejected from the ejection unit 103 of the medal payout device 15 and the medal M bounced by hitting the back surface of the front door 12 collide with each other.

Therefore, in the seventeenth embodiment, after the medal M ejected from the ejection unit 103 of the medal payout device 15 hits the back surface of the front door 12 and bounces off, the next medal M is ejected from the ejection unit 103 of the medal payout device 15. It is set.
That is, the interval of ejecting the medal M from the ejection unit 103 of the medal payout device 15, the ejection speed of the medal M from the ejection unit 103 of the medal payout device 15, and the distance from the lower medal receiving port 133 to the back surface of the front door 12. And are set so as to satisfy the above relationship.

In this way, the medal M ejected from the ejection unit 103 of the medal payout device 15 hits the back surface of the front door 12 at a position lower than the ejected position, bounces, and drops to a lower position, and then the next medal M is ejected. If ejected from the ejection unit 103 of 15, it is possible to secure a sufficient distance and height difference between both medals, and it is possible to prevent both medals M from colliding.
Here, when the medal M hit against the back surface of the front door 12 and bounces against the medal M ejected from the ejection portion 103 of the medal payout device 15 next to the medal M, the medal M in the vicinity of the lower medal receiving port 133 or the payout medal is released. There is a possibility that the medal M will be blocked in the passage 134.

Therefore, in the present embodiment, as described above, the medals M are set so as not to easily collide with each other, so that the medals M are not blocked near the lower medal receiving port 133 or in the payout medal passage 134. ..
In the present embodiment, the medal M hit by the back surface of the front door 12 and rebounded is set so that the medal M ejected from the ejection unit 103 of the medal payout device 15 next to the medal M is less likely to collide. However, this does not mean that the front and rear medals M do not collide when a large number of medals M are continuously ejected from the ejection unit 103, and that at least the first medal M and the second medal M are It is enough if there is no collision. Since it is most likely that two coins will be paid out when winning a small winning combination, if it is set so that the first medal M and the second medal M do not easily collide, the vicinity of the lower medal receiving port 133 This is because the medal M can be prevented from being blocked in the payout medal passage 134.

Further, as described in the sixth embodiment, the hopper disc 101 is provided with a plurality of holding portions 102 capable of holding the medals M stored in the hopper along the outer periphery of the hopper disc 101. There is.
When the following conditions (a) and (b) are satisfied or conditions (a) and (c) are satisfied, two or more medals M are continuously output from the ejection unit 103 of the medal payout device 15. It will be ejected.
(A) The medals M are held by the two adjacent holding portions 102 of the hopper disc 101.
(B) “(M−N)≧2” is satisfied when the number of remaining tokens until reaching the upper limit of the number of credits is “N” and the number of paid-out medals M is “M”.
(C) The settlement switch 43 is operated when the number of credits is “2” or more.

For example, in FIG. 17B of the sixth embodiment, the medals M are held by the holding unit 102 at the position of the character “B” and the holding unit 102 at the position of the character “C”, respectively. When it is present, the condition (a) above is satisfied even if the medal M is not held in the holding portion 102 at the position of the character “D”.
Further, for example, in FIG. 17B of the sixth embodiment, although the medal M is not held in the holding unit 102 at the position of the character “B”, the holding unit at the position of the character “C” is held. When the medals M are held in 102 and the holding unit 102 at the position of the character “D”, the condition (a) above is satisfied.

Furthermore, in FIG. 17B of the sixth embodiment, the holding unit 102 at the position of the character “B”, the holding unit 102 at the position of the character “C”, and the position of the character “D”. When the medals M are held in the holding units 102 in the above, the above condition (a) is satisfied.
Of course, when the medals M are held in all the holders 102 of the hopper disc 101, the above condition (a) is satisfied.

Further, for example, when the upper limit of the number of credits is "50" and the number of credits is "47", the remaining number of sheets until reaching the upper limit of the number of credits is "3". When a small winning combination of "5" or more is won, the condition of (b) above is satisfied.
Furthermore, for example, when the credit number has already reached the upper limit value of “50”, the remaining number of sheets until reaching the upper limit value of the credit number is “0”, and at this time, the payout number is “2”. When the above-mentioned small wins are won, the above condition (b) is satisfied.

From the above, for example, in FIG. 17B of the sixth embodiment, at least the holding unit 102 at the position of the character "B" and the holding unit 102 at the position of the character "C" are respectively medals. When the condition (b) or (c) is satisfied while M is held, two or more medals M are continuously ejected from the ejection unit 103 of the medal payout device 15.
Further, for example, in FIG. 17B of the sixth embodiment, the medal M is not held in the holding portion 102 at the position of the character "B", but at least the position of the character "C" is held. Even when the above condition (b) or (c) is satisfied under the condition that the medals M are held in the holding unit 102 and the holding unit 102 at the position of the character “D”, the medal payout is performed. Two or more medals M are continuously ejected from the ejection portion 103 of the device 15.

Further, there is a case where the medal M ejected from the ejection unit 103 of the medal payout device 15 hits the back surface of the front door 12 and bounces back to near the lower medal receiving port 133. When the returned medal M passes through the lower medal receiving port 133, it falls inside the cabinet 13 and cannot be paid out to the player.
Therefore, in the seventeenth embodiment, as shown in FIG. 87, when the height of the peripheral edge of the lower medal receiving opening 133 is “L2” and the thickness of the medal M is “T”, “L2≧T”. Is set to satisfy.

That is, the height “L2” of the peripheral portion of the lower medal receiving opening 133 is set to be equal to or more than the thickness “T” of the medal M.
As a result, even if the medal M ejected from the ejection unit 103 of the medal payout device 15 hits the back surface of the front door 12 and bounces back and returns to the vicinity of the lower medal receiving port 133, the returned medal M is the lower medal receiving port. It is possible to hit the peripheral edge portion of the 133 and not pass through the lower medal receiving opening 133.

Further, since the hopper disk 101 of the medal payout device 15 is arranged so as to be inclined with respect to the horizontal plane, the medal M is ejected from the ejection portion 103 of the medal payout device 15 in a state of being inclined with respect to the horizontal plane. Therefore, as shown in FIGS. 84 and 85, the lower medal receiving port 133 and the payout medal passage 134 are also inclined in accordance with the inclination of the ejected medal M.

Here, the vertical direction with respect to the front surface and the back surface of the medal M ejected in an inclined state is the height direction. Then, in the seventeenth embodiment, as shown in FIG. 87, when the height of the payout medal passage 134 is “L2” and the diameter of the medal M is “D”, “L2<D” is satisfied. It is set. That is, the height “L2” of the payout medal passage 134 is set to be less than the diameter “D” of the medal M.

Accordingly, even if the medal M that hits the back surface of the front door 12 and rebounds rotates in the payout medal passage 134, the front surface and the back surface of the medal M can be prevented from being parallel to the vertical plane in the payout medal passage 134. Therefore, it is possible to prevent the medal M from blocking the payout medal passage 134.
It should be noted that all of the embodiments and various modifications described in the present specification are not limited to be implemented alone, but may be implemented in appropriate combinations.

<Eighteenth embodiment>
The eighteenth embodiment relates to an external signal transmission process.
In the eighteenth embodiment, a signal indicating ON/OFF can be output as the external signal 4 and the external signal 5.
In the eighteenth embodiment, the external signal 4 is an ON signal for the setting key switch (setting key switch signal), a signal indicating that an error has been detected, a signal indicating that an error is being displayed, or the power switch 11 is ON. This is a signal indicating that it has been performed (detection of power-on).
The external signal 5 is a signal indicating that the front door 12 of the slot machine 10 has been opened (door switch ON signal).

FIG. 88 is a diagram showing a main storage area of the RWM 53 described in the eighteenth embodiment.
The input port 0 level data at the address “F00A(H)” is a storage area for storing data indicating ON/OFF of the input port 0. Each bit of input port 0 is configured as follows.
D0: Setting switch signal (“1” when on, “0” when off)
D1: Reset switch signal (“1” when on, “0” when off)
D2: Setting key switch signal (“1” when on, “0” when off)
D3: Door switch signal (“1” when on, “0” when off)
D4: Not used D5: Not used D6: Power failure detection signal D7: Full detection signal

Here, the D6-bit “power-off detection signal” is input when power-off occurs (for example, when “Yes” is determined in step S482 in FIG. 54 (the eleventh embodiment)). It is a signal.
Although not shown in FIG. 1, the slot machine 10 is provided with a sub tank for storing the medals overflowing from the hopper 35. Further, a full sensor is provided which is turned on when the medal contacts when the sub tank is full. Then, when the full sensor is turned on, the full detection signal is input to the D7 bit of the input port 0.
Further, although not shown in FIG. 88, in addition to the storage area of the input port 0 level data, each bit of the input port 0 is turned off (at the time of the previous interrupt processing) to on (at the time of the current interrupt processing). The storage area of the input port rising data for storing the data indicating that, and the data indicating that each bit of the input port 0 is turned on (at the time of the previous interrupt processing) to off (at the time of the current interrupt processing) It is also possible to provide a storage area for the input port falling data for storage.

Further, the input port 51 shown in FIG. 1 is not limited to the input port 0, and for example,
(1) Input port 1 to which operation switch signals such as the bet switch 40 (40a and 40b), the start switch 41, the stop switch 42, and the settlement switch 43 are input,
(2) Input port 2 into which signals from the passage sensor 46, the input sensor 44, the payout sensor 37, the reel sensor 33, etc. are input
And so on.
A storage area for input port level data corresponding to each input port is provided. Further, as described above, it is possible to provide a storage area for the input port rising data and the input port falling data for each input port.
Furthermore, when only the storage area for input port level data is provided (when the storage area for input port rising data and input port falling data is not provided), the storage area for input port level data in this interrupt processing Not only that, a storage area for the input port level data in the previous interrupt processing may be provided.

The power-off recovery time external signal 4 output time of the address “F013(H)” is a storage area of a timer value for counting the time for which the external signal 4 is output at power-off recovery. In the present embodiment, in FIG. 1, when the power switch 11 is turned on and the main control board 50 detects the recovery from the power failure, the address “F013(H)” is set to “136(D)” as an initial value. And is decremented by "1" for each interrupt. Then, it is determined that the external signal 4 is turned on (a signal indicating ON can be output as the external signal 4) until this value becomes “0”.
Further, in the eighteenth embodiment, the interrupt cycle is “2.235 ms”, as in the other embodiments. Therefore, the "136" interrupt corresponds to "303.96 ms". As a result, at the time of recovery from power-off, the external signal 4 is turned on for about “300” ms (a signal indicating the on-state can be output as the external signal 4).

The external signal 4 management time of the address “F014(H)” is a storage area of a timer value for managing the output time of the external signal 4. In this embodiment, the initial value “24 (D)” is set when the output of the external signal 4 is started (except when the power is restored from the above-described power failure), and “1” is subtracted for each interrupt. .. Then, it is determined that the external signal 4 is turned on (a signal indicating ON can be output as the external signal 4) until this value becomes “0”.
The "24" interrupt corresponds to "53.64 ms". As a result, the external signal 4 is turned on for at least “50” ms or more (a signal indicating the on state can be output as the external signal 4).

The external signal 5 management time of the address “F015(H)” is a storage area of a timer value for managing the output time of the external signal 5. In this embodiment, the initial value "24(D)" is set when the output of the external signal 5 is started, and "1" is subtracted for each interrupt. Then, it is determined that the external signal 5 is turned on (a signal indicating ON can be output as the external signal 5) until this value becomes “0”.
Similarly to the above, the "24" interrupt corresponds to "53.64 ms". As a result, the external signal 5 is turned on for at least "50" ms or more (a signal indicating the on state can be output as the external signal 5).

Further, the external signal 4 output time, the external signal 4 management time, and the external signal 5 management time at power recovery from the present embodiment are all 1-byte timers because they measure "255 (D)" or less. Then, these timer values are subtracted by the timer measurement in step S455 during the interrupt processing of FIG.
Here, in the eighteenth embodiment, the above three timers are arranged at the addresses “F013(H)” to “F015(H)”. Therefore, in the timer measurement, "F013(H)" is set as the measurement start timer address in the first step. Also, "3" is set as the number of 1-byte timers. As a result, all the timers including the addresses “F013(H)” to “F015(H)” are decremented by “1” by the timer measurement process.
In addition, when the subtraction process is executed when the timer value is “0”, in other words, when “0” is subtracted from “00 (H)”, “00 (H)” is set. ..

The error number of the address “F051(H)” is a storage area for storing the number corresponding to the detected error when the error is detected. As shown in FIG. 88, when no error is detected, the value of the address “F051(H)” is “0(D)”. Then, for example, when the "E5" error is detected, the value "105(D)" corresponding to the detected error is stored in the address "F051(H)".
In FIG. 88, "E0" to "E7" are illustrated as the error numbers.
Here, in the eleventh embodiment described above, as the non-recoverable error, “E1”, “E5”, “E6”, and “E7” errors are illustrated. On the other hand, the “E0” to “E7” errors of the eighteenth embodiment (FIG. 88) all correspond to recoverable errors.

When these recoverable errors occur, the progress of the game is stopped in principle. Further, even when at least one reel 31 is rotating, error detection is executed for at least some errors (“E7”, “E6”, “E5” errors in the example of the eighteenth embodiment). When an error is detected during the rotation of at least one reel 31, the progress of the game is continued until all reels 31 are stopped, and when all reels 31 are stopped, an error state (before the payout process is executed ( Error display) and stop the progress of the game. Then, when the error is removed by the hall clerk, the progress of the game is restarted. Of course, during the rotation of the reel 31, if any of "E7", "E6", and "E5" errors occur, the progress of the game is stopped (stop control by the operation of the stop switch 42 is not performed. ) Is also possible.

In FIG. 88, the "E0" error is an error when the insertion sensor 44 determines that the medals have accumulated.
The "E1" error is an error when it is determined that the medals have not passed in the order of the insertion sensors 44a and 44b.
The "E2" error is an error when it is determined that the sub tank is full.
The “E3” error is an error when it is determined that the medal in the hopper 35 is empty.
The "E4" error is an error when it is determined by the payout sensor 37 that the medals are accumulated (clogged) under the condition that the medal payout signal is output.
The "E5" error is an error when the payout sensor 37 is turned on under the situation where the medal payout signal is not output.
The "E6" error is an error when the insertion sensor 44b detects a medal under the condition that the blocker 45 does not form the medal flow path.
The "E7" error is an error when it is determined that medals have accumulated in the selector passage.

When any of the above errors is detected, the number corresponding to the detected error is stored in the address “F051(H)”. When the error number is stored in the address “F051(H)”, it becomes possible to display an error corresponding to the stored error number. For example, the segment data corresponding to the number stored in the address “F051(H)” is output to the acquired number display LED 78 to display the error number. Specifically, when the error code “101(D)” is stored in the address “F051(H)”, the digit is displayed in the LED display control in the interrupt process (for example, FIG. 55 of the eleventh embodiment). At the lighting timing of 3, the lighting data of the digit 3 and the segment data for lighting and displaying "E" are output. In addition, at the lighting timing of the digit 4, the lighting data of the digit 4 and the segment data for lighting and displaying "1" are output.

When any error number is stored in the address “F051(H)” (when it is not “0”), the external signal 4 is turned on (a signal indicating ON is output as the external signal 4). ).
After eliminating the error that occurred, the hall clerk turns on the reset switch. When it is detected that the reset switch is turned on, it is determined whether the error that has occurred is removed. When it is determined that the error that has occurred is not removed, the current status (error display) is maintained. On the other hand, when it is determined that the generated error has been removed (no error has occurred), the error number stored in the address “F051(H)” is cleared. When the error number of the address "F051(H)" is cleared, the error display (display of the error number by the digits 3 and 4) ends.
Although the above is an example in which the error number is displayed on the acquired number display LED 78 based on the other embodiment described above, the present invention is not limited to this, and may be displayed on the credit number display LED 76, or the error display may be performed. A dedicated LED may be provided and displayed on the LED.

The error detection flag of the address “F294(H)” is a storage area for storing the fact that an error has been detected in consideration of the case where the error state cannot be immediately set when an error is detected. Is. In the example of FIG. 88, the D0 to D2 bits in the storage area of the address “F294(H)” are used as detection flags for “E7”, “E6”, and “E5” errors, respectively. The “E7”, “E6”, and “E5” errors are all errors that may be detected even when at least one reel 31 is rotating.

Here, for example, even when the reel 31 is rotating, it is determined whether or not an "E5", "E6", or "E7" error has occurred by the interrupt processing. Then, when the occurrence of these errors is detected while the reel 31 is rotating, the bit corresponding to the error of the error detection flag is set to "1". When the error detection flag is "1", the external signal 4 is output.
However, even when these errors are detected under the condition that the reels 31 are rotating, the error state (error display) is not immediately entered at that time, and all the reels 31 are stopped. Shift to the error state before the payout process is executed.

When any of the error detection flags is set to "1" when all reels 31 have stopped, the corresponding error number is stored in the address "F051(H)". When the error number is stored in the address “F051(H)”, the stored error number is displayed. When the error number is stored in the address "F051(H)" after the error detection flag is stored in the address "F294(H)", when should the error detection flag of the address "F291(H)" be cleared? Is optional. For example, firstly, the error detection flag is not cleared until the error is removed. In this case, after the error detection flag is stored and after all reels 31 are stopped, the external signal 4 is turned on based on either the error detection flag or the error number (external signal 4 indicates ON). Signal can be output). When it is determined that the error has been removed, both the error detection flag and the error number are cleared. When the error detection flag and the error number are cleared, the external signal 4 is turned off (a signal indicating off is output as the external signal 4). However, even when both the error detection flag and the error number are cleared, the external signal 4 is not turned off (for example, the external signal 4 is turned off when the setting key switch is turned on). Is not output).

Secondly, if the error number is stored in the address "F051(H)" after storing the error detection flag in the address "F294(H)", the error detection flag of the address "F291(H)" is cleared. There are things to do. In this case, after the error detection flag is stored, the external signal 4 is turned on based on the error detection flag until the error number is stored (a signal indicating ON as the external signal 4 can be output. ). Further, when the error number is stored and the error detection flag is cleared, the external signal 4 is turned on based on the error number (a signal indicating the on state can be output as the external signal 4). After that, when it is determined that the error is removed, the error number is cleared. As a result, the external signal 4 is turned off (a signal indicating off is output as the external signal 4). However, even when both the error detection flag and the error number are cleared, the external signal 4 is not turned off (for example, the external signal 4 is turned off when the setting key switch is turned on). Is not output).

When an error is detected while the reels 31 are rotating, the error state (error display) cannot be immediately entered (the error state cannot be entered unless all reels 31 are stopped), but immediately when an error is detected. Since it is necessary to turn on the external signal 4 (enable to output a signal indicating ON as the external signal 4), an error detection flag is provided.
Therefore, when an "E5", "E6", or "E7" error occurs under a situation where the error state can be immediately entered, such as when the reel 31 is stopped, "1" is stored in the error detection flag. Whether or not to do it is arbitrary. For simplification of processing, even when an "E5", "E6", or "E7" error occurs under the condition that the error state can be entered, "1" is stored in the error detection flag. Good. Alternatively, when an "E5", "E6", or "E7" error occurs, and the error detection flag is "1" when the error state cannot be entered immediately (for example, at least one reel 31 is rotating). When an error state can be immediately entered (for example, during game standby), the error number is stored, but the error detection flag may not be set to “1”.

In the storage area of the RWM 53 described above, the storage areas of the addresses “F00A(H)”, “F013(H)” to “F015(H)”, and “F051(H)” are storage areas in the use area. .. On the other hand, the storage area of the address “F294(H)” is a storage area outside the used area. A program for detecting an error is stored in a control area outside the used area of the ROM 54.

89 and 90 are time charts showing the output timings of the external signal 4 and the external signal 5. FIG. 89 shows Example 1 and FIG. 90 shows Example 2.
In Example 1 of FIG. 89, (a) shows the relationship between ON/OFF of the setting key switch and the output of the external signal 4. When the ON of the setting key switch is detected, the external signal 4 is immediately turned ON (a signal indicating ON is output as the external signal 4). The minimum value of the time t1 from when the setting key switch is detected to be turned on until the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4) is “0” ms. Therefore, when it is detected that the setting key switch is turned on, the external signal 4 is turned on immediately (a signal indicating the on state can be output as the external signal 4).
Further, whether or not the setting key switch is ON is detected in the interrupt processing. For example, when the level data of the input port 0 is read and the level data of the setting key switch is “1” in the input port read process of step S457 during the interrupt process shown in FIG. 53 (the eleventh embodiment), The signal 4 is turned on (a signal indicating ON is output as the external signal 4).

When the setting key switch is turned on once, the external signal 4 is turned on for "50" ms or more (a signal indicating the on state can be output as the external signal 4) (t3 in the figure). Therefore, even if the setting key switch is turned off immediately after it is turned on (for example, after “10” ms has elapsed), the external signal 4 is turned on (external signal) until at least “50” ms has elapsed. A signal indicating ON is output as the signal 4).
Then, when the setting key switch is turned off, “50” ms or more has elapsed from the time when the external signal 4 was turned on (a signal indicating ON as the external signal 4 can be output). The external signal 4 is turned off (a signal indicating off is output as the external signal 4). If "50" ms or more has elapsed since the external signal 4 was turned on (a signal indicating that the external signal 4 is on can be output), the external signal 4 is turned off when the setting key switch is detected to be off. (It is possible to output a signal indicating OFF as the external signal 4) (t2 in the figure).

Therefore, after detecting the ON of the setting key switch and turning ON the external signal 4 (making it possible to output a signal indicating ON as the external signal 4), turn OFF the setting key switch before “50” ms has elapsed. When it is detected, the external signal 4 is turned off after a minimum of “50” ms has elapsed as the output time of the external signal 4 (a signal indicating that the external signal 4 is off can be output).
On the other hand, after detecting the ON of the setting key switch and turning ON the external signal 4 (making it possible to output a signal indicating ON as the external signal 4), the setting key switch is turned OFF after "50" ms or more has elapsed. When detected, the external signal 4 can be turned off immediately (a signal indicating off can be output as the external signal 4).

(B) shows the relationship between the detection/non-detection of an error and the output of the external signal 4. Here, "error detection" corresponds to any one of the bits being "1" in the error detection flag of the address "F294(H)", and "error non-detection" means the error. This corresponds to the detection flag being "0".
When “1” is stored in the error detection flag, the external signal 4 can be turned on immediately (a signal indicating ON can be output as the external signal 4). After "1" is stored in the error detection flag, the minimum value of the time t1 until the external signal 4 is turned on (a signal indicating ON as the external signal 4 can be output) is "0" ms.
When "1" is once stored in the error detection flag, the external signal is turned on for at least "50" ms (a signal indicating that the signal is on can be output as the external signal 4) (time t3). When the error detection flag is cleared, the external signal 4 can be turned off (a signal indicating off can be output as the external signal 4) (time t2). As described above, the error detection flag is cleared when the error is removed or when the error is not removed but the error number is stored.

Therefore, after detecting that the error detection flag has become "1" and turning on the external signal 4 (making it possible to output a signal indicating ON as the external signal 4), before "50" ms has elapsed. When it is detected that the error detection flag has become “0”, the external signal 4 is turned off after at least “50” ms has elapsed as the output time of the external signal 4 (a signal indicating that the external signal 4 is off). Can be output).
On the other hand, after detecting that the error detection flag has become “1” and turning on the external signal 4 (making it possible to output a signal indicating ON as the external signal 4), after “50” ms or more has elapsed, When it is detected that the error detection flag becomes "0", the external signal 4 can be immediately turned off (a signal indicating off can be output as the external signal 4).

(C) shows the relationship between the display/non-display of an error and the output of the external signal 4. The “error display” here means that the error number of the address “F051(H)” is a value other than “0” (in the example of FIG. 88, any of “100(D)” to “107(D)”. Or) is stored, and “non-display of error” corresponds to the value of the error number being “0”. Although a storage area for storing a flag indicating the display/non-display of an error may be provided, like the present embodiment, it is based on the data stored in the storage area for displaying the error number. By determining whether to display or not display the error, it is possible to reduce the storage area used.

When a value other than "0" is stored in the error number, it is possible to immediately turn on the external signal 4 (a signal indicating ON can be output as the external signal 4). The minimum value of the time t1 until the external signal 4 is output after the value other than the error number "0" is stored is "0" ms.
Further, when a value other than “0” is temporarily stored in the error number, the external signal 4 is turned on for at least “50” ms (a signal indicating ON is output as the external signal 4) (time is output). t3). Also, after the value other than "0" is stored in the error number, the external signal 4 is turned on for at least "50" ms or more (the signal indicating that the signal is turned on can be output as the external signal 4), and then the error number When is cleared, the external signal 4 can be immediately turned off (a signal indicating off can be output as the external signal 4) (time t2).

Therefore, when the error number is stored and after the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4) and the error number is cleared before “50” ms has elapsed, After at least "50" ms has passed as the output time of the external signal 4, the external signal 4 is turned off (a signal indicating the off state can be output as the external signal 4).
On the other hand, when the error number is stored and the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4), and the error number is cleared after “50” ms or more has elapsed, It is possible to immediately turn off the external signal 4 (a signal indicating off can be output as the external signal 4).

(D) shows the relationship between the power on/off and the output of the external signal 4. Here, there are various detection methods for determining whether or not the power is turned on (whether or not the power switch 11 is turned on in FIG. 1). In this example, “power on” means the address “F013”. (H)” corresponds to the time when the initial value “136 (D)” of the output time of the external signal 4 upon recovery from power failure is stored.
When the power-on is detected (when the initial value is stored in the output time of the external signal 4 when the power is restored), it is possible to immediately turn on the external signal 4 (indicating that the external signal 4 is on). It is possible to output a signal). The minimum value of the time t1 until the external signal 4 is output after the initial value is stored in the external signal 4 output time when the power is restored is "0" ms.
When the initial value is stored in the output time of the external signal 4 when the power is restored, the external signal 4 is turned on for "300" ms (a signal indicating the on state can be output as the external signal 4) ( Time t3). The “300” ms here corresponds to the number of interruptions “136”. Further, when the output time of the external signal 4 at power-off recovery is “0”, the external signal 4 can be immediately turned off (a signal indicating off can be output as the external signal 4). (Time t2).

Therefore, the initial value is stored in the output time of the external signal 4 when the power is restored, and after the external signal 4 is turned on (a signal indicating the on state can be output as the external signal 4), the power switch 11 is turned off. When it is detected (when the D7 bit of the input port 0 level data becomes “1”), the external signal 4 is turned off after “300” ms has elapsed as the output time of the external signal 4 (external A signal indicating OFF can be output as the signal 4).
On the other hand, the initial value is stored in the output time of the external signal 4 when the power is restored, and after the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4), the output time of the external signal 4 is “ After 300 ms, the external signal 4 is turned off (a signal indicating off is output as the external signal 4) even if the power switch 11 remains on.

(E) shows the relationship between the opening/closing of the front door 12 and the output of the external signal 5. Here, "the front door 12 is opened" corresponds to when the ON state of the door switch is detected. Particularly, the eighteenth embodiment corresponds to the case where the D3 bit of the input port 0 level data (or the input port 0 rising data) becomes "1".
When it is detected that the door switch is turned on, the external signal 5 can be turned on immediately (a signal indicating the on state can be output as the external signal 5). The minimum value of the time t1 until the external signal 5 is output after the ON state of the door switch is detected is "0" ms.
When the ON state of the door switch is detected, the external signal 5 is turned ON for at least "50" ms (a signal indicating ON is output as the external signal 5) (time t3). Thereby, even if the front door 12 is closed immediately after the front door 12 is opened, the external signal 5 is turned on for at least “50” ms (external signal 5 indicates ON). Signal can be output).

Therefore, after the ON state of the door switch is detected and the external signal 5 is turned ON (a signal indicating ON is output as the external signal 5), the OFF state of the door switch is detected before "50" ms has elapsed. At this time, after at least "50" ms has elapsed as the output time of the external signal 5, the external signal 5 is turned off (a signal indicating that the external signal 5 is off can be output).
On the other hand, after detecting the ON state of the door switch and turning ON the external signal 5 (making it possible to output a signal indicating ON as the external signal 5), the OFF state of the door switch is detected after "50" ms or more has elapsed. At this time, the external signal 5 can be immediately turned off (a signal indicating off can be output as the external signal 5).

The output destination of the external signal 4 or the external signal 5 is a hall computer or the like, but the external signal 4 or 5 is turned on for "50" ms or more (a signal indicating the on state as the external signal 4 or 5 can be output. By this, the hall computer (data lamp) or the like can surely receive the external signals 4 and 5. Therefore, even if an illegal act such as turning on the setting key switch for a moment (for example, about “5” to “10” ms) is performed or an illegal act including opening the front door 12 for a moment is performed, the hall is The external signal 4 or 5 can be received by a computer or the like.

Example 2 shown in FIG. 90 is a modification of Example 1 shown in FIG. 89.
In FIG. 90,
Time t1 from when the setting key switch shown in (a) is detected to be turned on until the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4),
Time t1 from when the error detection flag shown in (b) becomes "1" to when the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4),
Time t1 from when the error number shown in (c) is stored until when the external signal 4 is turned on (a signal indicating that the signal is on can be output as the external signal 4),
Time t1 from when the door switch shown in (e) is detected to be turned on until the external signal 5 is turned on (a signal indicating that the external signal 5 is turned on can be output).
Are both set to "0" ms.

Note that, in FIG. 90, the interval of the time t1 is illustrated as exceeding “0”, but in reality, for example, in (a), the timing at which the setting key switch is turned from OFF to ON and the external signal 4 The output turns from OFF to ON at almost the same timing (the setting key switch turns OFF to ON, and the output of the external signal 4 turns from OFF to ON within “2”). ..
Further, the time t3 for turning on the external signal 4 in (a) to (c) in the figure and the external signal 5 shown in (e) in the figure (making it possible to output signals indicating ON as the external signals 4 and 5). Is a minimum of 50 ms. This point is similar to the example of FIG. 89.
Furthermore, the time t3 for turning on the external signal 4 in FIG. 9D (making it possible to output a signal indicating ON as the external signal 4) is “300” ms, as in the example of FIG. 89.

Furthermore,
Time t2 from when the setting key switch shown in (a) is detected to be OFF until the external signal 4 is turned OFF (a signal indicating OFF is output as the external signal 4).
Time t2 from when the error detection flag shown in (b) is cleared to when the external signal 4 is turned off (a signal indicating that the signal is off can be output as the external signal 4),
Time t2 from when the error number shown in (c) is cleared to when the external signal 4 is turned off (a signal indicating off as the external signal 4 can be output),
Time t2 from when the output time of the external signal 4 at the time of power failure recovery shown in (d) becomes “0” to when the external signal 4 is turned off (a signal indicating the off state can be output as the external signal 4),
Time t2 from when the door switch shown in (e) is detected to be turned off until the external signal 5 is turned off (a signal indicating off is output as the external signal 5).
Is “50” ms in all cases.

To do so, for example, a timer for managing the output time of the external signal 4 when the setting key switch is detected to be off, the error detection flag is cleared, or the error number is cleared. The value "24 (D)" is set, the timer value is subtracted by "1" for each interrupt processing, and when the timer value becomes "0", the external signal 4 is turned off (the external signal 4 is turned off. It is possible to output a signal indicating).
Similarly, when it is detected that the door switch is off, a timer value “24 (D)” for managing the output time of the external signal 5 is set, and the timer value is subtracted by “1” for each interrupt processing. When the timer value becomes "0", the external signal 5 may be turned off (a signal indicating off may be output as the external signal 5).

Next, the output of the external signal 4 and the external signal 5 will be described based on a flowchart. 91 to 94 are flowcharts showing the external signal output processing.
91 and 92 are flowcharts showing Example 1 of the external signal output processing. Further, FIG. 92 is a flowchart following FIG. 91. Furthermore, FIG. 93 is a flowchart showing Example 2 of the external signal output processing. Further, FIG. 94 is a flowchart showing Example 3 of the external signal output processing.
The external signal output process (step S3221) is, for example, a process which is entered between step S455 (timer measurement) and step S456 (LED display control) in FIG.

First, Example 1 of the external signal output processing will be described.
In FIG. 91, in step S3231, it is determined whether the setting key switch is on. This processing determines whether or not the D2 bit of the input port 0 level data is "1", and when it is "1", it is determined that the setting key switch is on. When it is determined that the setting key switch is on, the process proceeds to step S3237, and when it is determined that the setting key switch is not on, the process proceeds to step S3232.

In step S3232, it is determined whether an error has been detected. This process determines whether or not any bit of the error detection flag is "1". When it is determined that any bit of the error detection flag is "1", the process proceeds to step S3237, and when it is determined that neither bit is "1" (no error is detected), the process proceeds to step S3233.
In step S3233, it is determined whether an error is being displayed. In this processing, the error number is read and it is determined whether or not it is "0". When the value is "0", it is determined that the error is not being displayed and the processing proceeds to step S3234. When the value is other than "0", it is determined that the error is being displayed and the processing proceeds to step S3237.

In step S3234, it is determined whether "300" ms has elapsed since the power was turned on. As described above, when the recovery from the power failure is detected, the initial value “136(D)” is set in the output time of the external signal 4 at the time of the power failure recovery of the address “F013(H)”, and the interrupt processing is performed for each interrupt processing. It is subtracted by "1". Then, in step S3234, it is determined whether or not the output time of the external signal 4 upon power-off recovery is “0”, and when it is “0”, “300” ms has elapsed since the power was turned on. And proceeds to step S3235. On the other hand, if the output time of the external signal 4 upon recovery from power failure is not "0", the flow advances to step S3241.

In step S3235, it is determined whether the output time of the external signal 4 has exceeded a predetermined time. Here, the external signal 4 management time of the address "F014 (H)" is set to "24 (D)" in step S3240 described later. Then, in step S3235, it is determined whether or not this external signal 4 management time is "0", and when it is determined that it is "0" (when it is determined that the output time of external signal 4 has elapsed). If it is determined that the value is not “0”, the process advances to step S3241.
In step S3236, external signal 4 is turned off (a signal indicating off is output as external signal 4). Then, the processing proceeds to step S3242 (in FIG. 92).

On the other hand, if “Yes” is determined in step S3231, S3232, or S3233 and the process proceeds to step S3237, it is determined whether or not the setting key switch is turned from off to on in this interrupt process. Whether or not the D2 bit (setting key switch signal) of the input port 0 level data is turned on in the interrupt process this time is, for example, firstly, when the input port 0 rising data is included, the input port 0 rising data is set. It is determined whether the D2 bit of "1" is "1". Secondly, the input port 0 level data at the time of the previous interrupt processing is saved, the D2 bit of the input port 0 level data at the previous interrupt processing is "0", and the input port 0 level data at the current interrupt processing is stored. If the D2 bit of "1" is "1", it is determined that the setting key switch is turned from off to on in this interrupt process. If it is determined that the setting key switch has been turned from off to on, the process proceeds to step S3240, and if it is determined that the setting key switch has not been turned from off to on, the process proceeds to step S3238.

In step S3238, it is determined whether the error detection flag has changed from off to on. Here, for example, the error detection flag in the previous interrupt processing is saved, and the error detection flag in the current interrupt processing is compared with the error detection flag in the current interrupt processing to turn the error detection flag from off to on. Determine whether or not. Then, when it is determined that the error detection flag is changed from off to on, the process proceeds to step S3240, and when it is determined that the error detection flag is not changed from off to on, the process proceeds to step S3239.

In step S3239, it is determined whether the error number is changed from non-display ("0") to display (other than "0"). Here, for example, the error number in the previous interrupt processing is saved, and the error number in the current interrupt processing is compared with the error number other than "0" to "0". It is determined whether or not If it is determined that the error number has changed from "0" to other than "0", the process proceeds to step S3240, and if it is determined that the error number remains "0", the process proceeds to step S3241.

When the processing proceeds from step S3237, S3238, or S3239 to step S3240, the external signal 4 management time of the address "F014(H)" is set to "24(D)" corresponding to the output time "50" ms as an initial value. .. Then, the process proceeds to step S3241.
In step S3241, the external signal 4 is turned on (a signal indicating ON is output as the external signal 4). Then, the processing proceeds to step S3242 (in FIG. 92).
In step S3242, it is determined whether the door switch is on. This process determines whether or not the D3 bit of the input port 0 level data is "1", and when it is "1" it is determined that the door switch is on. When it is determined that the door switch is on, the process proceeds to step S3245, and when it is determined that the door switch is not on, the process proceeds to step S3243.

In step S3243, it is determined whether the output time of the external signal 5 has elapsed. Here, the external signal 5 management time of the address "F015(H)" is set to "24(D)" in step S3246 described later. Then, in step S3243, it is determined whether or not the external signal 5 management time is "0". If it is determined to be "0", the process proceeds to step S3244. Proceeds to S3247.
In step S3244, the external signal 5 is turned off (a signal indicating off is output as the external signal 5). Then, the processing according to this flowchart is ended.

On the other hand, when it is determined in step S3242 that the door switch is on, and the process proceeds to step S3245, it is determined whether or not the door switch is turned on in this interrupt processing. Whether or not the D3 bit (door switch signal) of the input port 0 level data is turned on in this interrupt processing is, for example, firstly, when the input port 0 rising data is included, the input port 0 rising data It is determined whether the D3 bit is "1". Secondly, the input port 0 level data at the time of the previous interrupt processing is saved, and the D3 bit of the input port 0 level data at the previous interrupt processing is “0”, and the input port 0 level data at the current interrupt processing. When the D3 bit of is "1", it is determined that the door switch has been turned on from off in this interrupt processing. If it is determined that the door switch is turned on from off, the process proceeds to step S3246, and if it is determined that the door switch is not turned on, the process proceeds to step S3247.

In step S3246, the external signal 5 management time of the address "F015(H)" is set to "24(D)" corresponding to the output time "50" ms as an initial value. Then, the process proceeds to step S3247.
In step S3247, the external signal 5 is turned off (a signal indicating off is output as the external signal 5). Then, the processing according to this flowchart is ended.

FIG. 93 is a flowchart showing the second example of the external signal output processing.
In the example of FIG. 92,
(1) As shown in step S3237, when the setting key switch is turned from off to on,
(2) As shown in step S3238, when the error detection flag changes from off to on,
(3) As shown in step S3239, the output time of the external signal 4 is set when the error number is newly stored.
On the other hand, in the example of FIG. 93, based on whether or not the setting key switch is on, whether or not the error detection flag is on, and whether or not the error number is stored in this interrupt processing. Then, the output of the external signal 4 is controlled.

In FIG. 93, the same steps as those in FIGS. 91 and 92 are designated by the same step numbers. In the example of FIG. 93, steps different from those in FIGS. 91 and 92 are not provided.
In the example of FIG. 93,
(1) When it is determined in step S3231 that the setting key switch is on (when the D2 bit of the input port 0 level data of the address “F00A(H)” is “1”),
(2) In step S3234, when "300" ms has not elapsed since the power was turned on (when the output time of the external signal 4 at the time of power off recovery of address "F013(H)" is not "0"),
(3) When it is determined in step S3233 that an error is being displayed (when the error number stored in the address “F051(H)” is other than “0”),
(4) In step S3232, when an error is being detected (when any bit of the error detection flag of the address “F294(H)” is “1”)
Respectively proceeds to step S3240 and stores the number of interruptions “24 (D)” corresponding to the output time “50” ms of the external signal 4 in the address “F014 (H)”.

Therefore, in the previous interruption process, for example, it is determined in step S3231 that the setting key switch is on, and in step S3240, the external signal 4 management time of the address "F014(H)" is set to "24(D)". After that, if it is determined in step S3231 that the setting key switch is turned on also in the interrupt process this time, the process proceeds to step S3240, and the external signal 4 management time "24(D)" is reset. When it is determined in step S3234 that "300" ms has not elapsed since the power was turned on, when it is determined in step S3233 that an error is being displayed, and when it is determined in step S3233 that an error is being detected. The same is true. Then, after step S3240, the process proceeds to step S3241.

If it is determined in step S3232 that no error is being detected, the process advances to step S3235. In step S3235, it is determined whether the output time “50” ms of the external signal 4 has elapsed. Here, as described above, when the external signal 4 management time of the address "F014(H)" is "0", it is determined that the output time "50" ms of the external signal 4 has elapsed. If the output time of the external signal 4 has elapsed, the process proceeds to step S3236, the external signal 4 is turned off (a signal indicating off as the external signal 4 can be output), and the output time of the external signal 4 has elapsed. If not, the process proceeds to step S3241 to turn on the external signal 4 (a signal indicating ON is output as the external signal 4).

Next, proceeding to step S3242, it is determined whether the door switch is on. When it is determined that the door switch is on, the process proceeds to step S3246, and when it is determined that the door switch is not on, the process proceeds to step S3243.
In step S3246, "24 (D)" is set to the external signal 5 management time of the address "F015 (H)". Also in this case, similarly to the above, it is determined that the door switch is turned on in the previous interruption processing, "24 (D)" is set as the external signal 5 management time in step S3246, and then the step is also executed in this interruption processing. If it is determined in S3242 that the door switch is on, then in step S3246 the external signal 5 management time "24 (D)" is reset. Then, the process proceeds to step S3247.

In step S3243, it is determined whether the output time “50” ms of the external signal 5 has elapsed. Here, as described above, when the external signal 5 management time of the address “F015(H)” is “0”, it is determined that the output time “50” ms of the external signal 5 has elapsed. When it is determined that the output time of the external signal 5 has elapsed, the process proceeds to step S3244, the external signal 5 is turned off (a signal indicating that the signal is off can be output as the external signal 5), and the output time of the external signal 5 is increased. If it is determined that the time has not elapsed, the process advances to step S3247 to turn on the external signal 5 (a signal indicating the on state can be output as the external signal 5). Then, the processing according to this flowchart is ended.

As described above, in Example 1 of FIG. 91, whether the setting key switch is turned on from off, whether the error detection flag is turned on from off, and the error number is other than “0” to “0”. In each determination of whether or not the external signal 4 management time is set by the interrupt processing determined to be “Yes”, after that, the external signal 4 management time is subtracted by “1” for each interrupt processing to obtain “0”. , The external signal 4 is turned off (a signal indicating off is output as the external signal 4).
On the other hand, in the example 2 of FIG. 93, when the setting key switch is turned on, when the error detection flag is “1”, and when an error number other than “0” is stored, the external signal 4 Is kept ON (a signal indicating ON is output as the external signal 4). When the setting key switch is off, the error detection flag is "0", and "0" is stored as the error number, when the external signal 4 management time becomes "0", The signal 4 is turned off (a signal indicating off is output as the external signal 4).

In other words, the setting key switch is off, the error detection flag is "0", and the external signal 4 is turned on until "50" ms has elapsed since "0" was stored as the error number. (A signal indicating ON is output as the external signal 4). Therefore, for example, only when the error is detected or only when the setting key switch is turned on for a moment (for example, only the “3” interrupt), the external signal 4 is turned off (a signal indicating that the external signal 4 is turned off is turned off). Even when the condition (enabling output) is satisfied, the external signal 4 can be turned on (a signal indicating ON can be output as the external signal 4) for at least “50” ms.

Further, in the external signal output processing (interrupt processing) shown in FIG. 93, when the next interrupt processing is executed after the timer value “24(D)” related to the external signal 4 is set in step S3240, The timer value is subtracted from "24(D)" to "23(D)". Then, in the external signal output process of the next interrupt process, when the condition for turning on the external signal 4 (enabling a signal indicating ON as the external signal 4 to be output) is satisfied, the process proceeds to step S3240, and again. The timer value "24(D)" is set.

Even after that, the timer value is subtracted for each interrupt process, but if the condition for turning on the external signal 4 (enabling a signal indicating ON as the external signal 4 to be output) is not satisfied, the process of step S3240 is performed. Since it does not go through, the timer value finally becomes "0 (D)". When the timer value becomes “0 (D)”, it is determined as “Yes” in step S3235, and thus the process proceeds to step S3236 to turn off the external signal 4 (output a signal indicating off as the external signal 4). Possible).

By doing so, the external signal 4 is turned on (when the external signal 4 is turned on) from the time when the condition for turning on the external signal 4 (enabling the signal indicating the on as the external signal 4 to be output) is satisfied. It is possible to output the signal shown). Then, while the condition for turning on the external signal 4 (enabling a signal indicating ON as the external signal 4 to be output) is satisfied, turning on the external signal 4 (outputting a signal indicating ON as the external signal 4) Possible). Next, when the condition for turning on the external signal 4 (making it possible to output a signal indicating ON as the external signal 4) is not satisfied, the timer value is set to "0 (D)" for each interrupt processing. "1(D)" is subtracted by one. Until the timer value becomes “0(D)”, the external signal 4 is turned on (a signal indicating the on state can be output as the external signal 4). Then, when the timer value becomes “0 (D)”, the external signal 4 is turned off (a signal indicating off is output as the external signal 4).

The above also applies to the external signal 5.
In the external signal output processing (interrupt processing) shown in FIG. 93, when the timer value “24 (D)” related to the external signal 5 is set in step S3246 and the next interrupt processing is executed, the timer value is changed. "24(D)" is subtracted from "23(D)". After that, in the external signal output process of the next interrupt process, when the door switch is on (when the condition for turning on the external signal 5 (enabling a signal indicating ON as the external signal 5 can be output) is satisfied) The process proceeds to step S3246, and the timer value "24(D)" is set again.

Even after that, the timer value is subtracted for each interrupt processing, but the condition that the door switch is turned off (the external signal 5 is turned on (the signal indicating that the external signal 5 is turned on can be output) is no longer satisfied. In this case, since the processing of step S3246 is not performed, the timer value finally becomes “0(D)”. When the timer value becomes “0 (D)”, it is determined as “Yes” in step S3243, and thus the process proceeds to step S3244 to turn off the external signal 5 (output a signal indicating off as the external signal 5). Possible).

By doing so, the external signal 5 is turned on after the door switch is turned on (the condition that the external signal 5 is turned on (a signal indicating that the external signal 5 is turned on can be output) is satisfied). (A signal indicating ON is output as the external signal 5). Then, while the condition for turning on the external signal 5 (enabling a signal indicating ON as the external signal 5 to be output) is satisfied, turning on the external signal 5 (outputting a signal indicating ON as the external signal 5) Possible). Next, when the condition for turning on the external signal 5 (making it possible to output a signal indicating ON as the external signal 5) is no longer satisfied, the timer value is set to "0 (D)" for each interrupt processing. It is subtracted by "1". Until the timer value becomes “0(D)”, the external signal 5 is turned on (a signal indicating the on state can be output as the external signal 5). Then, when the timer value becomes "0 (D)", the external signal 5 is turned off (a signal indicating off is output as the external signal 5).
In Example 2 of FIG. 93 described above, since it is not necessary to generate the rising data and to check the level data and the like at the time of the previous interrupt processing, the hall computer is external while simplifying the external signal output processing. It is possible to secure the time when the signal indicating that the signal 4 or 5 is on can be received.

FIG. 94 is a flowchart showing Example 3 of the external signal output processing. In FIG. 94, steps performing the same processes as in FIG. 93 are given the same numbers, and steps performing different processes are underlined in the step numbers.
In Example 3 of FIG. 94, when determining whether or not to output the external signal 4, first, in step S3251, whether or not the external signal 4 management time of the address “F014(H)” is “0” is determined. To judge. If it is not "0", the flow advances to step S3241 to turn on the external signal 4 (a signal indicating the on state can be output as the external signal 4). On the other hand, when the external signal 4 management time is “0”, when the output conditions of the external signal 4 are satisfied in the determinations of steps S3231, S3234, S3233, and S3232, the process proceeds to step S3240, and the address “F014(H )” of the external signal 4 is set to "24(D)" corresponding to the output time "50" ms, and the process proceeds to step S3241. On the other hand, if none of the determinations in steps S3231, S3234, S3233, and S3232 satisfy the output condition of the external signal 4, the process proceeds to step S3236 to turn off the external signal 4 (as the external signal 4). A signal indicating off can be output).

As for the external signal 5, similarly to the above, when determining whether or not to output the external signal 5, first, in step S3252, the external signal 5 management time of the address “F015(H)” is “0”. Determine if there is. If it is not "0", the flow advances to step S3247 to turn on the external signal 5 (it is possible to output a signal indicating ON as the external signal 5). On the other hand, when the external signal 5 management time is “0”, when it is determined in step S3242 that the door switch is on, the process proceeds to step S3246, and the external signal 5 management time of the address “F015(H)” Is set to "24(D)" corresponding to the output time "50" ms, and the process proceeds to step S3247. On the other hand, when it is determined in step S3242 that the door switch is not on, the flow advances to step S3244 to turn off the external signal 5 (a signal indicating off is output as the external signal 5).

As described above, in Example 3 of FIG. 94, when the set timer value (external signal 4 management time or external signal 5 management time) is “0”, the timer is output when the output condition of the external signal 4 or 5 is satisfied. Set the value. Even if the set timer value becomes "0", if the output condition of the external signal 4 or 5 is satisfied, the timer value is set again.
Even in the method of Example 3 of FIG. 94, as in Example 2 of FIG. 93, it is not necessary to generate rising data, and it is not necessary to check the level data and the like at the time of the previous interrupt processing. While simplifying, it is possible to secure the time when the hall computer can receive the signal indicating that the external signal 4 or 5 is turned on.

Although the eighteenth embodiment has been described above, the eighteenth embodiment is not limited to the contents described above, and various modifications such as the following are possible.
(1) When the setting key switch is turned on, when an error is detected, or when any of the displayed errors is satisfied, the external signal 4 is turned on (a signal indicating the on state can be output as the external signal 4). However, the present invention is not limited to this, and each individual external signal (for example, the external signals 4, 6, 7) is turned on (a signal indicating ON as the external signals 4, 6, 7 can be output). May be. Further, when either one or both of the setting key switch is ON and the door switch is ON, a specific external signal (for example, the external signal 5 or 6) may be turned on ( A signal indicating ON may be output as the external signal 5 or 6.

(2) The various timer values of the addresses “F013(H)” to “F015(H)” are subtracted by “1” for each interrupt processing, but the present invention is not limited to this, and “N (N≧2)”. "N" may be subtracted every "" interrupts, or "1" may be subtracted every "N" interrupts. For example, “12(D)” may be set as the external signal 4 management time or the external signal 5 management time, and then “1” may be subtracted every two interrupts.
(3) The various modifications and numerical values described in the eighteenth embodiment are examples, and can be appropriately designed. For example, in FIG. 89, the times t1 and t2 are the minimum "0" ms, so various settings such as "5" ms and "10" ms can be made.

Further, in FIG. 89, the time t3 ((a), (b), (c), and (e) in the figure) is the minimum “50” ms, and therefore, for example, “75” ms or “100” ms. Etc., various settings can be made.
Particularly, at time t3 in FIGS. 89 and 90 ((a), (b), (c), and (e) in FIGS. 89 and 90), the hall computer or the like reliably receives the external signals 4 and 5. As long as it is possible, it may be less than “50” ms depending on the performance of the hall computer or the like.
Furthermore, the time t2 in FIG. 90 is not limited to “50” ms, and can be set variously according to the specifications and the like.

(4) When the setting key switch is turned from off to on or when the setting key switch is on, the external signal 4 is turned on (the signal indicating the on state can be output as the external signal 4) The external signal 4 may be turned on when the change mode or the setting confirmation mode is entered (a signal indicating the on state can be output as the external signal 4).
Here, as in the eighteenth embodiment, when the setting key switch is turned from off to on, or when the setting key switch is on, the external signal 4 is turned on (a signal indicating on as the external signal 4 is turned on). When the setting key switch is turned from OFF to ON while the reel 31 is rotating, the external signal 4 is turned ON (a signal indicating ON is output as the external signal 4). Possible).
On the other hand, when the setting is changed to the setting change mode or the setting confirmation mode is set, the external signal 4 is turned on (a signal indicating that the external signal 4 is turned on can be output). Even when the setting key switch is turned from ON to OFF while 31 is rotating, the external signal 4 is turned OFF based on the state of the setting key switch (a signal indicating OFF can be output as the external signal 4). To). However, there may be a case where the external signal 4 is turned on based on an error (a signal indicating ON is output as the external signal 4).

(5) In the eighteenth embodiment, when the setting key switch is on, when an error is detected, when an error is being displayed, or when “300” ms has not elapsed since the power was turned on, 1 When the two conditions are satisfied, the external signal 4 is turned on (a signal indicating ON is output as the external signal 4). However, it is not necessary to provide all of these conditions, and the external signal 4 is turned on only when one or a part of the conditions, for example, the setting key switch is turned on (a signal indicating the on can be output as the external signal 4). It may be configured. In other words, the configuration is such that the external signal 4 is not turned on (a signal indicating ON is not output as the external signal 4) even under other conditions, for example, when "300" ms has not elapsed since the power was turned on. May be
(6) All of the embodiments and various modifications described in this specification including the eighteenth embodiment are not limited to be implemented alone, but may be implemented in appropriate combinations.

<19th Embodiment>
The nineteenth embodiment relates to a setting change end sound.
Hereinafter, regarding the setting change end sound, a case where the gaming machine is a slot machine (19th embodiment (A)) and a case where the gaming machine is a pachinko game machine (19th embodiment (B)) are described respectively. To do.
In the following description, “setting change state (also referred to as “setting change mode” or “setting change processing”)” is a state in which the set value can be changed, and the game is started (progressed). ) It is a game state that cannot be played. In the setting change state, it is possible to end without changing the setting value.
The “setting confirmation state (also referred to as “setting confirmation mode” or “setting confirmation processing”)” is a state in which the current setting value can be confirmed although the setting value cannot be changed. In the setting confirmation state, the game cannot be started (progressed) like the setting change state.
On the other hand, the "normal state (also referred to as "normal mode")" refers to a state other than the setting change state and the setting confirmation state. In the normal state, the game can be started (progressed) except for special circumstances such as an error.

<19th Embodiment (A): When the gaming machine is a slot machine>
FIG. 95 is a block diagram showing an outline of control of the slot machine 10 in the nineteenth embodiment (A), and is a diagram corresponding to FIG. 1 of the first embodiment.
In FIG. 95, a door switch 17, a setting key insertion port 151, a setting key switch 152, and a setting change (reset) switch 153 are provided as components not shown in FIG. Although the above configuration is not shown in FIG. 1, it does not mean that the above configuration is not provided in the first embodiment.
The setting key insertion port 151, the setting key switch 152, and the setting change (reset) switch 153 do not necessarily have to be provided on the main control board 50 and may be provided as separate devices.

The door switch 17 is attached to either the cabinet 13 or the front door 12 in FIG.
Then, as shown in FIG. 22, the cabinet 13 and the front door 12 are normally closed, but the front door 12 is opened when the setting is changed or the setting is confirmed. The door switch 17 is a switch that is turned on when the front door 12 is opened and detects the opening of the front door 12. When the opening of the front door 12 is detected by the door switch 17, a door open error is notified.
The setting key insertion port 151, the setting key switch 152, and the setting change (reset) switch 153 are mounted on the main control board 50.
The setting key switch 152 is a switch that is turned on by inserting the setting key from the setting key insertion opening 151 and rotating the setting key 90 degrees clockwise. This is the switch used.

Furthermore, the setting change (reset) switch 153 is a switch that also serves as a setting change switch and a reset switch. The setting change switch is a switch operated when changing the set value in the setting change state. In addition, the reset switch is a switch operated when recovering the state before the error occurs after removing the error that has occurred.
In the following description, there are cases where it is referred to as “setting change (reset) switch 153”, where it is referred to as “setting change switch 153”, and where it is referred to as “reset switch 153”.
Although the setting change switch 153 and the reset switch 153 are integrally provided in the present embodiment, the present invention is not limited to this, and the setting change switch 153 and the reset switch 153 may be provided separately.

When shifting to the setting confirmation state, with the power turned on, the setting key is inserted into the setting key insertion port 151 and rotated 90 degrees clockwise, for example. As a result, the setting key switch 152 is turned on. When the door switch 17 is turned on while the power is on and the setting key switch 151 is turned on, the setting confirmation state is entered. In the setting confirmation state, the setting value cannot be changed (though the setting value does not change even if the setting change switch 153 is operated), but the current setting value can be confirmed. The current set value is displayed on the set value display LED 73. When the setting key is rotated counterclockwise and the setting key switch 152 is turned off, the setting confirmation state ends.

Further, when the power is off, the setting key is inserted into the setting key insertion port 151, the setting key is rotated 90 degrees clockwise, the setting key switch 152 is turned on, and the power switch 11 is turned on. It becomes possible to shift to the setting change state (setting change processing of FIG. 39).

When the slot machine 10 is powered on as described above, as shown in FIG. 38, the checksum is executed (step S204), the designated switch is turned on (step S208), and the power failure recovery is abnormal ( When it is possible to change the setting (step S209) or the setting (step S210), it becomes possible to shift to the setting change process (setting change state).

In the nineteenth embodiment, the “designated switch” in step S208 is the two switches, the door switch 17 and the setting key switch 152.
Alternatively, in addition to the door switch 17 and the setting key switch 152, a setting door switch (a switch that is turned on when a cover provided to cover the setting key insertion port 151 and the setting change (reset) switch 153 is opened) If provided, there are three switches, including a setting door switch.
In the following description, it is assumed that the setting door switch is not provided and the designation switches are the door switch 17 and the setting key switch 152.

Then, in FIG. 38, in step S208, only when the door switch 17 is on and the setting key switch 152 is on, it is determined to be "Yes" in step S208, and it is possible to shift to the setting change state. On the other hand, when only one of the door switch 17 and the setting key switch 152 is on, or when both switches are off, it is determined as “No” in step S208, and the setting is changed. Does not move.
As a result, when the front door 12 is not opened, or when the setting key is not inserted and there is a high possibility of a goto action, the setting change state is not entered.

In addition, in FIG. 38, “start of the setting change state” is firstly defined when “Yes” is determined in step S209 or when “No” is determined in step S210. .. In this case, the “setting change state” includes the processing of steps S221 to S233 in FIG. 39 as well.
Alternatively, secondly, in FIG. 39, when the output request at the time of starting the setting change is set in step S234 and the control command set 1 is executed in step S235 (the command to start the setting change is issued to the sub-control board 80). Is transmitted) is defined as "start of setting change state".

However, the present invention is not limited to this, and in FIG. 39, immediately before step S221 may be defined as "start of setting change state". Further, immediately after step S231 (at the end of initialization), it may be determined as "start of setting change state". Furthermore, when the interrupt is activated in step S233 or immediately after step S233 (immediately before step S234), the "start of the setting change state" may be defined.

Furthermore, in FIG. 39, “end of the setting change state” may be defined when the setting key switch 152 is turned off in step S243.
Alternatively, secondly, in FIG. 39, when the output request at the end of the setting change is set in step S246 and the control command set 1 is executed in step S247 (a command for ending the setting change is issued to the sub control board 80). Is sent) is defined as "end of setting change state".
However, the present invention is not limited to this, and when “Yes” is determined in step S242 (when the start switch 41 is operated and the set value is confirmed), the “end of the setting change state” may be defined.

Further, as will be described later, the setting change state may be terminated on the condition that the front door 12 is closed, in other words, on the condition that the door switch 17 is switched from ON to OFF. In this case, even if the setting key switch 152 is turned off, the setting change state does not end when the front door 12 is open (when the door switch 17 is on).
Another example is that the setting change state is not ended when the front door 12 is closed (when the door switch 17 is off) when the setting key switch 152 is turned off. This is because of measures against Goto.
In the following description, in the nineteenth embodiment (A), in FIG. 39, when it is determined to be “Yes” in step S243, that is, when the setting key switch 152 is turned off, “when the setting change state ends ".

In steps S246 and S247 of FIG. 39, when the command indicating that the setting change is completed is transmitted to the sub control board 80, the sub control board 80 receives the command. When the sub-control board 80 receives the command, the sub-control board 80 executes an output (output by the effect lamp 21) visually displaying the setting change end sound and the end of the setting change.
Here, in the present embodiment, the setting change end sound is equivalent to outputting a voice "setting change is completed" from the speaker 22.

Here, there are various thoughts about the speed at which words (Japanese) are spoken, but if you follow the idea that a speed of about 300 characters per minute is appropriate, you will say "the setting change is completed.""T01" for the time from the start of audio output to the end of audio output may be set to about "2000" ms.
FIG. 96 is a time chart showing a relationship between a setting change state, a setting change end sound and a lamp effect, and one game time described later in the nineteenth embodiment.
When the sub control board 80 receives a command indicating that the setting change has been completed, it immediately outputs a setting change end sound. Here, in FIG. 39, if “Yes” is determined in step S243, in the first interrupt process (FIG. 53) after the determination of “Yes” in step S243, the setting change is completed in step S464. Command is sent.

Then, in the sub control board 80, the interrupt processing is independently executed on the side of the sub control board 80, and it is determined for each interrupt processing whether or not a control command (command indicating that setting change has been completed) is received. ing. Then, when it is determined that the command indicating that the setting change is completed is received, the output of the setting change end sound is started.
Since the above process has been performed, at least one interrupt (referred to as an interrupt by the main control board 50.) from when "Yes" is determined in step S243 in FIG. 39. One interrupt time is "2.235" ms. After that, the sub-control board 80 starts outputting the setting change end sound or outputting the setting change end sound. In other words, in FIG. 39, the setting change end sound is not output until at least one interrupt has elapsed after the determination of “Yes” in step S243.

In FIG. 96, the timing at which the setting change state changes from on to off is when the setting key switch 152 is turned off, as described above. However, after the setting key switch 152 is turned off, a command is transmitted from the main control board 50 to the sub control board 80, the sub control board 80 receives the command, and starts outputting the setting change end sound. Since the time is extremely short, in FIG. 96, the end timing of the setting change state and the output start timing of the setting change end sound are matched.

In addition to the above-mentioned setting change end sound, a predetermined lighting mode of the effect lamp 21 (“lighting” is a concept that includes blinking.) Is a concept that includes a lighting color).
Here, when the lighting by the effect lamp 21 is executed, at least the same lighting mode as when the lighting by the effect lamp 21 is executed when the special role (feature) is elected is not performed. For example, if it is determined that the lamp A of the effect lamps 21 is to be turned on in the lighting mode a as an effect indicating that the special role has been won, the effect lamp 21 is selected as an effect indicating that the setting change has been completed. In the case of lighting, lighting of lamps other than the lamp A can be mentioned. In this case, if a lamp different from the lamp A is turned on, the lighting mode may be the same as the lighting mode at the time of indicating that the special combination is won.

Further, when the effect lamp 21 is turned on as an effect indicating that the setting change has been completed, the lamp A may be turned on. However, the lighting mode in this case is different from the lighting mode when indicating that the special combination has been won.
As described above, when the lighting of the effect lamp 21 is performed as an effect indicating that the setting change has been completed, the special combination has been won (that the special combination has been won in the game, or It should not be the same as the lighting mode of the effect lamp 21 in the effect of notifying that the winning has been carried over. As a result, when the game is started immediately after the setting change is finished, even if the production lamp 21 is turned on as an effect indicating that the setting change is finished, the player wins the special role. It is possible to prevent confusion when there is.

Further, it is preferable that the lighting pattern of the effect lamp 21 indicating that the setting change is completed and the lighting pattern of the effect lamp 21 indicating that the special combination is won are made different from each other so as not to be confused with each other. In other words, the lighting pattern of the effect lamp 21 indicating that the setting change has been completed is set to a lighting pattern that is not used for other effects, and if the lighting pattern is viewed, it means that the setting change is completed. It is preferable to be able to understand.
Further, for the effect lamp 21, the lighting pattern indicating that the setting change has been completed and the lighting pattern indicating that the special combination has been won are made the same, and for the lamps other than the effect lamp 21, the setting change is performed. The lighting pattern indicating the end may be different from the lighting pattern indicating that the special combination is elected.
Specifically, for example, when it is indicated that the setting change has been completed, all of the effect lamp 21 and the other lamps are turned on, and when notifying that the special role is won, the effect lamp 21 is turned on. It is possible to turn on the lamp but not turn on the other lamps. In this way, the manager can know which state the player is in by checking the lighting patterns of the effect lamp 21 and the other lamps (lamps of the gaming machine in general).

Furthermore, when the effect lamp 21 is turned on as an effect indicating that the setting change has been completed, as a general rule, the setting change end sound is output at the same time. However, not limited to this, the lighting effect of the effect lamp 21 may be started before the setting change end sound is output. Alternatively, the lighting effect of the effect lamp 21 may be started after the output of the setting change end sound is started and before the setting change end sound is output. Further, the lighting effect of the effect lamp 21 may be started after the output of the setting change end sound is ended.
Note that, as shown in FIG. 96, in the following embodiment, at the same time when the output of the setting change end sound is started, the effect lamp 21 indicating that the setting change has ended is executed.
Further, when the lighting time of the effect lamp 21 indicating that the setting change is completed is “T02”,
T01>T02
T01=T02
T01<T02
However, in the present embodiment, “T01<T02” is satisfied, as shown in FIG. 96. For example, when the time T01 is set to about "2000" ms as described above, the time T02 is set to, for example, about "2500" ms to about "4000" ms.

Next, consider a case where the setting change state is ended, the state is shifted to a normal state (a state in which the game can be started), and the game is immediately started.
In the following, as shown in FIG. 96, the time (preparation time until the game is started) required from the moment the setting change state is ended until the game is started (until the start condition of the game is satisfied) is referred to as “T11”. To do. Further, the time from the start of the game (after satisfying the start condition of the game) to the end of the game (1 game time) is defined as "T12".
In the setting change state, as shown in FIG. 39, the data stored in the RWM 53 is cleared. Therefore, for example, even if the player has bet data or credit data before starting the setting change, these data are also cleared. .. Therefore, immediately after the end of the setting change state, the bet amount is “0” and the credit amount is also “0”. Therefore, after the end of the setting change state, as shown in FIG. 2, it is necessary to insert the medals M from the medal insertion slot 47, bet the specified number, and then start the game.

Here, in the normal game (when the accessory is not operated), the bet number “3” is a commonly used prescribed number, but in the nineteenth embodiment (A), the minimum bet number “1” is the prescribed number. It is assumed that the game can be started with the bet number “1”. When the prescribed number is "1", the game can be started earlier than when the prescribed number is "2" or "3".
In FIG. 2, when the medal M is at the position M1 and is released into the medal selector, as described in the first embodiment, the medal M passes through the passage in the medal selector to the insertion sensors 44a and 44b. Detected. When it is determined by the insertion sensors 44a and 44b that the medal has normally passed, a "1" bet is placed.

In FIG. 2, the time taken for the medal M to be inserted from the position M1, detected by the insertion sensors 44a and 44b, and the specified number of bets to be bet corresponds to the preparation time "T11" for starting the game (note that The preparation time "T11" in this case does not take into consideration the operation time for closing the front door 12 or canceling the door open error.)
Here, if the prescribed number is "1", it is necessary to insert one medal, if the prescribed number is "2", it is necessary to insert two medals, and when the prescribed number is "3", You need to insert 3 medals. In FIG. 2, the time from the state of the medal M1 to the insertion of one medal to bet “1” is “T11a”, and the time to insert the two medals to bet “2”. If "T11b" is set and the time until three medals are thrown and "3" is bet is "T11c",
T11a<T11b<T11c
Becomes
However, since two or three medals can be continuously inserted, T11b (when the specified number is "2") is shorter than twice the time of T11a (when the specified number is "1"). It is believed that there is. Similarly, T11c (when the specified number is "3") is considered to be shorter than three times the time of T11a (when the specified number is "1").

Since a game can be started by operating the start switch 41 when a specified number of bets are placed, it is assumed in the present embodiment that the start switch 41 is operated at the moment when a "1" bet is placed. Therefore, the time from the bet of the specified number to the operation of the start switch 41 is set to "0".
In FIG. 41, when the start switch 41 is operated (“Yes” in step S278), rotation of the reel 31 is started in step S286.
Here, the motor 32 accelerates the reel 31 to reach a speed of 80 rotations per minute. When the speed reaches 80 rotations per minute, the speed is set to a constant speed. Until the reel 31 is in the constant speed state, the operation of the stop switch 42 is prohibited, and after reaching the constant speed state, the operation of the stop switch 42 can be received.
The time from when the start switch 41 is operated (after the rotation of the reel 31 is started) until when the operation of the stop switch 42 becomes possible is referred to as “T12a”.

Next, it is assumed that the first stop switch 42 is operated at the moment when the operation of the stop switch 42 can be accepted. In other words, the time from the moment when the operation of the stop switch 42 is accepted until the first operation of the stop switch 42 is set to “0”.
When the stop switch 42 is operated, as shown in FIG. 13, a reel stop control time (time until the reel 31 stops) and a four-phase excitation state time are required (note that the four-phase excitation state is Before the end, the operation of the next stop switch 42 may be accepted (this example will be described later). Let these total time be "T12b".
When the 4-phase excitation state ends, the next (second) stop switch 42 can be operated. Here, it is assumed that the second stop switch 42 is operated at the moment when the four-phase excitation state of the motor 32 that stops first stops and the operation of the next stop switch 42 becomes available. In other words, the time from the end of the four-phase excitation state of the motor 32 that stops first to the operation of the second stop switch 42 is set to "0".

When the second stop switch 42 is operated, the operation of the third stop switch 42 can be accepted after the reel stop control time and the time "T12b", which is the time of the four-phase excitation state, have passed, as described above. Becomes Here, it is assumed that the third stop switch 42 is operated at the moment when the four-phase excitation state of the second motor 32 ends and the next operation of the stop switch 42 is ready to be accepted. In other words, the time from the end of the four-phase excitation state of the motor 32 to be stopped second to the operation of the third stop switch 42 is set to “0”.
When the third stop switch 42 is operated, the reel stop control time and the time "T12b", which is the time of the four-phase excitation state, are required as in the above case.

Although the moment when the last reel 31 stops may be defined as the end of one game, in the nineteenth embodiment (A), when the time of the four-phase excitation state for the last reel 31 ends, 1 It is determined that the game is completed (when there is no payout).
Further, when the symbol combination corresponding to any of the winning combinations in the game is stopped, it is determined that the game is completed when the payout process is completed, specifically, when the process of FIG. 49 is completed.
Incidentally, when the symbol combination corresponding to the replay is stopped and displayed, as shown in FIG. 42, the automatic bet process is executed at the start of the next game. Therefore, when the symbol combination corresponding to the replay is stopped and displayed, it is determined that the game end is not the end of the automatic bet process but the end of the four-phase excitation state for the third reel 31.

For example, first, when the symbol combination corresponding to the small winning combination is stopped and the credit addition processing is executed, the end of the credit addition processing is determined to be the end of the game.
Further, when the symbol combination corresponding to the small winning combination is stopped and the actual medal payout process is executed, the payout of the last medal (driving the hopper 36) is completed, and “Yes” in step S401 in FIG. 49. The time (when it is determined that the payout amount data is “0”) is defined as the end of the game. However, even if it is assumed that the number of credits is “0” immediately after the end of the setting change, the game is started immediately after the setting change state is ended, and the small winning combination having the maximum payout amount “15” is won. All paid-out medals are credited. Therefore, in one game immediately after the end of the setting change, the medals are not actually paid out.
The symbol combination corresponding to the small winning combination is stopped and displayed, and the time from when the four-phase excitation state of the motor 32 for the third reel 31 is finished to when the payout of medals (addition to credits) is finished is "T12c". And
However, when the winning combination is not won (when no medals are paid out), “T12c=0”.

Further, when an effect (notification effect of winning combination, etc.) is output when all reels 31 are stopped, the effect time is not included in one game time. For example, even when an effect is output for several seconds after all the reels 31 are stopped, when the four-phase excitation state of the motor 32 is finished when the last reel 31 is stopped (at that time, all the reels 31 are stopped. It is assumed that one game ends (even when the production that has started the output sometimes continues). That is, the end of one game is based on the control by the main control board 50.

As described above, when the operation for starting the game is performed immediately after the end of the setting change state and the game is started, the preparation time "T11" until the game is started is required.
Furthermore, one game time "T12" is, as described above,
(1) Time "T12a" from when the start switch 41 is operated (after the rotation of the reel 31 is started) until when the operation of the stop switch 42 becomes possible.
(2) Time from the first operation of the stop switch 42 until the reel 31 stops and the time of four-phase excitation state "T12b"
(3) Time from when the second stop switch 42 is operated to when the reel 31 is stopped and time for four-phase excitation state "T12b"
(4) Time from when the third stop switch 42 is operated to when the reel 31 is stopped and time for four-phase excitation state "T12b"
(5) Time "T12c" until payment of medals (addition to credits) is completed when a small winning combination is won
Requires.
Therefore,
T12=T12a+3×T12b+T12c
Becomes
It is assumed that the three “T12b” times are the same.

Furthermore, when the start switch 41 is operated, a lottery of the winning combination is performed (step S282 in FIG. 41), and when a special winning combination (feature) is won in this lottery, a freeze (also referred to as "freezing effect") is performed. .) may be selected to be performed.
The "freeze" in this case refers to a state in which the progress of the game is stopped for a certain period of time. Therefore, for example, when the start switch 41 is operated, lottery of the winning combination is executed, it is determined that the special winning combination is won and the freeze is executed as an effect corresponding to the winning of the special winning combination, the rotation of the reel 31 is started. do not do. Then, after the freeze ends, the rotation of the reel 31 starts. It should be noted that, while the progress of the game is stopped due to the freeze, the sub-control unit 80 outputs an effect using the image display device 23 or the like.
If the freeze time in this case is “T12d”, one game time “T12” when the freeze is executed is “T12a+T12b×3+T12c+T12d”.

Next, consider the shortest time of one game time "T12". Since one game time is the shortest time, the freeze is not executed and the winning combination is not won.
Therefore, the shortest time of one game time “T12” is “T12a+3×T12b”.
First, the prescribed number is set to "1", and the time from when the medal M is inserted (dropped) in the medal selector from the position of M1 in FIG. 2 to bet (time required to start the game) It is assumed that "T11" is about "800" ms at the shortest.
Further, it is assumed that the time "T12a" from when the start switch 41 is operated to when the reel 31 becomes a constant speed and the operation acceptance of the stop switch 42 is permitted is about "1200" ms.

Furthermore, the time "T12b" from when the stop switch 42 is operated to when the reel 31 is stop-controlled and the four-phase excitation state of the motor 32 ends (the operation of the next stop switch 42 can be accepted) is As illustrated in FIG. 13, the shortest time is about “140” ms (reel stop control time is the shortest time is about “40” ms, and the four-phase excitation state time is the shortest time is about “100” ms). Suppose
In this case, “T11+T12”, which is the time required to start one game and one game time (shortest time), is “800 (T11)+1200(T12a)+140×3(T12b×3)”=“2420” ms It becomes a degree.
One game time "T12" in the case where the medals are paid out after all the reels 31 are stopped or when the freeze is executed when the start switch 41 is operated is longer than the above time.

On the other hand, as described above, when the setting change state is ended, the setting change end sound is output for the time “T01” (about “2000” ms) and the effect lamp 21 notifying the end of the setting change is issued. Lighting is output for a time "T02" (for example, about "2500" to "4000" ms).
Therefore, when the game is started immediately after the setting change state is ended, the setting change end sound "T01" which is output immediately after the setting change state is ended, and the preparation time "T11" for starting the game and one game The relationship with the time "T12 (shortest time)" is
T01<T11+T12
Becomes
Thereby, even when the operation (preparation) for starting the game is performed from the moment when the setting change state is ended, and the game is started at the moment when the preparation for starting the game is completed, the game is ended. That is, the output of the setting change end sound has been completed.
FIG. 96 shows the relationship among the above times “T01”, “T11”, and “T12”.

Here, the above example is an example in which the operation of the next stop switch 42 can be accepted after the stop switch 42 is operated and the four-phase excitation state ends. However, the present invention is not limited to this, and the operation of the next stop switch 42 may be accepted after the stop switch 42 is operated and before the 4-phase excitation state is terminated. By controlling in this way, the game can be digested more quickly. For example, after the stop switch 42 is operated (the operation of the stop switch 42 is accepted), it is possible to accept the operation of the next stop switch 42 at the time of the next interrupt processing.
In this case, since the time in the four-phase excitation state can be considered to be substantially “0” among the time “T12b” described above, “T12b (shortest time)=40 (ms)”.
Therefore, "T11+T12", which is the time required to start one game and one game time (shortest time) in this case, is "800(T11)+1200(T12a)+40x3(T12bx3)"="2120." It will be about ms.
Therefore, even in the case of such control, “T01<T11+T12” is satisfied.

In addition, as the effect timing of the slot machine 10, when the start switch 41 is operated (when the reel 31 starts rotating), when the first stop switch 42 is operated (when the first reel 31 is stopped), when the second stop switch 42 is operated (the first There are two reels 31 stopped) and the operation of the third stop switch 42 (when all reels 31 are stopped), but the final notification of the winning combination of the game (the most important effect in the game) is output. The timing of doing is often when all reels 31 are stopped.
Therefore, in the case of outputting the effect that announces the winning combination of the game when all reels 31 are stopped, the effect is output after the output of the setting change end sound is finished, so when all reels 31 are stopped. The effect and the setting change end sound do not overlap (do not cover). Therefore, even when the game is started immediately after the setting change state is finished, it is possible to accurately understand the effect when all reels 31 are stopped.

However, when there is an effect output when the start switch 41 is operated or when the first or second stop switch 42 is operated, the output timing of the effect and the output timing of the setting change end sound may overlap.
Here, the speaker 22 of the present embodiment has a plurality of channels. The channel for outputting the setting change end sound is set to be different from the channel for outputting the notification effect of the winning combination. As a result, even if the notification effect of the winning combination is output from the speaker 22 after the output of the setting change end sound is started, the setting change end sound is not erased on the way. However, there is a possibility that the setting change end sound and the winning effect notification sound may overlap.

Further, the lighting time T02 of the effect lamp 21 indicating that the setting change has been completed is
T02<T11+T12
T02=T11+T12
T02>T11+T12
Both cases are possible. However, as described above, if the lighting of the effect lamp 21 indicating that the setting change is completed is not confused with the lighting of the effect lamp 21 as the notification effect of the winning combination, no problem occurs.

In addition, the preparation time "T11" before starting the game eliminates the time to close the front door 12 and the door open error (error indicating that the front door 12 is open) after ending the setting change state. It does not consider the time to do.
At the end of the setting change state, at least the front door 12 should be in the open state. Therefore, even if the setting change state is completed, the slot machine 10 detects the door open error and notifies the error. When the door open error occurs, the game cannot be advanced (started). When the door open error occurs, the blocker 45 is controlled to be off (the state of returning medals), so that no bet is made even if a medal is inserted from the medal insertion slot 47. Even if the player is betting, the game is not started even if the start switch 41 is operated.

To cancel the door open error, the front door 12 is closed and the door switch 17 is turned off. The door open error can be eliminated at the moment when the door switch 17 is turned off. However, in general, a key is inserted in the key insertion opening for opening the front door 12 provided in the front door 12. The door open error is eliminated (error notification is terminated) by rotating the key in the opposite direction (for example, counterclockwise direction) from the case of inserting and opening the front door 12. Therefore, after the end of the setting change state, the preparation time "T11" for starting the game includes the operation time for closing the front door 12 and inserting the key to release the door open error. This is because the game cannot be started with the door open error still occurring.

When the setting change state is ended on condition that the setting key switch 152 is turned off, the setting change state can be ended even if the front door 12 is open. Therefore, in this case, the output of the setting change end sound is started in the state where the front door 12 is opened, and the lighting of the effect lamp 21 indicating that the setting change is ended is also started.

On the other hand, it is also possible to adopt a specification in which the setting change state is not ended unless the front door 12 is closed. In this case, merely turning off the setting key switch 152 does not end the setting change state, and closing the front door 12 (turning off the door switch 17) is set as one of the ending conditions of the setting change state. The setting change state may be ended only by closing the front door 12. In this case, when the front door 12 is closed (the door switch 17 is turned off), the output of the setting change end sound is started. Alternatively, the setting change state may be terminated when the front door 12 is closed and the door open error is released. In this case, when the door open error is released, the output of the setting change end sound is started.

Even in the case of the specification that the setting change state ends when the front door 12 is closed and the door open error is released, as described above, the time “T11+T12” from the end of the setting change to the end of one game. Since the output time “T01” of the setting change end sound is shorter than the setting change end sound, the output of the setting change end sound is finished before the end of one game immediately after the end of the setting change.
Further, when the setting key switch 152 is turned off, when the setting change state is ended even if the front door 12 is opened, the setting change end sound is output while the front door 12 is open. Therefore, after the front door 12 is closed, the door open error is released, and even if one game is ended after the time "T11+T12", the output of the setting change end sound is ended before the end of the game. ..
In addition, when the (operation) time from the end of the setting change state to the closing of the front door 12 and the release of the door open error is "T10", one game is started after the end of the setting change state. The preparation time is “T10+T11”. Therefore, it goes without saying that “T01<T10+T11+T12” is satisfied.

The above is the case where the output time “T01” of the setting change end sound is set to be shorter than the time “T11+T12” from the end of the setting change state to the end of one game, while not limited to this. The relationship between the output time “T01” of the setting change end sound and the time “T11+T12” from the end of the setting change state to the end of one game can be variously set as follows.
(1) The output time “T01” of the setting change end sound is set to be shorter than the average time “T11+T12” when the winning combination lottery result is not won.
(2) The output time “T01” of the setting change end sound is set to be shorter than the average time “T11+T12” when the special combination is won in the combination lottery result. When the special lottery result is won, the above-mentioned freeze may or may not be performed, so the average time is “T12”. For example, at the time of winning a special role, if freeze is executed with a probability of "p"% and freeze is not executed with a probability of "100-p"%, the average value of one game time "T12" is
"Average one game time without freeze T12 x (100-p)/100" + "Average one game time with freeze T12 x p/100"
Becomes

<The nineteenth embodiment (B): when the gaming machine is a pachinko gaming machine>
Next, the relationship between the setting change state, the setting change end sound, and one game time in the pachinko gaming machine will be described.
First, an outline of a pachinko game machine will be described.
FIG. 97 is an external perspective view of the pachinko gaming machine 500 as viewed from the front side (player side). Further, FIG. 98 is an external perspective view of the pachinko gaming machine 500 as viewed from the back side. Note that in FIG. 98, the unit including the image display device 543 and the game board 504 is omitted, and the glass door 505 is illustrated so that it can be seen from the back surface side. Further, in FIG. 98, the illustration of the board cases other than the main board case 550 is appropriately omitted.
Furthermore, FIG. 99 is a block diagram of the pachinko gaming machine 500.

In the hall, the pachinko game machine 500 is generally installed on an island. The pachinko gaming machine 500 firstly includes an outer frame 501 and a front frame 502. The outer frame 501 is a frame body formed so as to surround the outer periphery of the pachinko gaming machine 500. The front frame 502 is attached to the front side (player side) of the outer frame 501 in FIG. 97. The front frame 502 is attached to the outer frame 501 so as to be openable and closable with respect to the outer frame 501 by a hinge mechanism 503 provided at the upper left end of the outer frame 501 in FIG. Therefore, when the pachinko gaming machine 500 is installed on the island, the outer frame 501 is fixed to the island, but the front frame 502 can be opened and closed with respect to the outer frame 501, and on the back surface side of the front frame 502. It becomes accessible.

The front frame 502 is provided with a game board 504. Although not shown, the game board 504 is provided with an image display device 543, nails, accessories, a windmill, various winning openings (including a starting opening 532 described later), and the like. In addition, a portion other than the game board 504 of the front frame 502 is provided with an effect lamp 541, a speaker 542, an upper plate 506, a lower plate 507, a firing handle 508, and the like.

In FIG. 97 of the front frame 502, a key insertion opening 521 is formed on the right side edge portion.
When the front frame 502 is closed with respect to the outer frame 501 (the state shown in FIG. 97), a key is inserted from the key insertion opening 521, and the outer frame 501 and the front frame 502 are unlocked. The front frame 502 can be opened forward (toward the player) with respect to the outer frame 501 with the hinge mechanism 503 as the central axis. When the front frame 502 is opened with respect to the outer frame 501, the game board 504 attached to the front frame 502 side, the glass door 505, the effect lamp 541, the speaker 542, the upper plate 506, the lower plate 507, the firing handle. The whole including 508 moves forward with respect to the outer frame 501.
When the front frame 502 is opened, a frame opening switch 523 described later is turned on. When the frame opening switch 523 is turned on, a frame opening error is notified.

The glass door 505 is openably and closably attached so as to cover the game area on the front surface of the game board 504. This is because, for example, when a game ball is clogged in the game area, it is eliminated. By inserting a key into the key insertion opening 521 and unlocking the glass door 505, the locking of the glass door 505 and the game board 504 is released, and the glass door 505 can be opened. When the glass door 505 is opened, a door opening switch 522 described later is turned on. When the door opening switch 522 is turned on, a door opening error is notified.

In the block diagram of FIG. 99, in the pachinko game machine 500, a main control board (main board, main control board) 530 corresponding to the main control board 50 of the slot machine 10 and a sub control board 80 of the slot machine 10 are provided. And a control board (production control board, production board) 540.
The main control board 530, the payout control board 520, and the sub control board 540 each include a CPU, an RWM, a ROM, and the like, like the main control board 50 and the sub control board 80 of the slot machine 10, respectively. In FIG. 99, the illustration of the CPU, RWM, ROM, etc. is omitted.

When the power switch 511 is turned on, the power board 510 controls the power supply.
A power supply board 510 and a payout control board (also referred to as a "prize ball control board") 520 are connected to a harness (one or more lead wires (also referred to as "signal wires")). .. It is assumed that the boards shown in FIG. 99 are all harness-connected. Further, in FIG. 99, the illustration of the relay board is omitted, but in reality, each of the boards shown in FIG. There is.
A launch board 512 is connected to the power supply board 510. The launch board 512 is a board for driving and controlling the launch apparatus 513. The launching device 513 is a device for launching a game ball onto the game board 504 (game area). When the firing handle 508 is operated, the operation is detected, and the firing device 513 is drive-controlled to launch the game ball into the game area.

A payout control board 520 is connected to the power supply board 510. A payout device 524 is connected to the payout control board 520. The payout device 524 is a device for renting out the game balls corresponding to the requested number when the CR unit requests the ball lending, and for paying out the prize balls corresponding to the winning when the game balls are won. is there. The payout control board 520 and the CR unit are connected via an external terminal board 525.

A door opening switch 522 and a frame opening switch 523 are electrically connected to the payout control board 520. The door opening switch 522 and the frame opening switch 523 may be connected to the main control board 530.
As described above, when the glass door 505 is opened, the door opening switch 522 is turned on, and the signal is input to the payout control board 520 and further transmitted to the main control board 530. When the main control board 530 detects that the door opening switch 522 is turned on, the sub control board 540 executes, for example, notification of a door opening error.
Further, when the front frame 502 is opened, the frame opening switch 523 is turned on, and its signal is input to the payout control board 520 and further transmitted to the main control board 530. When the main control board 530 detects that the frame opening switch 523 is turned on, the sub control board 540 executes, for example, notification of a frame opening error.

The main control board 530 is connected to a starting opening switch 533 for detecting a winning at a starting opening 532 which is one of the winning openings provided in the game area of the game board 504. When the game ball wins the starting opening 532 and the main control board 530 detects that the starting opening switch 533 is turned on, a random number value is acquired and a winning/deciding determination is executed as described later (lottery processing). Then, based on the result of the judgment, the variation time and the stop symbol of the special symbol of the special symbol display device 531 are determined, and the variation pattern and the stop symbol of the special symbol display device 531 are controlled so as to correspond to the determination result.

In addition, on the game board 504, general winning openings and big winning openings (winning openings that are jackpots and are opened during special games) and the like are listed as winning openings other than the starting opening 532. Is omitted in the nineteenth embodiment (B).
Further, the special symbol display device 531 is a device which is provided on the game board 504 and displays the result of winning/decision determination based on that the starting opening switch 533 is turned on by a special symbol. In other words, the "special symbol" is a symbol that indicates whether the result of the winning/disapproval determination is a win or a non-win by the stopped symbol after the change. The special symbol display device 531 is composed of, for example, a 7-segment display.
The flow from the start to the change of the special symbol will be described later.

The main control board 530 is provided with a setting key switch 535 having a setting key insertion opening 534 and a setting change (reset) switch 536. The setting key insertion slot 534, the setting key switch 535, and the setting change (reset) switch 536 do not necessarily have to be provided on the main control board 530, and they may be provided as separate devices.
The setting key switch 535 is a switch which is turned on when a predetermined setting key is inserted from the setting key insertion opening 534 and rotated 90 degrees clockwise, for example.

The setting change (reset) switch 536 is a switch that serves both as a setting change switch and a reset switch. The setting change switch is a switch operated when changing a set value during the setting change state. The reset switch is a switch that is operated when the error that has occurred is removed and then the state before the error occurred is restored. In the following description, there are a case where it is referred to as a “setting change (reset) switch 536”, a case where it is referred to as a “setting change switch 536”, and a case where it is referred to as a “reset switch 536”.
In the present embodiment, the setting change switch 536 and the reset switch 536 are integrally provided, but the present invention is not limited to this, and the setting change switch 536 and the reset switch 536 may be provided separately.
In the pachinko gaming machine 500, when the power is off, the setting key is inserted into the setting key insertion port 534, the setting key is rotated to turn on the setting key switch 535, and the reset switch 536 is turned on. By turning on the power switch 511, it becomes possible to shift to the setting change state.

When shifting to the setting change state, the current set value is displayed on the set value display LED 537. The set value display LED 537 is equivalent to the set value display LED 73 in the slot machine 10 shown in FIG. 1, and is composed of, for example, a 7-segment display.
Then, when changing the set value, the setting change switch 536 is operated. Each time the setting change switch 536 is operated (pressed), the set value is incremented by "+1". For example, when the set value is in 6 steps, each time the setting change switch 536 is pushed, "1"→"2"→... -The set value cyclically changes in the order of → "5" → "6" → "1" →.... Then, when the setting key is turned counterclockwise, for example, and the setting key switch 535 is turned off, the set value is confirmed and the setting change state is ended. When the setting change state ends, the set value displayed on the set value display LED 537 is also turned off.

When the power is off, the setting key is inserted into the setting key insertion port 534, the setting key is rotated, and the power switch 511 is turned on while the reset switch 536 is off. Become. In the setting confirmation state, the set value cannot be changed, but the current set value is displayed on the set value display LED 537. Then, when the setting key is rotated to turn off the setting key switch 535, the setting confirmation state ends. When the setting confirmation state ends, the set value displayed on the set value display LED 537 is also turned off.
In the pachinko gaming machine 500, unlike the slot machine 10, even if the setting key switch 535 is turned on after the power is turned on, the setting confirmation state is not entered and the setting value is not displayed.

The management information display LED 538 corresponds to the management information display LED (role ratio monitor) 74 in the slot machine 10, and in the case of the pachinko gaming machine 500, it is called a performance display monitor as described above. The management information display LED 538, like the management information display LED 74, is composed of four 7-segments.

The sub control board 540 is a board that is connected to the main control board 530, determines effect contents based on a command transmitted from the main control board 530, and controls to output the decided effect. Although FIG. 99 shows one sub-control board 540, in practice, for example, the sub-control board 540 is a sub-main board (a board for controlling the overall effect) and a sub-sub-board (for example, an image display). Substrate for controlling the image display of the device 23).

Similar to the slot machine 10, the peripheral device for effect is provided with an effect lamp 541, a speaker 542, and an image (liquid crystal) display device 543, and these outputs are controlled by the sub control board 540.
As shown in FIG. 97, at least a part of the effect lamp 541 is attached so as to cover the outer peripheral edge of the front frame 502. The speaker 542 is attached to the upper side of the front frame 502. Furthermore, the image display device 543 is attached so that an image is displayed at a substantially central portion in the game area of the game board 504.

Next, the control processing of the pachinko gaming machine 500 will be described.
FIG. 100 is a flowchart illustrating the flow of activation of the pachinko gaming machine 500 after the power is turned on.
When the power switch 511 is turned on and the power is turned on, in step S701, the main control board (specifically, corresponds to the main CPU) 530 determines whether or not the transition condition to the setting change state is satisfied. To judge. In the present embodiment, the frame opening switch 523 is set to ON, the setting change key switch 535 is set to ON, and the reset switch 536 is set to ON as the transition condition of the setting change state. If it is determined that all of these conditions are satisfied, the process proceeds to step S702, and if it is determined that all three switches are not turned on, the process proceeds to step S703. In step S702, the process proceeds to the setting change process (setting change state). Then, when the setting change process is completed, the process proceeds to step S709.

In step S703, the main control board 530 determines whether or not the transition condition to the setting confirmation state is satisfied. In the present embodiment, the condition for shifting to the setting confirmation state is that the frame opening switch 523 is on, the setting change key switch 535 is on, and the reset switch 536 is off. When it is determined that these conditions are satisfied, the process proceeds to step S704, and when it is determined that these conditions are not satisfied, the process proceeds to step S706.

In step S704, the setting confirmation state is entered, and the main control board 530 reads the setting value data stored in the RWM and displays the current setting value on the setting value display LED 537. Next, in step S705, it is determined whether the setting key switch 535 is turned off. When it is determined that the setting key switch 535 is turned off, it is determined that the ending condition of the setting confirmation state is satisfied, and the process proceeds to step S710. On the other hand, if it is determined that the setting key switch 535 is not off, the process returns to step S704 and the setting confirmation state (display of the set value) is continued.

If “No” is determined in step S703 and the process proceeds to step S706, the main control board 530 determines whether the reset switch 536 is on. When it is determined that the reset switch 536 is on, the process proceeds to step S709, and when it is determined that the reset switch 536 is not on, the process proceeds to step S707.
In step S707, it is determined whether the RWM of the main control board 530 is normal. When the power is turned off, the RWM of the main control board 530 stores the information when the power is turned off. When the power is turned on next time, it is determined whether the information when the power is turned on matches the information when the power is turned off. To do. When they match, it is determined that the RWM is normal, and when they do not match, it is determined that the RWM is abnormal. When it is determined that the RWM is normal, the process proceeds to step S708, and when it is determined that the RWM is not normal, the process proceeds to step S709.
In step S708, a state restoration process is executed. This process is a process for returning the state of the solenoid, the state of the special symbol display device 531 and the like to the state when the power is cut off. Then, the process proceeds to step S710.

When the setting change process (setting change state) in step S702 is completed, when it is determined in step S706 that the reset switch 536 is on, or when it is determined in step S707 that the RWM is not normal, the process proceeds to step S709. Then, the RWM clearing process is executed. This process is a process of clearing the data stored in the predetermined storage area of the RWM (processing of initializing the predetermined storage area). The data to be cleared does not include the set value data. Then, the process proceeds to step S710.

In step S710, the timer interrupt is permitted. This process is a process for enabling the interrupt process. Therefore, when the interrupt processing timing comes after the interrupt processing is permitted in step S710, the interrupt processing is executed.
In the next step S711, a random number update process (random number counter increment process) is executed. This random number is used for various lottery (selection of stop symbol, selection of effect, etc.).

101 is a flowchart showing the setting change process in step S702 of FIG. In the present embodiment, the start of the process of step S721 is the start of the setting change process (setting change state).
In step S721, the main control board (main CPU) 530 reads the set value written in the RWM and determines whether the set value is within the normal range. In the present embodiment, the values stored in the RWM corresponding to the set values "1" to "6" are "0" to "5".

For example, if the value stored in the RWM is "0", the set value will be "1". Therefore, in step S722, it is determined whether or not the value stored in the RWM is within the range of "0" to "5". When it is determined that the value is within the range, the process proceeds to step S724. On the other hand, when it is determined that the value stored in the RWM is not within the range of “0” to “5”, “0” is stored in the RWM. When the value of RWM is "0", the set value is "1". The set value “1” is a basic set value as described later. Then, the process proceeds to step S724.

In step S724, the main control board 530 displays the set value corresponding to the value stored in the RWM on the set value display LED 537. For example, when the value of RWM is "0", "1" is displayed on the set value display LED 537.
Next, proceeding to step S725, the main control board 530 determines whether or not the setting change switch 536 has been operated. If it is determined that the setting change switch 536 has been operated, the process proceeds to step S726, and if it is determined that it has not been operated, the process proceeds to step S729. In step S726, "1" is added to the set value. For example, when "1" is displayed on the set value display LED 537 until then, the display is updated from "1" to "2" by the process of step S726, and the set value data stored in the RWM is set to "0". Is updated from "" to "1". In the example of FIG. 101, when the setting value “6” is displayed in step S724, if it is determined in step S725 that the setting change switch 536 is operated, the process of step S726 is skipped and the process proceeds to step S727. Let's assume.

In step S727, it is determined whether the set value exceeds the upper limit. For example, when the setting value "6" is displayed in step S724 and it is determined in step S725 that the setting change switch 535 has been operated, it is determined in step S727 that the upper limit value has been exceeded. On the other hand, when the setting values “1” to “5” are displayed in step S724, when it is determined that the setting change switch 536 is operated in step S725, it is determined that the upper limit of the setting value is exceeded in step S727. Is not judged.
When it is determined in step S727 that the upper limit of the set value is exceeded, the process proceeds to step S728, and when it is determined that the upper limit of the set value is not exceeded, the process proceeds to step S729.

In step S728, the basic setting value is set. That is, “0” is stored as the set value data of RWM, and “1” is displayed on the set value display LED 537. Then, the process proceeds to step S729.
In step S729, the main control board 530 determines whether or not a condition for ending the setting change process (setting change state) is satisfied. In this embodiment, when the setting key switch 535 is turned off, it is determined that the condition for ending the setting change process is satisfied. Therefore, in step S729, the main control board 530 determines whether or not the setting key switch 535 is on, and when determining that the setting key switch 535 is on, returns to step S724 and determines that it is off. If so, the process proceeds to step S730.

In step S730, the set value display of the set value display LED 537 is hidden.
Next, proceeding to step S731, the main control board 530 transmits a setting change end command to the sub control board 540. Then, the processing according to this flowchart is ended.
When the sub-control board 540 receives the setting change end command, it outputs a setting change end sound from the speaker 542, and executes the lighting process of the effect lamp 541 to indicate that the setting change has ended.

In addition, the end timing of the setting change state in Pachinko gaming machine 500,
(1) When it is determined to be “Yes” in step S729 (when it is detected that the setting key switch 535 is turned off).
(2) When the display of the set value by the set value display LED 537 is hidden in step S730.
(3) When the setting change end command is transmitted in step S731.
However, the end timing of the setting change state in the nineteenth embodiment (B) may be set to “when the setting key switch 535 is turned off” in the above (1). Stipulate.
However, not limited to this, the above (2) and (3) may be set as the end timing of the setting change state.

FIG. 102 is a flowchart showing the flow of one game in the pachinko gaming machine 500.
In the Pachinko game 500, the start timing of one game may be one of the following.
(1) When the game ball is launched by the launching device 513 toward the game area of the game board 504. In this case, one game will be started even if the game ball has not reached the game area.
(2) When the game ball is launched toward the game area of the game board 504 by the launching device 513 and the game ball enters the game area. Although illustration is omitted in FIG. 97, a rail for guiding the game ball launched by the launching device 513 into the game area is provided in the range from the lower side to the left side of the game area to the upper left. ing. Then, the moment when the game ball comes off the rail (the moment when the game ball enters the game area) is defined as the start of one game.

(3) When the game ball wins the starting opening 532 provided in the game area. Or, when the game ball wins the starting opening 532 provided in the game area and the starting opening switch 533 is turned on.
As described above, as the start time of one game in the pachinko gaming machine 500, various points can be cited as to which time point is the start time, but in the present embodiment, the above-mentioned (3) "gaming ball is the starting opening 532""When you enter" is the start timing of one game.
Further, the timing of the end of one game is when the fluctuation of the special symbol display device 531 is finished and the special symbol is stopped and displayed.

In step S741, the main control board (main CPU) 530 continues to determine whether or not a game ball has been won in the starting opening 532. That is, the starting opening switch 533 is turned on. If it is determined that the starting opening switch 533 is turned on, then the flow proceeds to step S742.
In step S742, various lottery processes are executed at the timing when the starting opening switch 533 is turned on. A random number value is extracted at the timing when the start opening switch 533 is turned on, and based on the extracted random number value, jackpot lottery (judgment of whether it is jackpot or out), special symbol lottery (stop symbol of special symbol) Which lot is used as a symbol), and a variation pattern lottery (a lottery for the variation time of the special symbol) is executed.

In the next step S743, prize ball processing (prize ball payout processing) based on winning in the starting opening 532 is executed. Here, the payout control board 520 drives and controls the payout device 524 to pay out a predetermined number of game balls.
Of the various lottery processes executed in step S742, at least part of the lottery results including the fluctuation time is transmitted to the sub control board 540. When receiving the lottery result of the game this time, the sub control board 540 controls the effect lamp 541, the speaker 542, and the image display device 543 so as to correspond to the lottery result.

Next, proceeding to step S744, the main control board 530 starts changing the special symbol by the special symbol display device 531 based on the lottery result in step S742. In addition, the change of the special symbol by the special symbol display device 531 is a condition that the change of the previous special symbol has ended at that time, and when the change of the special symbol is in progress, the next special symbol The fluctuation is suspended, and after the fluctuation of the special symbol that is currently fluctuating ends, the fluctuation of the next special symbol is started.

In step S745, the sub-control board 540 causes the image display device 543 to change the decorative symbol. The change in the decorative pattern corresponds to a part of the effect in the game this time.
Here, the device which directly shows the result of the jackpot lottery in step S742 is the special symbol display device 531 and the stop symbol after the change by the special symbol display device 531 has a special symbol corresponding to the jackpot (for example, "7"). )), and a special symbol (for example, “−”) corresponding to the deviation are provided.

Further, the decorative design is varied by the image display device 543 so as to be linked (synchronized) with the variation of the special design. Then, when the special design corresponding to the big hit is stopped, the decorative design is also stopped with the decorative design corresponding to the big hit such as "777". On the other hand, when stopping with the special symbol corresponding to the loss (non-winning), the decorative symbol is also stopped with the decorative pattern corresponding to the loss (a pattern other than the decorative symbol corresponding to the jackpot). The special symbol display device 531 is composed of a small 7-segment display, but the image display area of the image display device 543 for displaying the decorative symbol as an image is larger than the image display area of the special symbol display device 531 (for example, a game. It is formed so as to occupy more than half of the area). Thereby, the player can confirm whether or not the game is a big hit this time by seeing the stop mode of the decorative symbol.

The variation of the decorative symbol in step S745 is controlled to be within the variation time determined by the lottery in step S742. Then, when the variation of the decorative symbol ends, the process proceeds to step S746, the main control board 530 varies the special symbol for the variation time determined by the lottery, and then the variation of the special symbol becomes the stop symbol determined by the lottery. finish.
Next, proceeding to step S747, post-stop processing of the special symbol is executed. As the post-stop processing, for example, when the game is a big hit this time, processing for shifting to a special game can be cited.

In the nineteenth embodiment (B) of the pachinko gaming machine, similarly to the nineteenth embodiment (A) of the slot machine, the setting change end sound is emitted after the setting change state ends, and the lamp indicating the end of the setting change is turned on. Execute. Further, when it is assumed that the game is started at the same time as the end of the setting change state, the setting change end sound is output before the end of the game.
As described above, assuming that the setting change state is ended when “Yes” is determined in step S729 in FIG. 101, then the setting change end command is transmitted to the sub control board 540 in step S731, Upon receiving the command, the control board 540 starts outputting the setting change end sound from the speaker 542.

The time from when it is determined “Yes” in step S729 until the output of the setting change end sound (and the predetermined lighting by the effect lamp 541) is started is longer than “0” ms, for example, in step S729. The timing is about the time when one interrupt time (for example, "4" ms in the case of the pachinko gaming machine 500) has elapsed from the time when "Yes" is determined. In other words, the setting change end sound is not output until at least one interrupt has elapsed after the determination of “Yes” in step S729.
Then, the setting change end sound is to output the sound "The setting change is completed.", as in the nineteenth embodiment (A). Further, when the time from the output start to the output end of the sound "the setting change is completed" is "T01" as in the nineteenth embodiment (A), the time "T01" is the nineteenth embodiment (A). In the same manner as the above), it is possible to set about 2000 ms.

Further, as an effect indicating that the setting change has been completed, in addition to the setting change end sound, an effect of turning on the effect lamp 541 in a predetermined lighting mode is executed.
Here, when the lighting by the effect lamp 541 is executed, at least the same lighting mode as when the lighting by the effect lamp 541 is executed at the time of a big hit is not performed. For example, if it is determined that the lamp A of the effect lamps 541 is turned on in the lighting mode a as an effect indicating that the jackpot has been hit, the effect lamp 541 is turned on as an effect indicating that the setting change has been completed. In this case, it is possible to turn on a lamp other than the lamp A. In this case, as long as the lamp different from the lamp A is turned on, the lighting mode may be the same as the lighting mode when the big hit is shown.

When the effect lamp 541 is turned on as an effect indicating that the setting change has been completed, the lamp A is turned on. In this case, the lighting mode is different from the lighting mode when the big hit is shown.
As described above, when the effect lamp 541 is turned on as an effect indicating that the setting change has been completed, the lighting mode of the effect lamp 541 when the jackpot is hit is not the same. Thereby, when the game is started immediately after the setting change is finished, even if the production lamp 541 is turned on as an effect indicating that the setting change is finished, the player misunderstands that the jackpot is a big hit. It is possible to prevent that.

Furthermore, it is preferable that the lighting pattern of the effect lamp 541 indicating that the setting change is completed and the lighting pattern of the effect lamp 541 when the jackpot is different are made different from each other so as not to be confused with each other. In other words, the lighting pattern of the effect lamp 541 that indicates that the setting change has been completed is set to a lighting pattern that is not used for other effects (or has an extremely low frequency of use), and if the lighting pattern is viewed, the setting is changed. It is preferable to make it understandable as a production that means the end of.
Further, for the effect lamp 541, the lighting pattern indicating that the setting change has been completed and the lighting pattern when the jackpot is the same may be made the same, but for the lamps other than the effect lamp 541, the setting change is made. The lighting pattern indicating the end may be different from the lighting pattern when the jackpot is achieved.
Specifically, for example, when it is indicated that the setting change is completed, the effect lamp 541 and the other lamps are all turned on, and when the jackpot is hit, the effect lamp 541 is turned on, but the other lamps are turned on. It is possible not to turn on. In this way, the administrator can know which state the player is in by checking the lighting patterns of the effect lamp 541 and the other lamps (lamps of the gaming machine in general).

Furthermore, when the effect lamp 541 is turned on as an effect indicating that the setting change has been completed, as a general rule, it is possible to output it at the same time as the setting change end sound. However, not limited to this, the lighting effect of the effect lamp 541 may be started before the setting change end sound is output. Alternatively, after the output of the setting change end sound is started and before the output of the setting change end sound is ended, the lighting effect of the effect lamp 541 may be started. Further, the lighting effect of the effect lamp 541 may be started after the output of the setting change end sound is ended.
In the nineteenth embodiment (B), at the same time when the setting change end sound is output, the effect lamp 541 that indicates that the setting change has ended is turned on.

Further, when the lighting time of the effect lamp 541 indicating that the setting change is completed is “T02” as in the nineteenth embodiment (A),
T01>T02
T01=T02
T01<T02
However, in this embodiment, “T01<T02” is satisfied. For example, when the time "T01" is set to about "2000" ms as described above, the time "T02" is set to, for example, about "2500" ms to about "4000" ms.

Next, a case where the game is started as soon as possible after ending the setting change state will be described.
In the present embodiment, it is assumed that the launch device 513 is operated so that the game ball cannot be launched into the game area during the setting change state. Therefore, at least, unless the setting key switch 535 is turned off, the game ball cannot be launched into the game area.

However, the present invention is not limited to this, and even when the setting is being changed, the launching device 513 may be operated to launch the game ball into the game area itself. In this case, it is possible to control not to pay out the prize balls even when the game balls are won in any of the winning openings during the setting change state. Even if the game ball wins the starting opening 532, the jackpot lottery is not executed, and the special symbol display device 531 is not changed or the decorative symbol is changed by the image display device 543. To be

In the setting change state, at least the front frame 502 is opened as described above, but first, a case will be described in which it is assumed that a game is possible even when the front frame 502 is opened.
And, as described above, the timing of starting the game is when the game ball wins the starting opening 532.
First, assuming that the preparation time before starting the game is "T21", the game ball is guided to the launchable position in the launcher 513, the game ball is launched from the launchable position, and the winning opening 532 is won. The total of the above times is the time “T21”.
In this case, the time "T21" is considered to be about "2000" ms.
In the above assumption, it is assumed that the first game ball of the game ball launched from the launching device 513 wins the starting opening 532.

When the game ball wins the starting opening 532, in FIG. 102, it is determined to be “Yes” in step S741, and then the special symbol starts changing (step S744), and after the special symbol changes for the determined change time, , The fluctuation of the special symbol is stopped (step S746). Here, in FIG. 102, the time from the determination of “Yes” in step S741 to the end of the process of step S746 is one game time, and this one game time is set to “T22”.
First, when a game ball is won in the starting opening 532 in a state where there is no holding ball, one game time "T22" is determined from a range of about "10000" to "30000" ms, for example. And Therefore, the shortest time of one game time "T22" is "10000" ms.

Note that, for example, when the number of holding balls becomes a predetermined number (for example, three) or more, a shortening function that improves time efficiency by shortening the variation time of the special symbol is known, but in the present embodiment, the setting is performed. Since it is the state after the end of the changed state, there is no holding ball. Therefore, in one game time "T22", the function of shortening the variation time of the special symbol is not considered.

As described above, the time required to start the game immediately after the setting change state is finished is "T21+T22".
Then, the shortest time of “T21+T22” is about “12000” ms.
Therefore,
T01 (time when the setting change end sound is output)<T21+T22 (preparation time for starting a game+1 shortest time for a game)
Becomes

Furthermore, even when the lighting indicating that the setting change has been completed by the effect lamp 541 is executed immediately after the end of the setting change state (when the setting change end sound is output), the lighting time T02 of the effect lamp 541 and “T21+T22”. The relationship with
T02 (about "2500" to "4000" ms) <T21+T22
Becomes
Thereby, even when the game is started immediately when the setting change state is ended, the output of the setting change end sound is ended and the effect lamp indicating the end of the setting change is ended before the end of one game. This means that the lighting of 541 has ended.
FIG. 96 shows the time relationship at this time.

Further, the above 1 game does not consider the time for closing the front frame 502 after the setting change state or the operation time for eliminating the frame open error after closing the front frame 502.
Similar to the slot machine 10, when the setting change state is completed, at least the front frame 502 should be in the open state. Therefore, even if the setting change state is ended, the pachinko gaming machine 500 detects the frame opening error and notifies the error. The game cannot be started when the frame opening error is reported. When the frame opening error occurs, firstly, the firing device 513 is not operated. Secondly, although the launching device 513 is in an operable state, even if a game ball is won in the starting opening 532 (even if the game ball is detected by the starting opening switch 533), the game is not started (lottery processing). Is not executed, fluctuation of the special symbol display device 531 is not started, and prize balls are not paid out).

To cancel the frame opening error, the front frame 502 is closed and the frame opening switch 523 is turned off. Further, by inserting a key into the key insertion opening 521 and performing a predetermined operation, the frame opening error is eliminated (error notification is ended). Therefore, the preparation time “T21” after the end of the setting change state until the game starts includes the operation time for closing the front frame 502, inserting the key, and canceling the frame opening error. After the end of the setting change state, by closing the front frame 502 and turning off the frame opening switch 523, the time until the frame opening error is resolved is “T20”.
T01 (output time of setting change end sound)<T20+T21+T22
T02 (lighting time of effect lamp 541)<T20+T21+T22
Becomes

In the above example, the example in which the setting change state is ended when the setting key switch 535 is turned off is shown, but the present invention is not limited to this, and the front frame 502 is closed (the frame opening switch 523 is turned off), It is also possible to end the setting change state on condition that the operation for canceling the frame opening error (the operation of inserting the key into the key insertion opening 521 and rotating it in a predetermined direction) is performed. In this case, the front frame 502 is closed, and at the end of the frame opening error cancellation operation, the setting change state ends, and the setting change end sound is output. The setting change state may be terminated by closing the front frame 502 on condition that the frame opening switch 523 is turned off (without performing a frame opening error cancellation operation). In this case, when the frame opening switch 523 is turned off, the setting change state is ended and a setting change end sound is output.

Therefore, even in the case where the setting change state ends when the front frame 502 is closed and the frame opening error is released, as described above, the time from the end of the setting change to the end of one game " Since the output time “T01” of the setting change end sound is shorter than “T21+T22”, the output of the setting change end sound is completed before the end of one game immediately after the end of the setting change.

The above is the case where one game time "T22" is finished in the shortest time.
On the other hand, not limited to this, the relationship between the output time “T01” of the setting change end sound and the time “T21+T22” from the end of the setting change to the end of one game can be variously set as follows. ..
(1) The output time "T01" of the setting change end sound is shorter than the total time of the average one game time "T22" when the big hit lottery is out (non-winning) and the preparation time "T21" Set.
For example, the variation time of the special symbol display device 531 when it is out of range is in the range of "T22 (min1)" to "T22 (max1)", and its average time is "T22 (avg1)",
T01<T21+T22 (avg1)
It can be set to.

(2) The output time “T01” of the setting change end sound is set shorter than the total time of the average one game time “T22” when the big hit is hit in the big hit lottery and the preparation time “T21”.
For example, the variation time of the special symbol display device 531 when the big hit is in the range of "T22 (min2)" to "T22 (max2)", and its average time is "T22 (avg2)",
T01<T21+T22 (avg2)
It can be set to.

<Twentieth Embodiment>
The twentieth embodiment relates to a board case of a control board.
As a substrate case for housing the control substrate, a double door type and a sliding type are known, but the twentieth embodiment is a sliding type substrate case.
The slide system has a smaller exposed area of the control board than the double-door system, and accordingly, the number of points for unauthorized access can be reduced.
In addition, the twentieth embodiment has a structure in which the upper case 560 and the lower case 570 slide while the main control board 530 is fixed to the upper case 560. Therefore, the surface of the main control board 530 exposed during the sliding movement is a solder surface.
The surface of the control board on which the CPU, the connector, and other electronic components are mounted is referred to as a "component surface", and the surface on which the legs of the electronic component are soldered is referred to as a "solder surface".

In the twentieth embodiment, the board case 550 for housing the main control board 530 in the pachinko gaming machine 500 is taken as an example. However, not limited to this, the board case 550 of the twentieth embodiment is not limited to the main control board 530 in the pachinko gaming machine 500, and is a control board on which a payout control board 520, a sub control board 540, and other CPUs are mounted. Therefore, it can be applied to a case that accommodates a control board that requires security.

Further, the board case 550 of the twentieth embodiment is not limited to the control board of the pachinko gaming machine 500, but is a control board on which the main control board 50 of the slot machine 10, the sub control board 80, and other CPUs are mounted, and security is ensured. The present invention can be applied to a case that accommodates a control board that requires
Specifically, the main control board 50 of the slot machine 10 is formed in the same or similar shape as the main control board 530 of the pachinko gaming machine 500, and the board case 550 (the upper case 560 and the lower case 570 of the twentieth embodiment is formed. ) Can be accommodated.
The board case 56 shown in the second embodiment (FIGS. 9 and 10) can be applied to the main control board 530 and other control boards of the pachinko gaming machine 500. Furthermore, the second embodiment and the twentieth embodiment may be carried out independently, but it is also possible to carry out the second embodiment and the twentieth embodiment at the same time.

FIG. 103 is an exploded perspective view of the board case 550 (the upper case 560 and the lower case 570) and the main control board 530 as seen from the front side. FIG. 104 is an exploded perspective view of the board case 550 (the upper case 560 and the lower case 570) and the main control board 530 as seen from the rear side.
Furthermore, FIG. 105 is an external perspective view of the state in which the main control board 530 is housed in the board case 550 as seen from the front side. Further, FIG. 106 is a front view of the main control board 530 accommodated in the board case 550 as seen from the front side. Further, FIG. 107 is a front view of the state where the main control board 530 is housed in the board case 550 as seen from the rear (back) side.

Here, the “front side” refers to the component side of the main control board 530, and the “rear (back) side” refers to the solder side of the main control board 530.
The “upper” in the “upper case 560” refers to the component side of the main control board 530, and may be referred to as a “front side case (or cover)” or “component side side case (or cover)”. ..
Furthermore, the "lower" in the "lower case 570" refers to the solder surface side of the main control board 530, and includes the "rear (back) side case (or cover)" and the "solder surface side case (or cover)". May be called.
Further, FIGS. 103 and 106 show a state in which the cover 561 is attached to the upper case 560, and FIG. 105 shows the upper case 560 excluding the cover 561.

As shown in FIG. 103, the main control board 530 includes the above-described setting change (reset) switch 536 and the setting key insertion port 534. Furthermore, connectors 539a to 539h for connecting a harness to another board, electronic component, or electronic device are provided. Various parts shown in the twentieth embodiment such as FIG. 103 are examples, and the present invention is not limited to these.
In addition, holes 530 a are formed at the four corners of the main control board 530 for screwing when the main control board 530 is attached (fixed) to the upper case 560.

On the other hand, in the upper case 560, as shown in FIGS. 103 and 104, the connectors 539a to 539h of the main control board 530, the setting change (reset) switch 536, and the setting key insertion port 534 have appropriate gaps. The openings 563a to 563i are formed so that they can pass through (pass through).
Further, in the upper case 560, a cover 561 is openably and closably attached to a portion where the setting change (reset) switch 536 and the setting key insertion opening 534 are exposed when the main control board 530 is attached. In the present embodiment, the opening/closing of the cover 561 is not detected by a sensor or the like, but the opening/closing of the cover 561 can be detected by a sensor. Then, it is possible to shift to the setting change state on the condition that the sensor is on (the cover 561 is in the open state), or set on the condition that the sensor is on (the cover 561 is in the open state). The changed state may be allowed to end.

Caulked portions 562 and 572 are provided on one end sides of the upper case 560 and the lower case 570, specifically, on the left edge when viewed from the front side in FIG. 103. The caulking portions 562 and 572 are used for sealing (caulking) the upper case 560 and the lower case 570 in a fitted state, respectively. After sealing (caulking), the fitting between the upper case 560 and the lower case 570 cannot be released unless the caulking portion 562 on the upper case 560 side is destroyed.
Furthermore, in FIG. 103, side walls 565 and 571 are provided at the ends opposite to the one end side (the side where the caulking portions 562 and 572 are provided, respectively) of the upper case 560 and the lower case 570 when viewed from the front side. Has been. These side walls 565 and 571 come into contact with each other when the upper case 560 and the lower case 570 are fitted together.

In FIG. 104, bosses 564 (four pieces) are provided on the back side of the upper case 560. In FIG. 104, two bosses 564 are visible. The arrangement interval of the four bosses 564 is the same as the arrangement interval of the four holes 530a of the main control board 530. Further, the boss 564 is formed with a screw hole.
When the main control board 530 is applied to the back side of the upper case 560 in the state shown in FIG. 104, the four holes 530a of the main control board 530 and the screw holes of the four bosses 564 of the upper case 560 overlap.

Further, in this state, the connector 539a of the main control board 530 penetrates the opening 563a of the upper case 560 and its connector surface is exposed to the front side of the upper case 560.
Similarly, the connectors 539b and 539c of the main control board 530 penetrate the opening 563b of the upper case 560 and their connector surfaces are exposed to the front side of the upper case 550.
Further, the connectors 539d, 539e, and 539f of the main control board 530 pass through the openings 563c, 563d, and 563e of the upper case 560, and their connector surfaces are exposed to the front side of the upper case 560.

Furthermore, the connectors 539g and 539h of the main control board 530 penetrate the openings 563f and 563g of the upper case 560, respectively, and their connector surfaces are exposed to the front side of the upper case 560.
In this way, all the connectors provided on the main control board 530 pass through the openings formed in the upper case 560 and are exposed to the front side of the upper case 560. 105 and 106 show the state at this time.
Further, in this case, the gaps between the connectors 539a to 539h and the openings 563a to 563g are set to be appropriate gaps, and the connectors 539a to 539h are arranged to open the openings 563a to 563a. 563g can be penetrated without resistance, and after the penetration, there should be no unnecessary gap between the connectors 539a to 539h and the openings 563a to 563g (for example, a gap between the connector and the opening). Is about 0.5 mm in design value). As a result, it is difficult to carry out the goto action by utilizing the gap between the connector and the opening.

Furthermore, the setting change (reset) switch 536 and the setting key insertion port 534 of the main control board 530 penetrate through the openings 563h and 563i formed in the upper case 560, respectively, and contact (access) from the front side of the upper case 560. ) Is possible (see FIG. 105), however, since the cover 561 is mounted on the setting change (reset) switch 536 and the setting key insertion port 534 as shown in FIGS. 103 and 106, the front side Not exposed to. However, the substrate case 550 (the upper case 560 and the lower case 570) including the cover 561 is made of transparent resin, and the setting change (reset) switch 536 and the setting key insertion port 534 can be visually confirmed from the outside of the cover 561. Has become.
In the above state, if screws are inserted from the solder surface side of the main control board 530 into the holes 530a (4 places) and screwed onto the bosses 564 of the upper case 560, the main control board 530 is fixed to the upper case 560. To be done.

Thereby, even when the upper case 560 and the lower case 570 are fitted together, the main control board 530 moves integrally with the upper case 560.
As described above, since the main control board 530 is fixed to the upper case 560 before the upper case 560 and the lower case 570 are fitted together, when the upper case and the lower case 570 are fitted together, There is no relative movement between the case 560 and the main control board 530. Therefore, on the upper case 560 side, openings 563a to 563g each slightly larger than the outer shapes of the connectors 539a to 539h of the main control board 530 are formed, and the connectors 539a to 539h penetrate the openings 563a to 563g. With such a structure, it is possible to obtain a structure in which an unnecessary gap is not formed between each connector 539a to 539h and each opening 563a to 563g. For example, even after the upper case 560 and the lower case 5670 are fitted to each other, even if the positional relationship between the upper case 560 and the lower case 570 is shifted by the goto action, the upper case 560 and the main control board 530 are Cannot be relatively displaced, so that it is not possible to increase the gap between the connectors 539a to 539h and the openings 563a to 563g, for example. As a result, it is possible to suppress goto actions.

Next, a method of fitting the upper case 560 to which the main control board 530 is attached and the lower case 570 will be described.
FIG. 108 is a side cross-sectional view showing a fitted state of the upper case 560 and the lower case 570, (a) shows a temporary fitted state (before sliding movement), and (b) shows a main fitted state ( (After slide movement).
In FIG. 108, the cross-sectional area is not hatched in consideration of the visibility of the drawing. Further, in the figure, the upper case 560 is shown by a solid line and the lower case 570 is shown by a two-dot chain line.
As shown in FIGS. 103, 104, and 108, the upper case 560 is provided with a side wall 565, and the lower case 570 is provided with a side wall 571.

Further, as shown in FIGS. 103, 104, and 108, the lower end edge (on the lower case 570 side) in the longitudinal direction of the upper case 560 is referred to as a lower edge 560a. The longitudinal edge of the lower case 570 is referred to as an outer edge 570a.
When the upper case 560 and the lower case 570 are overlapped with each other, the shapes of the upper case 560 and the lower case 570 are formed so as to overlap each other in the positional relationship shown in FIG. When the upper case 560 and the lower case 570 are overlapped with each other, the lower edge 560a of the upper case 560 and the outer edge 570a of the lower case 570 are formed in contact with each other. This position is called a "temporary fitting state". In the temporary fitting state, the gap L between the side wall 565 of the upper case 560 and the side wall 571 of the lower case 570 is formed to be about several tens of mm (for example, about “10” to “30” mm). ing.
Further, in the temporarily fitted state, the upper case 560 and the lower case 570 can be separated at any time. In other words, in the state shown in FIG. 108A, the upper case 560 can be moved with respect to the lower case 570 in the direction away from the lower case 570 without interference of parts or the like.

FIG. 109 is a plan view of the vicinity of the side wall 565 and the side wall 571 from the lower case 570 side in the temporary fitting state.
In the temporarily fitted state, as shown in FIG. 109, since the upper case 560 and the lower case 570 have a gap L, one end of the solder surface of the main control board 530 can be seen from this gap L. There is. Here, in the connector of the main control board 530, if the foot of the connector 539g is the connector foot 539g′ and the foot of the connector 539h is the connector foot 539h′, these connector feet 539g′ and 539h′ are respectively arranged in the longitudinal direction. It has two rows of legs (see Figure 104).
Then, in the temporary fitting state, as shown in FIG. 109, the connector legs 539g′ and 539h′ are formed so that only one row outside thereof is exposed. In other words, even in the temporarily fitted state, the connector legs 539g' and 539h' are not exposed, but only a part thereof is exposed.

The lower case 570 can be slid with respect to the upper case 560 from the temporarily fitted state of FIG. The sliding movement direction is the longitudinal direction of the substrate case 550, and is the leftward direction in FIG. 108(a).
When the lower case 570 is slid with respect to the upper case 560, the upper case 560, the main control board 530, and the lower case 570 can be moved to the end point of the sliding movement without interfering with each other. Then, as shown in FIG. 108(b), the side wall 565 of the upper case 560 and the side wall 571 of the lower case 570 can be slid to a position where they come into contact with each other. The state of FIG. 108(b) is the final fitting state. Note that FIG. 107 shows a state where the side wall 565 of the upper case 560 and the side wall 571 of the lower case 570 are in contact with each other (full fitting state).

When the main fitting state is achieved, the engaging members (not shown) formed on the upper case 560 and the lower case 570 respectively engage. This makes it impossible to move the upper case 560 relative to the lower case 570 in a direction away from the lower case 570. However, in this state, it is possible to slide the lower case 570 with respect to the upper case 560 in the opposite manner to the above, and the sliding movement in the opposite direction always returns the main fitting state to the temporary fitting state. be able to.

In the temporarily fitted state shown in FIG. 108(a), the caulking portion 562 of the upper case 560 and the caulking portion 572 of the lower case 570 are displaced in the vertical direction, but the book shown in FIG. In the fitted state, the caulking portion 562 of the upper case 560 and the caulking portion 572 of the lower case 570 overlap each other, and the caulking is possible using both. When the caulking portion 562 and the caulking portion 572 are caulked at this position, the main case 560 and the lower case 570 are separated or the upper case 560 is separated unless the caulking portion 562 of the upper case 560 is cut (destroyed) thereafter. On the other hand, it is impossible to slide the lower case 570 to return it to the temporary fitting state shown in FIG. 108(a).

However, it is conceivable that the lower case 570 is slid with respect to the upper case 560 by some method to return to the temporary fitting state and the soldering surface of the main control board 530 is exposed.
On the other hand, as shown in FIG. 109, if all the connector legs are not exposed and only a part of the connector legs are exposed, the goto action can be made difficult.
Further, not all connector legs are exposed even in the temporary mating state, and in the example of the twentieth embodiment, the exposed connector legs are the connector legs 539g′ and 539h′, and the other connector legs. The feet of 539a, 539b, 539c, 539d, 539e, and 539g are not exposed.

When the slide method is adopted for the substrate case 550, the sliding direction is usually the longitudinal direction of the substrate case. In this case, the amount of slide movement is related to the number of exposed legs of the connector.
In the present embodiment, as shown in FIG. 103, the connector is arranged near the outer peripheral edge of the main control board 530. For example, if the connector is provided at the center of the main control board 530, the opening of the upper case 560 corresponding to the connector is inevitably in the shape of a square with its four sides surrounded by side walls. However, if the connector is arranged inside the substantially square shape surrounded by side walls on four sides, it becomes difficult to insert and remove the connector. Therefore, in the present embodiment, as shown in FIG. 103, the connectors 539a to 539h are arranged near the outer peripheral edge of the main control board 530.

Specifically, in FIG. 103, the connector 539a is arranged near the left edge of the main control board 530, the connectors 539b, 539c, 539d, 539e, and 539f are arranged near the upper edge, and the connectors 539g and 539h are arranged near the right edge. Was placed.
Each of the connector opening portions 563 of the upper case 560 has a structure having no wall at least on the outer side. For example, as shown in FIG. 105, the periphery of the opening 563a through which the connector 539a penetrates has a substantially concave shape having no side wall on the left side (outside) in the figure.
Further, as shown in FIG. 105, the periphery of the opening 563b through which the connectors 539b and 539c are penetrated has a substantially concave shape having no side wall on the upper side (outer side) in the figure.

Furthermore, the peripheries of the openings 563c, 563d, and 563e through which the connectors 539d, 539e, and 539f respectively pass are substantially L-shaped with no side walls on the upper side and the right side (outer side) in FIG. ..
Further, as shown in FIG. 105, the peripheries of the openings 563f and 563g through which the connectors 539g and 539h respectively penetrate have a side wall only on the left side (inner side) in the figure. This makes the connector easy to insert and remove.

Furthermore, when the connectors are arranged on the main control board 530 as described above, when the lower case 570 is slid and moved as in the present embodiment, the legs of the connector exposed first are the ones of the connectors 539g and 539h. Feet (539g' and 539h').
Further, when the slide movement amount is set larger than that of the present embodiment, the foot of the connector 539f is exposed next.

Therefore, in the present embodiment, regarding the connectors 530a to 539f among the connectors of the main control board 530, even if the lower case 570 is slid with respect to the upper case 506, the legs of the connectors are not exposed. Note that, for example, in FIG. 105, if the connector group of the connectors 539d, 539e, and 539f is arranged so as to be closer to the left side in the figure (closer to the connectors 539b and 539c), the sliding movement amount becomes larger than that in the present embodiment. Even if provided, the legs of the connector 539f can be configured not to be exposed.

When the lower case 570 is slid with respect to the upper case 560 as in the present embodiment, the legs of the connectors 539g and 539h arranged near the right edge of the main control board 530 in FIG. 105 are easily exposed. .. Therefore, in the present embodiment, when the lower case 570 is slid with respect to the upper case 560, the legs of the connectors 539g and 539h (connector legs 539g′ and 539h′) are exposed, but It is structured so that the part of the legs is not exposed, but only part of the legs are exposed, so that the goto action becomes a little difficult.

It is preferable that the number of connectors in which at least a part of the feet is exposed by the sliding movement is as small as possible.
When the number of rows of legs of one connector is "N (N is an integer of 2 or more)", the number of exposed legs is "N-1" or less (that is, not all are exposed). Preferably. Furthermore, when the number of rows of legs of the connector is "1", it is preferable that the legs of the connector are not exposed.
Alternatively, when the number of pins of the connector is “N”, that is, when the number of legs of the connector is “N”, the “n”th pin (“n”≦“N−1”) of the “N” pins. It is possible to expose up to the “)-th pin, but not expose the “n+1”-th and subsequent pins (that is, configure not to expose all pins).
Further, among the pins of the connector, one reference pin may be at least not exposed. By not exposing at least one pin, it is possible to make the goto more difficult than when all the pins are exposed.

Further, when the main control board is the main control board 530 in the pachinko gaming machine 500, as shown in FIG. 99, the main control board 530 is a payout control board 520, a special symbol display device 531, a start opening switch 533, a sub Since it is electrically connected to the control board 540 and the like, it is connected to these boards and electronic parts. Connections are made using leads. Further, a plurality of lead wires are combined into one to form a harness, a connector terminal is attached to the end of the harness, and the connector terminal and the connector on the main control board 530 are connected.
Here, of the lead wires connected to the main control board 530, the lead wire for which security is to be particularly ensured is the lead wire to which the signal of the starting opening switch 533 (signal related to lottery) is input. Therefore, regarding the connector to which the signal of the starting port switch 533 is input, the connector foot is not exposed even if the connector is slid (at least one foot row is not exposed or at least one pin is not exposed). Is preferred.

Further, regarding the connector connected to the payout control board 520, the connector foot is not exposed even if the connector is slid and moved (at least one foot row is not exposed, or at least one pin is It is preferable that it is not exposed).
Further, a lead wire for supplying power to the main control board 530 (a lead wire connected to the power supply board 510 when the power supply board 510 and the main control board 530 are directly connected), a sub control board 540, Regarding each connector to which the connected lead wire and the lead wire connected to the board for outputting an external signal are respectively connected, at least one foot row is not exposed or at least one pin is not exposed. It is preferable to configure.

On the other hand, when the main control board is the main control board 50 in the slot machine 10, as shown in FIG. 1, the main control board 50 includes a medal selector, various operation switches, a power switch 11, a medal number display device, and a symbol. The display device and the medal payout device are electrically connected.
Among the lead wires connected to the main control board 50, the lead wire for which security is to be particularly ensured is the lead wire to which the signal of the start switch 41 (the signal related to the lottery) is input. Therefore, regarding the connector to which the lead wire to which the signal of the start switch 41 is input is connected, the connector foot is not exposed even if the connector is slid (at least one foot row is not exposed or at least one pin is not exposed). It is preferable to configure as follows.

Furthermore, the lead wire to which the signal of the closing sensor 44 is input also needs security from the viewpoint of preventing credit got. Therefore, with respect to the connector to which the lead wire to which the signal of the closing sensor 44 is input is connected, the connector foot is not exposed even if the connector is slid (at least one foot row is not exposed or at least one pin is not exposed). It is preferable that it is not exposed).

Further, each lead wire connected to the medal payout device, specifically, a lead wire for outputting a drive signal of the hopper motor 36 and a lead wire to which a signal from the payout sensor 37 is input are connected. Also, from the viewpoint of preventing payout, it is preferable that the connector foot is not exposed even if it is slid (at least one foot row is not exposed or at least one pin is not exposed). ..
In addition, as in the case of the Pachinko gaming machine 500, a connector having a lead wire relating to a power source, a connector having a lead wire connected to the sub-control board 80, and a lead connected to a board for transmitting an external signal. Also for each connector to which the wires are respectively connected, it is preferable that at least one foot row is not exposed or at least one pin is not exposed.

<Twenty-first embodiment>
The twenty-first embodiment relates to the thickness (diameter) of the lead wire (also referred to as “signal wire”).
In the twenty-first embodiment, the lead wire for starting is made thinnest, and at least one or more other lead wires having the same thickness as the lead wire for starting are provided in one connector terminal having the lead wire for starting. Also, by providing at least one lead wire that is thicker than the lead wire for starting, it is difficult to identify the lead wire for starting, and it is possible to suppress goto actions (illegal starting or starting at an intentional timing). To do.

Here, in the pachinko gaming machine 500, the lead wire for starting corresponds to the lead wire that connects the starting opening switch 533 and the main control board 530.
Further, in the slot machine 10, the lead wire for starting corresponds to the lead wire that connects the start switch 41 and the main control board 50.
The "lead wire for starting" is actually composed of two wires, one of which serves as a starting signal wire and the other one serves as a GND wire. Further, in the present embodiment, the start signal line is referred to as a “lead wire related to start” and does not include the GND line. However, the GND wire may be included in the lead wires other than the lead wire for starting.

FIG. 110 is a plan view showing a state where the harnesses B to H are connected to the connectors 539b to 539h of the main control board 530, respectively.
In addition, in FIG. 110, the illustration of the substrate case 550 is omitted. Further, in FIG. 110, the main control board 530 is illustrated, but the invention is not limited to the main control board 530 and can be applied to the main control board 50. In other words, the twenty-first embodiment can be applied to both the slot machine 10 and the pachinko gaming machine 500.
Moreover, the connector terminals respectively attached to the tips of the harnesses B to H are referred to as “harness B connector terminals” to “harness H connector terminals”, respectively.

The connector 539a is usually a connector to which a cable or the like is not connected. The connector 539a is a connector that is connected to the matching device when the gaming machine enforcement authority checks the data stored in the CPU, ROM, and RWM using the matching device.
Further, the connectors 539b to 539h are concave connectors mounted on the main control board 530, and these are connected to the harness B connector terminal to the harness H connector terminal (convex connector), respectively.
Further, FIG. 111 is a front view showing in detail each harness B to H and the harness B to H connector terminals.
Each of the harnesses B to H is composed of a plurality of lead wires, and each lead wire is numbered in FIG. 111. For example, the harness B is composed of nine lead wires 1 to 9 in the first row (upper row in the drawing) and nine lead wires 10 to 18 in the second row (lower row in the drawing) in the drawing. It is a harness.

Each connector terminal of the harnesses B, C, D, G, and H is composed of two rows. On the other hand, each connector terminal of the harnesses E and F is composed of one row.
The harnesses and connector terminals shown in FIG. 111 are merely examples, and the connector terminals may be composed of, for example, three rows or more. The number of lead wires in one row is determined according to the application (the number of signal wires), and is not limited to that shown in FIG. 111, and may be one or 10 or more. ..
Even if it is composed of one lead wire, it will be referred to as a "harness".
Furthermore, in addition to a harness in which each lead wire is separated (whether or not it is bound), specifically, a harness such as a discrete wire cable, for example, a flat cable or a ribbon cable, Includes all lead wires integrally connected (whether separable or not).

Also, in FIG. 111, two types of thickness are illustrated as the lead wire. In the figure, the lead wire indicated by a single circle indicates a thin lead wire, and the lead wire indicated by a double circle indicates a thick lead wire. Here, the "lead wire thickness" refers to the diameter of the lead wire. Therefore, if the thickness of the lead wire indicated by a single circle is the diameter D1 and the thickness of the lead wire indicated by the double circle is the diameter D2, then "D1<D2".
In the example of FIG. 111, two types of lead wire thickness are shown, but the present invention is not limited to this, and a harness may be configured from lead wires of three or more types of thickness.

In FIG. 111, a lead wire for starting (in the case of the Pachinko gaming machine 500, a lead wire that connects the starting opening switch 533 and the main control board 530. In the case of the slot machine 10, the start switch 41 and the main control board 50. It is assumed that the lead wire for connecting to and is the seventh lead wire of the harness D. The lead wire for starting uses a thin lead wire of two types of thickness. This is because the thin lead wire makes the lead wire for starting as inconspicuous as possible. Also, by using a thin lead wire, it is easy to break the wire when a fraudulent act (modification, etc.) is performed, so that the abnormality can be easily found. In other words, a thick lead wire is less likely to be broken even if a fraudulent act is performed, as compared with a thin lead wire. This is because it is difficult.
However, the lead wire for starting is not limited to this, and may be a thick lead wire. Alternatively, when using lead wires of three different thicknesses, a lead wire of intermediate thickness may be used as the lead wire for starting.
In some cases, only two wires, the lead wire for starting and the GND wire, are connected to one connector terminal.
On the other hand, the harness D shown in FIG. 111 has a plurality of other lead wires in addition to the lead wire (No. 7) for starting.

Further, in the harness D including the lead wire (No. 7) for starting, at least one lead wire having the same thickness as the lead wire (No. 7) for starting is provided. Even if it is known that the lead wire for starting is included in the connector D, it is difficult to identify which lead wire (it is difficult to carry out the goto action). In this example, the second, fourth, and eighth lead wires have the same thickness as the seventh lead wire (lead wire for starting).

Furthermore, the 8th lead wire having the same thickness is arranged adjacent to the 7th lead wire of the harness D. This is because it is difficult to identify the lead wire relating to the start by disposing the lead wire having the same thickness adjacent to the lead wire relating to the start. In addition, in the example of FIG. 111, the 8th lead wire located on the right side of the 7th lead wire in the harness D has the same thickness as the 7th lead wire. The thickness of the wire may be the same as the thickness of the 7th lead wire. Alternatively, the thickness of the third lead wire may be the thickness of the seventh lead wire. In the harness D, the lead wires “adjacent” to the lead wire No. 7 correspond to the lead wires No. 3, 6, and 8 in the example of FIG. At least one of these lead wires is set to have the same thickness as the No. 7 lead wire.

Further, the harness D is provided with one or more lead wires having a different thickness from the lead wire (No. 7) for starting. In the example of FIG. 111, the lead wires of Nos. 1, 3, 5, and 6 have different thicknesses from the lead wire (No. 7) for starting. By including a lead wire having a thickness different from the thickness of the lead wire for starting in one connector terminal (harness D connector terminal), the lead wire for starting can be more difficult to specify.

Also, in addition to the lead wire for starting, important signal wires, specifically, lead wire for loading game media, lead wire for payout, lead wire for transmitting external signals, etc. are also prevented From the viewpoint of, in the same manner as the lead wire for starting, one or more other signal lines having the same thickness and one or more other signal lines having other thicknesses are provided in one connector terminal. Preferably.
Furthermore, it is preferable that the lead wire for starting and the lead wire for the power supply are arranged so as not to be adjacent to each other. This is because the lead wire for starting is less susceptible to noise.
Here, “not adjacent” means that, for example, when the 7th lead wire of the harness D is a lead wire for starting, the 3rd, 6th and 8th wires of the harness D are not set as the lead wires for the power source. It can be mentioned.

If the harness G connector terminal and the harness H connector terminal are linearly arranged on the main control board 530 and the distance between both connector terminals is short, as in the present embodiment, the harness G number 5 is used. When the lead wire of No. 1 is set as the lead wire for starting, it is preferable not to set the No. 1 lead wire of the harness H as the lead wire for power supply.
On the other hand, even when the harness G connector terminal and the harness H connector terminal are arranged in a straight line on the main control board 530, the fifth lead of the harness G is provided if there is a certain distance between both connector terminals. It does not matter if the wire is set as the lead wire for starting and the first lead wire of the harness H is set as the power lead wire.

Furthermore, when the connector terminal of the harness including the lead wire for starting is adjacent to the connector terminal of the other harness, the harness including the lead wire for starting is arranged below the other harness to It is preferable to wire so that the lead wire for H.
FIG. 112 is a perspective view showing an example of hiding the lead wire for starting. In FIG. 112, for simplification of the drawing, both the harness D and the harness E are made up of one row of lead wires, the harness D is made up of three lead wires, and the harness E is made up of five lead wires. Illustrated. Then, in the harness D, the lead wire closest to the harness E is set as the lead wire for starting.
In this case, the direction in which the harness D extends is on the side of the harness E, and the wiring is so arranged that the harness E passes above the harness D. As a result, the lead wire for starting the harness D can be hidden from the outside as much as possible, and the security can be improved.

<Twenty-second Embodiment>
The twenty-second embodiment relates to the setting change state. The description of the twenty-second embodiment partially overlaps with that of the nineteenth embodiment, but will be described again.
First, in the case of the slot machine 10, before shifting to the setting change state, whether the door switch 17 is ON, whether the setting key switch 152 is ON, and whether the reset switch 153 is ON. Then, it is possible to shift to the setting change state on condition that all of these switches are on. When only some of the three switches are on or when all of the switches are off, the setting change state is not entered. As a result, even if the setting key switch 152 is accessed by illegally making a hole in the front door 12 with a drill or the like, the setting change state will not be entered unless the door switch 17 is turned on.

Further, even if all of the door switch 17, the setting key switch 152, and the reset switch 153 are turned on after the power is turned on, the setting change state is not entered. When the setting key switch 152 is turned on after the power is turned on, the setting confirmation state can be entered. In the setting confirmation state, the current setting value can be confirmed, but the setting value cannot be changed. In addition, when shifting to the setting confirmation state, the door switch 17 may be turned on. Furthermore, when shifting to the setting confirmation state, the reset switch 153 may be turned off.

Furthermore, the ending condition of the setting change state is set that the setting key switch 152 is turned off and the door switch 17 is turned on. As a result, it is possible to eliminate a state where the door switch 17 is off, that is, the setting change state ends in a state where the front door 12 is not opened (state in which there is a high possibility of goto action).
Here, in the present embodiment, it is possible to shift to the setting change state on the condition that the door switch 17 is on, and to end the setting change state on the condition that the door switch 17 is on.
However, not limited to this, firstly, it is possible to shift to the setting change state on condition that the door switch 17 is on, and do not judge the on/off state of the door switch 17 at the end of the setting change state. May be.

Secondly, when the setting change state is entered, on/off of the door switch 17 is not judged, but when the setting change state is ended, it is judged whether the door switch 17 is on/off, and if the door switch 17 is not on. The setting change state may not be terminated.
Furthermore, thirdly, whether or not the door switch 17 is turned on or off is not judged when shifting to the setting change state, but if the door switch 17 is not on, the setting value will not be changed even if the setting change switch 153 is operated. It may be set to.
Further, fourthly, the setting value can be changed by not judging whether the door switch 17 is turned on or off when shifting to the setting change state and operating the setting change switch 153 during the setting change state. When the door switch 17 is not turned on when the start switch 41, which is an operation for fixing the value, is operated, the setting value may not be fixed (a new setting value is not stored in the RWM 53). ..

Further, in order to shift to the setting change state in the slot machine 10, since the power is turned on while the reset switch 153 is turned on, before shifting to the setting change state (setting change processing) or the setting change state. The current set value stored in the RWM 53 is cleared before the set value can be changed after shifting to (setting change processing). In this case, the set value data is "0". Therefore, the set value at the start of the setting change state is "1".

In addition, when the reset switch 153 is turned on and the power switch 11 is turned on in order to shift to the setting change state, the information displayed on the management information display LED 73 (role ratio monitor) in the storage area of the RWM 53 is displayed. Such data is not cleared. The data related to the information displayed on the management information display LED 73 is a game number counter, a payout number counter (including a ring buffer), each ratio data, and the like.

In the case of the pachinko gaming machine 500, when the power is turned on, whether the frame opening switch 523 is on, whether the setting key switch 535 is on, and whether the reset switch 536 is on. Is determined, and it is possible to shift to the setting change state on condition that these three switches are on. When only some of the three switches are on or when all the switches are off, the setting change state is not entered. As a result, in the illegal state in which the front frame 502 is not open, even if the setting key switch 535 is turned on, the setting change state is not entered.

In particular, as shown in FIG. 98, the back side of the pachinko gaming machine 500 is not in a closed state (see FIG. 22) like the slot machine 10 but is in an open state.
Therefore, depending on the situation of the islands installed in the hall, it may be possible that the main control board 530 is accessed without opening the front frame 502 by going around the back side of the pachinko gaming machine 500. However, if the frame opening switch 523 is not on, it is determined that the state is not normal, and the state is not shifted to the setting change state (setting value cannot be changed).

Even if the frame opening switch 523 is turned on, the setting key switch 535 is turned on, and the reset switch 536 is turned on after the power is turned on, the setting change state is not entered. Furthermore, even if the setting key is inserted into the setting key insertion slot 534 after the power is turned on and the setting key switch 535 is turned on, the setting change state is not entered and the setting confirmation state is also entered. do not do.
In the case of the Pachinko gaming machine 500, as described above, when the power is turned on while the setting key is inserted into the setting key insertion port 534 and the setting key switch 535 is turned on (the reset switch 536 is in the off state). , It is possible to shift to the setting confirmation state.

Further, in the case where the opening of the front frame 502 and the opening of the glass door 505 can be individually detected as in this embodiment, when both the front frame 502 and the glass door 505 are open at the same time (that is, the door is open). When the opening switch 522 is on and the frame opening switch 523 is on, the specification may be such that the transition to the setting change state or the setting confirmation state is permitted.
By setting in this way, it becomes possible to inspect the function of the set value in the manufacturing process of the pachinko gaming machine 500 without performing an extra procedure. Further, after the pachinko gaming machine 500 is installed in the hall, even if the glass door 505 is removed from the pachinko gaming machine 500 during the board surface maintenance work in the hall, the setting change and the setting confirmation can be performed in parallel with the board surface maintenance. Therefore, the convenience can be improved.

Further, the door opening switch 522 (switch that is turned on when the glass door 505 is opened) is not detected when shifting to the setting change state or the setting confirmation state. Therefore, when shifting to the setting change state or the setting confirmation state, the glass door 505 may be either open or closed. However, it is determined that the glass door 505 is closed when shifting to the setting change state or the setting confirmation state, and it is determined that the door opening switch 522 is on/off when shifting to the setting change state or the setting confirmation state and is off. On the condition of, the condition may be changed to the setting change state or the setting confirmation state.

Furthermore, as shown in FIGS. 103 and 106, the setting key insertion port 534 and the setting change (reset) switch 536 are covered with a cover 561. Then, in order to insert the setting key into the setting key insertion opening 534, it is necessary to open the cover 561.
Therefore, a sensor that detects opening/closing of the cover 561 (hereinafter referred to as “cover sensor”) may be provided so that the setting change state or the setting confirmation state can be set on condition that the cover sensor is on.

In the pachinko gaming machine 500, in the setting change state, the setting value can be changed each time the setting change switch 536 is operated, which is common to the slot machine 10.
Further, in the slot machine 10, the operation of the start switch 41 is an operation of fixing the set value, but in the case of the Pachinko gaming machine 500, turning off the setting key switch 535 makes the set value fixed, and , This is an operation for ending the setting change state.
Further, in the case of the pachinko gaming machine 500, the setting change state can be terminated on condition that the setting key switch 535 is turned on and the frame opening switch 523 is turned on. As a result, it is possible to eliminate a state in which the frame opening switch 523 is turned off, that is, the setting change state ends in a state in which the front frame 502 is not opened (state in which there is a high possibility of goto action).

In this embodiment, the setting change state can be set on condition that the frame opening switch 523 is on, and the setting change state can be ended on condition that the frame opening switch 523 is on.
However, the present invention is not limited to this. Firstly, it is possible to shift to the setting change state on condition that the frame opening switch 523 is on, and do not judge the on/off state of the frame opening switch 523 when the setting changing state ends. You may

Secondly, when the setting change state is entered, whether the frame opening switch 523 is turned on or off is not judged, but when the setting change state is ended, the frame opening switch 523 is turned on or off and the frame opening switch 523 is turned on. Otherwise, the setting change state may not be terminated.
Furthermore, thirdly, when shifting to the setting change state, whether the frame opening switch 523 is turned on or off is not judged, but if the frame opening switch 523 is not on, the setting value is changed even if the setting changing switch 536 is operated. It may be set not to be performed.

Further, fourthly, the setting value can be changed by operating the setting change switch 536 while not judging whether the frame opening switch 523 is turned on or off when shifting to the setting change state. When the setting key switch 535, which is an operation for confirming the set value, is turned off, the set value will not be confirmed unless the frame opening switch 523 is turned on (a new set value is not stored in the RWM). You may set it.

Further, in the case of the Pachinko gaming machine 500, even if the power is turned on while the reset switch 536 is turned on in order to shift to the setting change state, the management information display LED (performance) in the storage area of the RWM is displayed. The data related to the information displayed on the display monitor) 538 is not cleared. The data related to the information displayed on the management information display LED 538 is a base value.

Furthermore, it is preferable that the setting key insertion port 534 and the setting change (reset) switch 536 are provided on the back surface side of the front frame 502 near the hinge mechanism 503. By doing so, it is possible to prevent the setting key insertion opening 534 and the setting change (reset) switch 536 from being easily accessed by simply opening the front frame 502.
For example, in FIG. 98, the setting key insertion opening 534 and the setting change (reset) switch 536 are arranged inside the cover 561, but when the main control board 530 is viewed from the front, the setting key insertion opening 534 and the setting The change (reset) switch 536 is arranged on the right side in the area of the main control board 530. Accordingly, the setting key insertion port 534 and the setting change (reset) switch 536 can be arranged near the hinge mechanism 503. In FIG. 98, the left side is the open side in the figure, so if formed as in FIG. 98, the setting key insertion port 534 and the setting change (reset) switch 536 are located at a position far from the open side (left side in the figure). Can be placed.

In the slot machine 10 as well, in the same manner as above, the setting key insertion opening 151 and the setting change (reset) switch 153 on the main control board 50 are rotated when the front door 12 is opened. It is preferable to arrange them so that they are closer to each other. For example, when the main control board 50 is arranged as shown in FIG. 22 and the front door 12 is viewed from the front side (player) side, the left side is the rotation axis side of the front door 12 and the right side is the open side, the front When the main control board 50 is viewed with the door 12 opened, it looks like FIG. Therefore, if the setting key insertion opening 151 and the setting change (reset) switch 153 are arranged on the left side in FIG. 10A, the setting key insertion opening 151 and the setting change (reset) are located at a position far from the opening side of the front door 12. The switch 153 can be arranged.

Furthermore, as a measure for making it difficult to shift to the setting change state due to goto, for example, in the Pachinko gaming machine 500, after inserting the setting key into the setting key insertion port 534, rotating the setting key counterclockwise. Then, the setting key switch 535 may be turned on. In this case, if the setting key is configured to be rotatable in the clockwise direction and the setting key is not moved to the setting change state when the setting key is rotated in the clockwise direction, it is difficult to understand the transition to the setting change state. be able to.
In particular, when the front frame 502 is opened by inserting a key into the key insertion opening 521, the front frame 502 can be opened by rotating the key clockwise. The rotation direction of the key and the rotation direction of the setting key are opposite to each other, which makes it difficult to understand the transition to the setting change state.

The same applies to the slot machine 10.
After the setting key is inserted into the setting key insertion port 151, the setting key switch 152 may be turned on by rotating the setting key counterclockwise. In this case, if the setting key is configured to be rotatable in the clockwise direction and the setting key is not moved to the setting change state when the setting key is rotated in the clockwise direction, it is difficult to understand the transition to the setting change state. be able to.
Particularly, when the front door 12 is opened by rotating the key clockwise when the front door 12 is opened, the rotation direction of the key when the front door 12 is opened and the rotation direction of the setting key are set. Since and are opposite directions, the transition to the setting change state can be made difficult to understand.

FIG. 113 is a side sectional view showing the positional relationship among the upper case 560 of the substrate case 550, the cover 561, the setting key insertion opening 534, and the setting change (reset) switch 536. Note that, in FIG. 113, as in FIG. 108, the cross-section is not hatched for the sake of easy viewing of the drawing.
As shown in FIGS. 105 and 113, among the surfaces of the upper case 560, the highest surface is the surface S1, and the opening surfaces of the setting key insertion port 534 and the setting change (reset) switch 536 are the surfaces S2. In this case, the surface S2 is formed lower than the surface S1. By forming in this way, when an attempt is made to access the setting key insertion opening 534 or the setting change (reset) switch 536 by inserting a wire-like object from the outside, for example, the surface S1 is accessed rather than the surface S1. It is more difficult to access S2. Therefore, it is possible to suppress the set goto action.

Further, as shown in FIGS. 103 and 113, when the cover 561 is attached to the upper surfaces of the setting key insertion port 534 and the setting change (reset) switch 536, the surface S3 (FIG. 113) which is the upper surface of the cover 561 is , And is arranged at a position lower than the surface S1 of the upper cover 560.
With such a structure, when an attempt is made to access the setting key insertion opening 534 or the setting change (reset) switch 536, a wire-like object is inserted between the upper cover 560 and the cover 561 or the cover is inserted. Even if an attempt is made to open 561, it is possible to make those actions difficult, and thus it is possible to suppress the setting action.

Although the nineteenth to twenty-second embodiments have been described above, these embodiments are not limited to the contents described above, and various modifications such as the following are possible.
A. Nineteenth Embodiment (1) In the nineteenth embodiment, a setting confirmation end sound when the setting confirmation state is ended may be output. For example, it may be possible to output the voice "Confirm setting is completed."
Furthermore, if the game starts at the same time as the setting confirmation state ends,
a) The output of the setting confirmation end sound is finished before the end of the game when the game is finished in the shortest time.
b) The output of the setting confirmation end sound is ended before the end of the game when the game is ended in the average time of one game.
c) Before the end of the game when the game is finished in the average time of one game in the special winning game (in the case of slot machine 10) or the jackpot (in the case of Pachinko gaming machine 500) , Output the setting confirmation end sound.
It can be cited as follows.

(2) Further, at the same time as the end of the setting confirmation state, the effect lamp 21 (in the case of the slot machine 10) or the effect lamp 541 (in the case of the Pachinko gaming machine 500) outputs an effect indicating that the setting confirmation state is ended. May be. Also in this case, as in the nineteenth embodiment, the effect time by the lamp is
a) The lamp effect is finished before the end of the game when the game is finished in the shortest time.
b) The lamp effect is ended before the end of the game when the game is ended in the average time of one game.
c) Before the end of the game when the game is finished in the average time of one game in the special winning game (in the case of the slot machine 10) or the big win (in the case of the Pachinko gaming machine 500) , Lamp production ends.
There are such things.

(3) When the setting change state is ended (or when the setting confirmation state is ended as in the above example), the setting change (or confirmation) end sound and the lamp effect are output. The (or confirmation) end sound and lamp effect are controlled by the sub control board 80 or 540.
However, not limited to this, when ending the setting change (or confirmation) state, an output indicating that the setting change (or confirmation) state is ended is executed by the output device controlled by the main control board 50 or 530. You may.

(4) In the slot machine 10, the setting key insertion port 151 (setting key switch 152) and the setting change (reset) switch 153 are provided on the main control board 50, but the present invention is not limited to this, and is separate from the main control board 50. Alternatively, a setting change board may be provided, and the setting key insertion port 151 (setting key switch 152), the setting change (reset) switch 153, and the set value display LED 73 may be provided on the setting change board.
The same applies to the pachinko gaming machine 500. A setting change board is provided separately from the main control board 530, and a setting key insertion opening 534 (setting key switch 535), a setting change (reset) switch 536, and a set value display LED 537 are provided on the setting change board. Good.

(5) As an example of outputting the sound "End setting change" as the setting change end sound, it is not necessarily limited to this wording. For example, "Setting value is updated" etc. It may be.
(6) In the nineteenth embodiment, an example is shown in which the game is started immediately after the end of the setting change state, but it is assumed that the game is started immediately after the end of the setting change state during actual hall business. I haven't. For example, it is assumed that the hall manager tries to digest one game after changing the settings. In such a case, while confirming that the setting change state has been correctly ended by the setting change end sound and the output of the effect lamp, do not confuse the notification by the setting change end sound and the effect lamp with the effect output in the game. One of the goals is to

B. Twentieth Embodiment (1) In the twentieth embodiment, the lower edge 560a of the upper case 560 and the outer edge 570a of the lower case 570 are brought into contact with each other to be slidable. However, there are various methods for engaging the upper case 560 and the lower case 570 before the sliding movement, and the engaging method is not limited to that shown in FIG. 108. Further, the upper case 560 and the lower case 570 may have a shape that allows them to overlap with each other with a certain degree of freedom when they are overlapped. Alternatively, the upper case 560 and the lower case 570 may have a shape that overlaps only at a specific position.

(2) How to arrange the connectors 539a to 539h on the main control board 530, and which connector foot is set to be exposed when the upper case 560 and the lower case 570 are temporarily fitted together. , And various methods.
When the upper case 560 and the lower case 570 are slid as in this embodiment, the first exposed legs of the connector are the connector legs 539g′ and 539h′, as shown in FIG. 109. Therefore, in the case of the connector 539a provided on the main control board 530 at a position symmetrical to the connectors 539g and 539h, the connector foot is not exposed even if the slide movement amount increases.

Therefore, for example, on the main control board 530, from the connector 539a side (left side in the figure) in FIG. 103, a connector important in terms of security (a connector having a signal line for starting, a signal for receiving and paying out a game medium) A connector having a line, a connector having a signal line relating to the output of an external signal, and a connector having a signal line relating to performance) are sequentially arranged, and the connector of the signal line which is not so important in terms of security is adopted as the connectors 539g and 539h. It can be mentioned.

(3) Although the substrate case 550 has the caulking portions 562 and 572 as an example, the present embodiment can be applied to a substrate case 550 having no caulking portion. For example, the board case that houses the sub-control board 540 of the pachinko gaming machine 500 may not have the caulking portion, but the 20th embodiment can be applied to such a board case.

C. Twenty-first Embodiment (1) The types and the number of connectors and the types and the numbers of harnesses (connector terminals) shown in the above embodiments are examples, and the present invention is not limited to these.
For example, in FIG. 111, the harnesses B and C may all be composed of thick lead wires, or all of them may be composed of thin lead wires.
Further, although the harness E shows an example in which only the thin lead wires are in one row, it may be a harness and a connector terminal in which the thin lead wires are arranged in two or more rows.
Furthermore, the harness and connector terminals may be in any number of rows, and the number of lead wires (terminals) in one row may be any number.
Furthermore, in a harness in which a thick lead wire and a thin lead wire are mixed in one row, the number of thick lead wires in the row may be one or more, and the number of thin lead wires may be one or more.

(2) In this embodiment, as shown in FIG. 110, a set of lead wires connected to one connector of the main control board 530 is defined as “one harness”.
For example, the harness G connected to the connector 539g is one harness, and the harness H connected to the connector 539h is one harness. When the harness G and the harness H are bundled into one at the end, it is referred to as a "harness group" and not as "one harness".

(3) When the main control board 530 and another board are connected by a harness, a specific connector is mounted on the main control board 530, and a harness of N lead wires is attached to the specific connector. Assume that the connector terminals are connected.
On the other hand, at the other end of the harness, N lead wires are divided into Nx lead wires (Nx≧1) and Ny lead wires (Ny≧1), and the connector terminals X are attached to the tips of the Nx lead wires, The connector terminal X is connected to another board, and a connector terminal Y (≠connector terminal X) is attached to the tip of Ny lead wires, and the connector terminal Y is connected to another board (Nx lead wires). It is assumed that the wire is connected to the same board as the board to which the wire is connected or a different board).
In this case, “one harness” in the present embodiment refers to a set of N lead wires connected to the main control board 530 side.

D. Twenty-second Embodiment (1) In the pachinko gaming machine 500, it is possible to shift to the setting change state or the setting confirmation state when the power is turned on. However, like the slot machine 10, after turning on the power, the setting key switch 535 is turned on. It may be possible to shift to the setting confirmation state with. Also in this case, it is possible to judge whether or not the frame opening switch 523 is on, and shift to the setting confirmation state on condition that it is on.

(2) As described above, it is conceivable that a setting change board is provided separately from the main control board 50 or 530. In this case, in the case of the slot machine 10, the setting is changed to the open shaft side (close to the open shaft) of the front door 12 inside the housing, in other words, to the side away from the open end when viewed from the player side. It is preferable to arrange the substrate. Similarly, in the case of the pachinko gaming machine 500, it is set on the back side of the front frame 502 on the hinge mechanism 503 side (close to the hinge mechanism 503), in other words, on the side away from the open end when viewed from the player side. It is preferable to place a modified substrate. With this arrangement, the setting key insertion ports 151, 534 and the setting change (reset) switches 153, 536 can be arranged at positions far from the open end. Even in this case, it is preferable that the main control board 50 or 530 is arranged at a position far from the open end.

Particularly, the management information display LEDs 74 or 538 are mounted on the main control board 50 or 530, respectively, but it is preferable that the information displayed by the management information display LEDs 74 or 538 is not easily visible. Therefore, it is preferable that the management information display LED 74 or 538 on the main control board 50 or 530 is arranged at a position away from the open side, and the main control board 50 or 530 is also arranged at a position away from the open end.
However, the information displayed by the management information display LED 74 or 538 is not easily seen only by disposing the management information display LED 74 or 538 on the main control board 50 or 530, respectively, at a position away from the open side. Is also possible. Similarly, even when the management information display LEDs 74 or 538 are mounted at the substantially central position of the main control board 50 or 530, respectively, the management information can be provided only by disposing the main control board 50 or 530 at a position away from the open end. It is also possible that the information displayed by the display LEDs 74 or 538 is not easily visible.

E. All of the embodiments and various modifications described in the present specification including the nineteenth to twenty-second embodiments are not limited to be implemented alone, but may be implemented in appropriate combinations.

<Twenty-third embodiment>
Next, a twenty-third embodiment will be described.
The meanings of the terms in the twenty-third embodiment are as follows.
"RT" means that the type (number) of the winning combination and the winning probability thereof are in a unique drawing state, and "RT transition" means transition from one RT to another RT. This means that the winning probability of at least one replay targeted for the lottery changes. Therefore, the type of replay and the winning probability thereof in one RT are values unique to that RT, and the type of replay and the winning probability thereof are the same in one RT and another RT. Absent. However, the total value of the winning probabilities of replay may be the same in one RT and another RT.

In the present embodiment, the RT includes a non-RT and an RT1 as shown in FIG. 131 described later.
Note that “non-RT” does not mean that it is not included in the concept of RT, and is equivalent to “RT0”. Therefore, the term “RT” used herein includes non-RT.
Further, in the present embodiment, as a special game (feature object operating state), 1BB game (1BB operating state), and RB game (RB operating state) are provided. Strictly speaking, the 1BB game (1BB operating state) and the RB game (RB operating state) are not included in RT, but may be one of RT.

The RB of the present embodiment is a role that is drawn during a general game of the 1BB game (meaning a game other than the RB game), and when the RB is won during the general game of the 1BB game and the RB wins. During the 1BB game, the normal game shifts to the RB game. Therefore, the RB selected in the normal game of the 1BB game is also referred to as "SRB (shift RB)".

Furthermore, it is a concept different from RT, and has a main game state in which the transition is controlled by the main control board 50 similarly to RT. The main game state of the present embodiment includes main game states 0 to 5, as shown in FIG. 132 described later.
The RT and the main game state have cases in which they are linked and cases in which they are not linked. For example, when the transition conditions for both the RT and main game states are met, both the RT and main game states are transitioned. On the other hand, when the transition condition of RT is satisfied but the transition condition of the main gaming state is not satisfied, only the RT is shifted while the main gaming state remains unchanged. On the contrary, when the transition condition of the main game state is satisfied but the transition condition of RT is not satisfied, only the main game state is transitioned while RT is kept.

In the twenty-third embodiment, the winning lottery means 61 carries out the lottery of the “winning number”. Therefore, the role lottery means 61 is also referred to as “winning number lottery (decision, selection) means”. The winning numbers of this embodiment include winning numbers "1" to "41" as shown in FIG.
Then, when the winning number is determined, a “condition device number” corresponding to the winning number is generated. For example, in FIG. 126, when the winning number "1" is determined, the winning and replay condition device number "1" is generated.

The “condition device number” (also referred to as “winning information”) has a “feature condition device number” and a “winning and replay condition device number”. In this embodiment, as shown in FIG. 122 described later, “1” to “17” are provided as the accessory condition device numbers. Further, as shown in FIGS. 123 to 125 which will be described later, “1” to “24” are provided as winning and replay condition device numbers.
Then, when the winning number is determined and the condition device number is generated, the condition device corresponding to the condition device number is activated, so that the symbol combination of the combination corresponding to the operated condition device can be stopped and displayed on the activated line. Becomes
Since 1BB and RB of this embodiment may not be won in the winning game, they may be inside 1BB and RB, respectively.

In the twenty-third embodiment, the left reel 31 may be referred to as the first reel 31, the middle reel 31 may be referred to as the second reel 31, and the right reel 31 may be referred to as the third reel 31.
In particular, in the name of the RWM 53 described later, they are referred to as the first reel 31, the second reel 31, and the third reel 31.

FIG. 114 is a diagram showing a symbol array of the reel 31 in the twenty-third embodiment. As shown in FIG. 114, in this embodiment, each reel 31 is composed of 20 frames.
In FIG. 114, the symbol numbers are also shown. For example, in the left reel 31, the symbol with the symbol number 0 is "replay". Further, in FIG. 114, the symbol number when the reel 31 is reversely rotated is also displayed. The symbol number when the reel 31 rotates in the reverse direction will be described later.

Further, in the twenty-third embodiment, the maximum number of moving symbols from the moment the stop switch 42 is operated to when the reel 31 is stopped is set to "4". For example, when the left stop switch 42 is operated immediately before the first "watermelon" of the left reel 31 passes through the activated line, the maximum is 4 symbols moved from the symbol to the fifth "replay", It becomes possible to stop at the active line.
Therefore, if, for example, four specific symbols are arranged at five symbol intervals on one reel 31, it is possible to always stop the specific symbol on the activated line regardless of which position the stop switch 42 is operated. For example, on the left reel 31, "replays" are arranged at Nos. 5, 10, 15, and 0. That is, "replay" on the left reel 31 is arranged with four five symbol intervals. Therefore, for the left reel 31, it is possible to always stop the "replay" on the activated line, no matter which timing the left stop switch 42 is operated. In addition, such a symbol arrangement may be referred to as ““PB=1” arrangement”.

Then, on the left reel 31, the “bell A” and the “watermelon” are arranged in “PB=1”.
In the middle reel 31, "replay", "bell A", and "cherry" are arranged in "PB=1".
Furthermore, on the right reel 31, the “replay”, “bell A”, and “bell B” are arranged in “PB=1”, respectively.
Furthermore, in the left reel 31, No. 3 "black BAR", No. 8 "special drawing", No. 13 "red 7", No. 18 "blue BAR", "PB=1" in these four symbols It is an arrangement. Therefore, no matter which timing the left stop switch 42 is operated, any of "black BAR", "on special view", "red 7" or "blue BAR" can be stopped on the activated line.
Similarly to the left reel 31, the middle reel 31 has “PB=1” arrangement in “black BAR”, “blue BAR”, “red 7” or “on special drawing” in total of these four symbols.
Further, in the right reel 31, "blue BAR" or "special drawing below" is the arrangement of "PB=1" in the total of these two symbols.

FIG. 115 is a diagram showing the display window (transparent window) 18, the positional relationship between the reels 31, and the effective line (display line for displaying the symbol combination).
The reel 31 disposed inside can be seen through the display window 18.
In this embodiment, three reels 31 (left reel 31, middle reel 31, and right reel 31) are provided in parallel in the lateral direction. Furthermore, the reels 31 are arranged so that the three symbols that are vertically continuous can be seen from the display window 18. Therefore, a total of nine symbols (frames) are arranged so that they can be seen from the display window 17 of the slot machine 10.

Further, in FIG. 115, the designation of symbol positions in this specification is illustrated. In the present specification, the symbol positions at the time of stop for each reel 31 when viewed from the display window 18 are referred to as “upper”, “middle” and “lower” in order from the top. , "Left middle stage", and "lower left stage".

Furthermore, as shown in FIG. 115, an effective line is set for the nine symbols visible from the display window 18.
Here, the "effective line" is a line of symbols arranged when the reel 31 is stopped, a symbol combination line (display line) for forming a symbol combination, and a symbol combination corresponding to one of the winning combinations. This is the line that will win the winning combination when you stop at that line. In the present embodiment, the specified number is three in any gaming state, and the valid lines are set to be the same in any gaming state.
The effective line of the twenty-third embodiment is a so-called straight line descending to the right (“upper left stage”-“middle middle stage”-“lower right stage”). Other than this is an invalid line.
The specified number may be different for each gaming state (for example, the specified number during 1BB operation is "2"). Further, the position and number of effective lines may be different for each gaming state and for each specified number (for example, a certain specified number has a plurality of effective lines).

116 to 121 are diagrams showing types of winning combinations (such as winning combinations corresponding to the winning numbers drawn by the winning combination lottery means 61), symbol combinations, and payout numbers in the twenty-third embodiment.
The roles are roughly classified into special roles, replays (re-game roles), and small roles.
Then, the symbol combination corresponding to each winning combination, the number of payouts at the time of winning, and the like are set. When all the reels 31 are stopped, the symbol combination corresponding to one of the winning combinations stops on the activated line (the winning combination wins. The same applies hereinafter), and the number of medals corresponding to that winning combination is paid out (payout (profit) ) Is given)).
However, the number of payouts at the time of winning the special part is set to 0. Further, in the replay, the medals are automatically inserted and the replay can be executed.

In FIG. 116 to FIG. 121, “3 pieces (1)” corresponds to a non-actuation of a winning combination, and particularly in the 23rd embodiment, a game other than the 1BB game (for example, 1BB non-winning state and 1BB game) It corresponds to a non-medium state, a state where 1BB winning information (conditional device number) is carried over, etc.). In the twenty-third embodiment, since there is a case where AT is executed during the 1BB game, games other than the 1BB game are non-AT. Therefore, in the twenty-third embodiment, a game other than the 1BB game may be referred to as a "normal game (non-acting non-AT, non-AT)". However, even in the normal game, there are cases of an advantageous section and non-advantageous section.
In addition, "3 sheets (2)" corresponds to a non-operating RB during 1BB operation (during 1BB game). Furthermore, "3 sheets (3)" corresponds to 1BB operation (during 1BB game) and RB operation (during RB game).
For example, in FIG. 116, 1BB with the winning number "001" is subject to lottery when the prescribed number is 3 (1) (when the role is inactive), but the prescribed number is 3 (2) and the prescribed number is 3 In the case of (3), it means that the lottery is not eligible.

The winning combination numbers "001" to "017" shown in FIG. 116 correspond to special winning combinations (features). In the present embodiment, one type of 1BB and 16 types of RBs (RBA to RBP) are provided as special roles.
In the twenty-third embodiment, since only 1BB is selected and the RBs are not selected when the accessory is not in operation, there is no case where the accessory is not in operation and the RB is in operation.
If 1BB is won and 1BB is won when the accessory is not in operation, there is no payout of medals in this game, but the next game is shifted to 1BB operation (1BB game) corresponding to a special game.

Also, during the 1BB operation (1BB game), RB is drawn by lot. If the RB wins during the 1BB operation and the RB wins, the medal is not paid out in the game this time, but the RB operation (RB game) during the 1BB operation (1BB game) shifts from the next game.
In addition, in the twenty-third embodiment, the time when 1BB is operating and the RB is not operating may be referred to as "general game of 1BB game".
In the case where the ending condition of the RB operation is satisfied, when the ending condition of the 1BB operation is satisfied, the 1BB operation is ended and the character object is not operated (normal game). On the other hand, when the termination condition of the RB operation is satisfied and the termination condition of the 1BB operation is not satisfied, the 1BB operation (and the RB non-operation) is performed.

The winning combination numbers “018” to “047” shown in FIG. 117 all correspond to replays (replay winning combinations). In the twenty-third embodiment, replays 01 to 10 are provided as types of replay. As shown in FIG. 117, when the accessory is not in operation (three pieces (1)), all of the replays 01 to 10 are lottery targets. On the other hand, when the RB is not in operation while the 1BB is in operation (three (2)), only the replay 01 is the lottery target. Furthermore, when the RB is operating during the 1BB operation (three (3)), the replay is not drawn.

118-121 have shown the small winning combination of 23rd Embodiment. Small winning combinations 01 to 34 are provided as the small winning combinations of the 23rd embodiment.
Of the small wins 01 to 34, the small wins 01 to 12 have the number of payouts at the time of winning set to 15, and at the time of so-called push order bell winning (small win A group (small wins A1 to A6) to be described later, And the winning combination of the small winning group B (small winning cases B1 to B6).
In addition, the small prizes 13 to 24 are set to three payout numbers at the time of winning, and are low rank bells at the time of so-called push order bell winning (at the time of winning the small prize A group (small prizes A1 to A6)). It is a role.
Furthermore, the small prizes 25 to 33 have the number of payouts at the time of winning set to one, and are the low-rank bells at the time of so-called push order bell winning (at the time of winning the small prize B group (small prizes B1 to B6)). It is a role.
Furthermore, the small winning combination 34 is a winning combination subject to the lottery during the RB operation during the 1BB operation (at the time of three cards (3)).

In each of the above-mentioned winning combinations, when the symbol combination corresponding to the winning combination does not stop in the activated line in the game won as the winning combination, the winning combination to be carried over after the next playing game and the winning combination not to be carried over are defined.
In the present embodiment, the roles to be carried over are 1BB and RB. Since the symbol combinations of 1BB and RB are both set to “PB≠1”, there is a case where the game won in 1BB or RB does not win. When the player wins 1BB or RB, in the game until 1BB or RB wins, the winning information of the 1BB or RB is controlled to be carried over to the next game or later.

On the other hand, when a small win or replay is won, the winning combination is valid only in the current game, and the winning is not carried over to the next game or later. That is, in the games winning these winning combinations, the reel 31 is stopped and controlled so that the symbol combination corresponding to the winning combination can be won, but at the end of the game, regardless of whether or not the winning combination is won. The right to win the winning role disappears.
In the twenty-third embodiment, when a winning number including a small win or a replay is won, it is set so that any replay or a small win always wins, and there is no case that the replay or the small win is missed. However, the present invention is not limited to this, and it goes without saying that a small win (“PB≠1”) may be provided.

122 to 125 are diagrams showing condition device numbers, condition devices, winning combinations, and the like.
First, the winning lottery means 61 draws a winning number. The winning numbers include winning numbers “1” to “41”, for example, as shown in FIG. 126 described later. Then, as shown in FIG. 126, for example, when the winning number "1" is won, the condition device "Replay A" corresponding to the winning and replay condition device number "1" becomes operable.
Also, for example, when the winning number "25" is won, the condition device "1BB" corresponding to the accessory condition device number "1" becomes operable.

Here, as shown in FIG. 138, which will be described later, the RWM 53 has a storage area (address “F0A9(H)”) capable of storing the winning and replay condition device numbers and a storage area capable of storing the accessory condition device number. (Address “F0AA(H)”). For example, it is assumed that the winning number "11" is won when the accessory is not in operation. In this case, the winning and replay condition device numbers can be updated by storing the value of the winning number (“11”) in the address “F0A9(H)”. Further, for example, it is assumed that the winning number “25” is won when the accessory is not operated. In this case, a value obtained by performing a predetermined calculation on the value of the winning number (in the twenty-third embodiment, "1" which is a value obtained by subtracting "24" from the winning number) is stored in the address "F0AA(H)". As a result, the accessory condition device number can be updated.

In the twenty-third embodiment, the winning number won in the lottery by the winning lottery means 61 is compared with "25", and when it is determined to be less than "25", the winning number is assigned to the address "F0A9(H)". It can be stored. If it is determined that the number is not less than “25”, the accessory condition device number can be derived from the winning number by a predetermined calculation (as described above, “24” is subtracted in the twenty-third embodiment). The control processing is performed so that the specified accessory condition device number can be stored in the address “F0AA(H)”. Particularly, as in the twenty-third embodiment, when the total number “17” of the accessory condition device numbers is smaller than the total number “24” of the prize and replay condition device numbers, it is an effective derivation method. ..

FIG. 122 shows an accessory (particularly 1BB or RB in the 23rd embodiment) condition device.
For example, the 1BB condition device corresponding to the accessory condition device number "1" is an accessory condition device that becomes operable when 1BB is won. When this 1BB condition device operates, the winning combination 1BB can be won.
Further, the remarks column of FIG. 122 shows the operation end conditions of the accessory condition device. The 1BB condition device continues until the number of medals acquired exceeds 170, and when the number of medals acquired exceeds 170, the operation end condition of the 1BB condition device is satisfied and the operation of the 1BB condition device is ended.
Similarly, all of the RBA condition device to the RBP condition device end based on 12 games or 8 winnings, or the operation end of the 1BB condition device.

123 to 125 show winning and replay condition devices. Among the winning and replay condition device numbers, “1” to “9” are condition device numbers related to replay, and “10” to “24” are condition device numbers related to small winning combinations.
For example, when the replay B condition device corresponding to the winning and replay condition device number “2” is activated, since the winning combinations include Replay 01 and 02, Replay 01 and 02 can be won. When the condition device operates, not all winning combinations corresponding to the condition device can be won. For example, when the replay B condition device operates, replay 02 can be won in the 23rd embodiment. Becomes
Therefore, in the twenty-third embodiment, even if a plurality of types of replays are won, only one replay wins. Similarly, as will be described later, there are cases where multiple types of small winning combinations are won, but in this case as well, only one small winning combination can be won (no overlapping winning).

When the replay A condition device corresponding to the prize and replay condition device number “1” is activated, only replay 01 can win. The symbol combinations of Replay 01 are the combination numbers “018” to “021” in FIG. 117. Therefore, "replay"-"blue BAR/black BAR/red 7/special view"-"bell A" stops on the activated line. When "blue BAR/black BAR/red 7/special drawing top" is stopped on the activated line (middle middle tier) when the middle reel 31 is stopped, "replay" is stopped at the middle upper tier. Further, when "bell A" stops on the activated line (lower right stage) when the right reel 31 stops, "replay" stops on the upper right stage. Therefore, when the symbol combination of Replay 01 stops on the activated line (Replay 01 wins), "Replay"-"Replay"-"Replay" (upper replay) is stopped on the upper line (ineffective line).

When the replay B condition device is activated, replay 02 can be won. The symbol combination of Replay 02 is the combination number “022” in FIG. 117. Therefore, "replay"-"replay"-"replay" (downward replay) stops on the activated line.
When the replay C condition device is activated, replay 03 or 10 can be won. Here, "weak cherry" is mentioned in the remarks column because it can be a so-called square cherry ("cherry" stops at the lower left). The lower left is not an effective line. The pattern of the left reel 31 of the replay 03 is "bell A", but in FIG. 114, when the 4th "bell A" of the left reel 31 is stopped on the activated line (upper left row), the 2nd "cherry". Stops at the lower left (invalid line).

In the replay D1 condition device, “strong cherry 1” is included in the remarks column because it can be a so-called middle cherry (“cherry” is stopped in the middle left). The middle line on the left is not an effective line. The same applies to the “strong cherry 2” of the replay D2 condition device and the “strong cherry 3” of the replay D3 condition device.
When the replay D1 condition device is activated, the winning combination, replay 03, 04 or 10, can be won. Of these, the symbol combination of Replay 04 is "Black BAR"-"Red 7/Cherry"-"Replay/Bell B" as shown by the combination numbers "027" to "030" in FIG. Then, when the third "black BAR" is stopped on the activated line (upper left row) when the left reel 31 is stopped, the second "cherry" is stopped on the left middle row.

When the replay D2 condition device is activated, the winning replay 02, 03, 04 or 10 can be won, and when the replay D3 condition device is activated, the replay 03, 04, 05 or 10 can be won.
When the replay D2 condition device or the replay D3 condition device is activated, if the replay 04 wins, the second “cherry” is stopped in the left middle stage when the left reel 31 is stopped, similarly to when the replay D1 condition device is activated.

When the Replay E condition device is activated, the winning combination, Replay 06, can be won. The symbol combination of Replay 06 is “watermelon”-“replay/watermelon”-“red 7/watermelon/special figure/black BAR” as shown in FIG. 117. Here, since the "watermelon" of the left reel 31 is "PB=1", the "watermelon" always stops on the activated line. Further, the "watermelon" of the middle and right reels 31 is "PB≠1", but if the "watermelon" is pressed, the "watermelon" can be stopped on the effective line.
When the Replay F condition device is activated, Replay 07, which is a winning combination, can win the prize.

When the Replay G condition device operates, the winning combination, Replay 08 or 09, can be won. Here, in order to win the Replay 08, when the left reel 31 is stopped, the No. 8 "special map top" is pressed so as to stop in the upper left stage, and when the right reel 31 is stopped, the No. 16 " When the player presses so that "Replay" stops at the lower right, Replay 08 wins, and "Special drawing upper" and "Special drawing lower" stop at the upper left and middle left. Furthermore, "special drawing upper" and "special drawing lower" stop at the upper right and middle right. This stop type is referred to as the "strongest cherry" in the twenty-third embodiment.

In FIG. 124, when the small winning combination A1 condition device to the small winning combination A6 condition device are activated, any of the small winning combinations 01 to 06 or the small winning combinations 13 to 24 included in the winning combination can be won.
Here, when the small winning combination A1 condition device to the small winning combination A6 condition device are activated during the 1BB game (1BB operation), and the stop switch 42 is operated in the correct answer order, 15 winning combinations (included in the winning combination) When the stop switch 42 is operated in an incorrect pressing order (a pressing order other than the correct pressing order) when a small winning combination 01-06 is won, three winning combinations (small winning combinations 13- included in the winning combinations). Any of 24) will win.
On the other hand, when the accessory does not operate, the correct answer pressing order does not exist when the accessory A1 condition device to the accessory A6 condition device operate. When the small win A1 condition device to the small win A6 condition device are in operation when the accessory is not in operation, three wins are won even if all are in the pushing order.

In addition, the small role A1 condition device to the small role A6 condition device can be operated only when the RB is not operated during the 1BB operation. Therefore, the small role A1 condition device to the small role A6 condition device operate during the normal game of the 1BB game (other than the RB game).
Here, the relationship between the small wins A1 to A6 condition device and the correct answer pressing order during 1BB operation is as follows.
Small role A1 condition device: 123 (left center right)
Small role A2 condition device: 132 (left and right middle)
Small role A3 condition device: 213 (middle left and right)
Small role A4 condition device: 231 (middle right left)
Small role A5 condition device: 312 (right left middle)
Small role A6 condition device: 321 (right middle left)

For example, in the case where the small win A1 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct answer pressing order "123", "watermelon"-" on the effective line to win the small win 01. "Cherry"-Stop "Bell A". As a result, "bell A"-"bell A"-"bell A" is stopped on the lower line (ineffective line).
In addition, when the stop switch 42 is operated in the incorrect answer pressing order "132", the correct answer pressing order is set at this point when the left first stop is performed. Therefore, when the left reel 31 is stopped, "Watermelon" (small win) (The pattern that constitutes 01) is stopped. Next, at the time of the second stop on the right side, the improper pressing order is reached at this point, so the small reel 17 of which the left reel 31 is “watermelon” among the winning reels 13 to 17 is stopped on the activated line. That is, at the time of the second stop on the right, "Replay" is stopped on the lower right side. Furthermore, at the time of the third stop in the middle, "Red 7/Replay" is stopped in the middle middle stage.

On the other hand, when the stop switch 42 is operated in the wrong pressing order "213" or "231", the wrong pressing order is reached at this point in the middle first stop, so that, for example, the small win 14 is stopped on the activated line. Therefore, the "bell A" is stopped in the middle and middle stages at the middle first stop. When the left reel 31 is stopped, "replay" is stopped in the upper left stage, and when the right reel 31 is stopped, "bell A/bell B" is stopped in the lower right stage.
Further, when the stop switch 42 is operated in the incorrect pressing order "312" or "321", the incorrect pressing order is reached at this time when the first stop on the right side is made. Therefore, for example, the small win 17 is stopped on the activated line. Therefore, the "replay" is stopped in the lower right stage at the first stop on the right. Further, when the left reel 31 is stopped, the “watermelon” is stopped in the upper left stage, and when the middle reel 31 is stopped, “Red 7/Replay” is stopped in the middle and middle stage.

As described above, in the case where the small winning combination A1 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct answer pressing order "123", 15 winning combinations are won. On the other hand, when the 1BB game is not being performed, that is, in the twenty-third embodiment, when the accessory is not operating (1BB is not inside and 1BB is inside), even if the small role A1 condition device is operated, the correct answer is obtained. There is no push order. Therefore, even when the stop switch 42 is operated in the pressing order “123” when the small role A1 condition device is activated when the role object is not operated, three winning combinations are won (without winning 15 winning combinations). As the three-piece winning combination, for example, a small winning combination 14 or 17 with “PB=1” can be cited.

The above is the same for the small role A2 to small role A6 condition devices (condition device numbers “11” to “15”).
When the small win A2 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct answer press order "132", the small win 02, which is a 15-card win, is won and the press order other than "132" is entered. When the stop switch 42 is operated in the pushing order, any one of the three winning combinations included in the winning combination is won.
Furthermore, when the small winning combination A2 condition device is activated when the accessory is not operated, any of the three winning combinations included in the winning combination can be selected regardless of the pressing order (since there is no correct pressing order). Make a prize.

When the small win A3 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct pressing order "213", the small win 03, which is a 15-card win, is won, and the pressing order other than "213" is entered. When the stop switch 42 is operated in the pushing order, any one of the three winning combinations included in the winning combination is won.
Furthermore, when the small role A3 condition device is activated when the accessory is not activated, no matter which pressing order is selected (since there is no correct answer pressing order), any of the three winning combinations included in the winning combination is selected. Make a prize.

In the case where the small role A4 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct answer pressing order "231", the small role 04 which is the 15-piece winning combination is won, and the pressing order other than "231" is entered. When the stop switch 42 is operated in the pushing order, any one of the three winning combinations included in the winning combination is won.
Furthermore, when the small role A4 condition device is activated when the accessory is not activated, no matter which pressing order is selected (since there is no correct answer pressing order), any three winning combinations included in the winning combination are Make a prize.

When the small winning combination A5 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct answer pressing order "312", the small winning combination 05 having 15 winning hands is won and the pressing order other than "312" is entered. When the stop switch 42 is operated in the pushing order, any one of the three winning combinations included in the winning combination is won.
Further, when the small role A5 condition device is activated when the accessory is not activated, any of the three winning combinations included in the winning combination is selected regardless of the pressing order (since there is no correct pressing order). Make a prize.

When the small win A6 condition device is activated during the 1BB game, when the stop switch 42 is operated in the correct press order "321", the small win 06 which is 15 wins is won, and the press order other than "321" is entered. When the stop switch 42 is operated in the pushing order, any one of the three winning combinations included in the winning combination is won.
Furthermore, when the small role A6 condition device is activated when the accessory is not activated, no matter which push order is selected (since there is no correct answer push order), any of the three winning combinations included in the winning combination is selected. Make a prize.

Further, inside the SRB during the operation of 1BB, the small win B1 condition device to the small win B6 condition device (condition device numbers “16” to “21”) are operated, and the stop switch 42 is operated in the correct pressing order. In this case, when 15-stop winning combination (one of the small winning combinations 07 to 12 included in the winning combination) is won and the stop switch 42 is operated in the wrong pressing order (pressing order other than the correct pressing order), 1 A single winning combination (one of the small winning combinations 25 to 33 included in the winning combination) is won.
On the other hand, in the non-operation of the accessory and in the non-inside of the SRB during the operation of 1BB, the correct answer pressing order does not exist when the small combination B1 condition device to the small combination B6 condition device are operated. When the accessory is not activated, and when the small winning combination B1 condition device to the small winning combination B6 condition device are in operation while the SRB is not inside the 1BB, one winning combination is won, even if they are in the pushing order.
The winning and replay condition device numbers “16” to “21” are drawn only when the RB is not operated among the 1BB operated.

In the case where the small win B1 condition device is activated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the correct answer pressing order "123", in order to win the small win 07, "watermelon "-"Cherry"-"Bell B" is stopped. As a result, "bell A"-"bell A"-"bell B" is stopped on the lower line (ineffective line).
In addition, when the small win B1 condition device is operated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the incorrect pressing order "132", the correct pressing order is left at this point when the left first stop is made. Therefore, when the left reel 31 is stopped, the “watermelon” (the pattern forming the small winning combination 07) is stopped on the activated line. Next, at the time of the second stop on the right side, since it is in the improper pressing sequence at this time, the winning combination 25, 26, and 28, for example, the small winning combination 28 in which the left reel 31 is a “watermelon” is stopped on the activated line. That is, at the time of the second stop on the right, "Bell A" is stopped at the lower right. Further, at the time of the third stop in the middle, the "bell B/watermelon" is stopped in the middle and middle stages.

On the other hand, when the small win B1 condition device is activated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the wrong pressing order "213" or "231", at this point during the first stop In order to stop the small winning combination 25 on the activated line, for example, "blue BAR/black BAR/red 7/special figure" is stopped in the middle and middle stage when the middle first stop is made. When the left reel 31 is stopped, "replay" is stopped in the upper left stage, and when the right reel 31 is stopped, "black BAR/red 7/watermelon/special figure" is stopped in the lower right stage.
Also, when the small win B1 condition device is activated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the wrong pressing order "312" or "321", at this time when the right first stop is made. Since there is an incorrect pressing order, the small winning combination 25 is stopped on the activated line, for example, as described above.

In addition, in the game in which the small winning combination B1 to B6 condition device is activated during the 1BB game and the SRB non-internal, there is no correct answer pushing order. Therefore, for example, even when the stop switch 42 is operated in the pushing order "123" when the small win B1 condition device is operating during the 1BB game and the SRB is not inside (without winning the small win 07, which is a 15-win hand,). ) Win one winning role. As one winning combination to be won, for example, a small winning combination 25 or 28 with “PB=1” can be cited.
Similarly, when the 1BB game is not in progress, that is, when the accessory is not in operation (1BB is not inside and 1BB is inside), the game in which the small winning combination B1 condition device is operated does not have the correct answer pushing order. Therefore, even if the stop switch 42 is operated in the pushing order "123" when the small win B1 condition device when the accessory is not operated, the small win 07 (as in the 1BB game and the SRB non-internal). One winning combination (for example, the small winning combination 25 or 28 with “PB=1”) is won without winning the 15 winning combination.

The above is the same when the small win B2 condition device to the small win B6 condition device are operated.
When the small win B2 condition device is activated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the correct answer press order "132", the small win 08, which is a 15-card win, is won, and the correct answer press order. When the stop switch 42 is operated in a pressing order other than "132", one of the winning combinations included in the winning combinations is won, without winning the small winning combination 08.
Furthermore, when the small winning combination B2 condition device is activated during the 1BB game and the SRB is not inside or the accessory is not operating, the small winning combination 08 is pressed regardless of the pushing order (since there is no correct answer pushing order). Any one of the winning combinations included in the winning combination is won without winning.

When the small win B3 condition device operates during the 1BB game and inside the SRB, when the stop switch 42 is operated in the correct answer press order "213", the small win 09, which is a 15-win hand, is won, and the correct answer press order. When the stop switch 42 is operated in a pressing order other than "213", any one of the winning combinations included in the winning combination is won without winning the small combination 09.
Furthermore, when the small win B3 condition device is activated during the 1BB game and the SRB is not inside or when the accessory is inactive, the small win 09 may be applied in any pressing order (since there is no correct answer pressing order). Without winning, one of the winning combinations included in the winning combination is won.

When the small win B4 condition device is activated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the correct answer press order "231", the small win 10 which is 15 wins is awarded and the correct answer press order When the stop switch 42 is operated in a pressing order other than "231", any one of the winning combinations included in the winning combination is won without winning the small winning combination 10.
Furthermore, when the small win B4 condition device is activated during the 1BB game, the SRB is not inside, or the accessory is not in operation, the small win 10 can be obtained in any pressing order (since there is no correct answer pressing order). Without winning, one of the winning combinations included in the winning combination is won.

When the small win B5 condition device is activated during the 1BB game and inside the SRB, when the stop switch 42 is operated in the correct answer press order "312", the small win 11 which is 15 wins is won and the correct answer press order. When the stop switch 42 is operated in a pressing order other than "312", any one of the winning combinations included in the winning combination is won without winning the small winning combination 11.
Furthermore, when the small win B5 condition device is activated during the 1BB game and while the SRB is not inside or when the accessory is inactive, the small win 11 can be obtained in any pressing order (since there is no correct answer pressing order). Without winning, one of the winning combinations included in the winning combination is won.

In the case where the small win B6 condition device operates during the 1BB game and inside the SRB, when the stop switch 42 is operated in the correct answer press order "321", the small win 12, which is a 15-win hand, is awarded, and the correct answer press order. When the stop switch 42 is operated in a pressing order other than "321", one of the winning combinations included in the winning combination is won without winning the small winning combination 12.
Further, when the small win B6 condition device is activated during the 1BB game and the SRB is not inside or the accessory is inactive, the small win 12 is obtained regardless of the pushing order (since there is no correct answer pushing order). Any one of the winning combinations included in the winning combination is won without winning.

The small role C condition device is a condition device which becomes operable when the winning number "22" is won during the RB operation (game). When the small winning combination C condition device is activated, one of the small winning combinations 01 to 12 (15 winning combinations) included in the winning combination is won. In this case, which of the 15 winning combinations is to be won is arbitrary, but, for example, the small winning combination to be won may be changed according to the pressing order of the stop switch 42.
The small role D condition device is a condition device which becomes operable when the winning number “23” is won during the operation of the RB. When the small winning combination D condition device is activated, one of the small winning combinations 13 to 24 (three winning combinations) included in the winning combination is won. In this case, which of the three winning combinations is to be won is arbitrary, but different small winning combinations may be selected depending on the order in which the stop switch 42 is pressed.
The small role E condition device is a condition device which becomes operable when the winning number “24” is won during the operation of the RB. When the small win E condition device is activated, one of the small wins 25 to 34 (one win) included in the winning combination is won. In this case, it is optional which one of the winning combinations is to be won, but, for example, the small winning combination to be won may be changed according to the pressing order of the stop switch 42.

126 to 130 show the winning probabilities determined by the lottery table when the winning lottery means 61 performs the lottery of the winning numbers, and show the numbers of the winning numbers for each RT (game state) and each set value. It is a figure (numerical table). Dividing the numerical values shown in FIGS. 126 to 130 by “65536” gives the winning probability. For example, in FIG. 126, since the number of the winning number “1” is “4338” common to all settings, the winning probability is “4338/65536”.
126 to 130, for example, if the winning number "1" is won in FIG. 126, the winning and replay condition device number "1", that is, the replay A condition device becomes operable, and the replay 01 can win.

The set value refers to a value displayed on the set value display LED 73 in the setting change state and the setting confirmation state, and is different from the information stored in the RWM 53 as the set value information. Specifically, the setting value information stored in the RWM 53 is in the range of “0” to “5” in the twenty-third embodiment. For example, when the set value information stored in the RWM 53 is "0", the value displayed on the set value display LED 73 is "1", and when the set value information stored in the RWM 53 is "1". The value displayed on the set value display LED 73 is “2”, and when the set value information stored in the RWM 53 is “2”, the value displayed on the set value display LED 73 is “3”, which is displayed on the RWM 53. When the stored set value information is “3”, the value displayed on the set value display LED 73 is “4”, and when the set value information stored in the RWM 53 is “5”, the set value display LED 73 is displayed. The value displayed in is "6".

Further, the role lottery means 61 executes the role lottery using the role lottery table. For example, in FIG. 126, the winning number 1 (replay A) indicates that the number "4338" is common from setting 1 to setting 6, but in such a case, winning number 1 (replay A). ), it is determined whether or not one winning number “4338” is stored in the winning lottery table. On the other hand, when at least a part of the numbers is different between the settings 1 to 6 as in the winning number 3 (replay C), the numbers corresponding to the set values are stored in the winning lottery table.
Specifically, in the combination lottery table, for example, “940 (D)” is stored in the 2-byte addresses of the addresses “XXX0(H)” and “XXX1(H)” corresponding to the setting 1, and the setting 2 is set. "940(D)" is stored in the 2-byte address of the corresponding addresses "XXX2(H)" and "XXX3(H)", and the addresses "XXX4(H)" and "XXX5(H)" corresponding to the setting 3 are stored. “940(D)” is stored in the 2-byte address of “”. Further, "950(D)" is stored in the 2-byte address of the addresses "XXX6(H)" and "XXX7(H)" corresponding to the setting 4, and the address "XXX8(H)" and the address corresponding to the setting 5 are stored. “950(D)” is stored in the 2-byte address of “XXX9(H)”. Furthermore, “960(D)” is stored in the 2-byte address of the addresses “XXXA(H)” and “XXXB(H)” corresponding to the setting 6. The above-mentioned "XXX0(H)" to "XXXB(H)" indicate arbitrary continuous addresses in the ROM 54.

Then, for example, when the setting value information is "1" (that is, setting 2), the address "XXX0(H)" is used as a reference address, and the value obtained by doubling the setting value information is used as an offset value, and the address "XXX2(H)" is used. And “940(D)” stored in “XXX3(H)” are acquired, the random number and the registered number “940(D)” are compared and calculated, and whether the winning number 3 (replay C) is won Determine whether or not. In the above-mentioned example, since the register number is 2 bytes, the value obtained by doubling the setting value information is set as the offset value. However, when the register number is 1 byte, the setting value information is doubled. It is possible to set the offset value without performing. In this way, by using the specific address as the reference address and the set value information or the value obtained by doubling the set value information as the offset value, it is possible to acquire the number corresponding to the set value information. ..

If the winning number "25" is won in the game this time in a game that has not been won as a special role (1BB), and the winning 1BB is not won in the game in which the 1BB condition device becomes operable, The winning will be carried over after the next game. Then, after the next game (during the inside of 1BB), the winning number "25" is not drawn, and the winning numbers "1" to "21" are selected. When one of the winning numbers "1" to "21" is won in 1BB, the condition device corresponding to the winning number won in the game this time becomes operable, and the accessory condition device does not operate. On the other hand, when none of the winning numbers "1" to "21" is won in the inside of 1BB, the 1BB condition device relating to the 1BB carrying the winning is operable and the 1BB can be won. ..

The same applies to the other special roles RB.
In the RB non-winning game of the 1BB game, in the game in which the winning numbers “26” to “41” are won in the current game, and the RBA to RBP condition device becomes operable, the winning combination RBA to If the RBP does not win, the winning is carried over to the next game or later. Then, in the next game and after (while the SRB is inside), the winning numbers “26” to “41” are not drawn, and the winning numbers “10” to “21” are selected. When any of the winning numbers “10” to “21” is won inside the SRB, the condition device corresponding to the winning number won this time in the game becomes operable, and the RBA to RBP condition devices do not operate. On the other hand, when none of the winning numbers “10” to “21” is won inside the SRB, the RBA to RBP condition device relating to the RBA to RBP carrying the winning becomes operable and the winning is won. The winning RBA to RBP can be won.

FIG. 126 is a diagram showing a numerical table in non-RT. In non-RT, 1BB is drawn for the winning character (winning number “25”), but RB is not drawn. RBs are selected by lottery at the time of 1BB operation (during 1BB game) described later.
In the non-RT, all the winning numbers “1” to “9” corresponding to the winning of the replay are subject to the lottery. Also, the winning numbers “10” to “21” corresponding to the winning of the small winning combination are subject to the lottery. The winning numbers “10” to “27” are subject to lottery at any RT (game state) except when the RB is operating.
The winning numbers “22” to “24” are targeted for lottery only when the RB is operated during the 1BB game described later, and are not targeted for lottery at other RTs (gaming state).

FIG. 127 is a diagram showing a number table in RT1. The difference between RT1 and non-RT is that the winning number “9” (replay G) is not drawn. Other than that, it is the same as the non-RT.
Note that in both non-RT and RT1, 1BB (winning number “25”) is drawn by the numbers shown in FIGS. 126 and 127, respectively, when the winning number “25” is won. In non-RT and RT1 of (inside 1BB), 1BB (winning number “25”) is not drawn. That is, the number "19930" shown in FIGS. 126 and 127 is "0" after the 1BB winning.

FIG. 128 is a diagram showing a numerical table of RB (SRB) non-internal during 1BB operation. The inside of RB during 1BB operation corresponds to the normal game of 1BB game.
In this gaming state, the winning number “25” (1BB) is not drawn, but all RBs (winning numbers “26” to “41”) are drawn. In this embodiment, all the RBs are set to the same number "1807" in all the set values.
In addition, the replay is not drawn in the non-RB inside 1BB operation. Therefore, the numbers of the winning numbers “1” to “9” are set to “0”.
As for the small winning combination, the winning numbers “10” to “21” are subject to the lottery as in the case of the non-RT and RT1 described above. The winning numbers “22” to “24” corresponding to the small winning combination in the RB game are not drawn.

FIG. 129 is a diagram showing a numerical table inside the RB (SRB) during 1BB operation. The inside of the RB during the operation of the 1BB corresponds to the general game of the 1BB game, like the inside of the RB during the operation of the 1BB.
In the inside of the RB during the operation of the 1BB, no RB is selected by lottery in addition to 1BB, so that the numbers of the winning numbers “25” to “41” are all “0”.
In addition, unlike the inside of the RB during the operation of the 1BB, the winning number “1” (replay A) is drawn in the inside of the RB during the operation of the 1BB.
FIG. 130 is a diagram showing a numerical table during 1BB operation and RB operation. During the 1BB operation and the RB operation, only the winning numbers “22” to “24” are drawn.

The payout rate in each of the above game states will be described.
There are various definitions of the payout rate, but in the twenty-third embodiment, the payout rate is defined as “out number/in number”.
Here, the "number of coins" refers to the number of bets, and in the twenty-third embodiment, it is "3" in any gaming state.
Further, the “out number” means the payout number, and by design, indicates the expected value of the payout number. For example, in the game in which the instruction function is activated (the game in which the correct answer push order is informed), when the winning numbers “10” to “21” are won (when the push order bell is selected), the higher bell (in the 23rd embodiment) is always used. 15 bells).
Specifically, when the in-number is “3” and the out-number is “1”, the payout rate is about “0.33”.
Further, when the in-number is “3” and the out-number is “3”, the payout rate is “1”.
Furthermore, when the in-number is “3” and the out-number is “9”, the payout rate is “3”.

Also, when the winning number "10" to "15" is won when the accessory (1BB) is not activated, the three winning combinations are always won, and the winning numbers "16" to "21" when the accessory is not activated are won. At any given time, one winning combination shall always be awarded.
Furthermore, in the RB non-internal and non-AT during 1BB game (game in which the instruction function does not operate), when the winning numbers "10" to "15" are won, there is a high probability of "1/6" bell ( It is assumed that 15 bells will win and a cheap bell (3 bells) will win with a probability of "5/6". It should be noted that the reason for setting "1/6" is that the winning order is the winning probability when the stop switch 42 is operated at random because the pressing order is 6 selections. Further, in the non-internal RB during the 1BB game and at the time of non-AT, when the winning numbers "16" to "21" are won, one bell is always won.

Furthermore, in the RB inside the 1BB game and at the time of non-AT (game in which the instruction function does not operate), when the winning numbers “10” to “15” are won, there is a high probability of being “1/6” (15 pieces). Bell) wins, and a cheap bell (3 bells) wins with a probability of "5/6". In addition, when the winning number "16" to "21" is won while the RB is in the 1BB game and not in AT, a high-rank bell (15 bells) wins with a probability of "1/6", and "5" A cheap bell (1 bell) will be awarded with a probability of "/6".

Further, when the replay symbol combination is stopped and displayed, firstly, there is a method of setting the number of outs in the current game to "0" and the number of ins in the next game to "0". Secondly, there is a method of setting the number of outs in the current game to "3" and the number of ins in the next game to "3". In the following example, the latter is used for the calculation.
Furthermore, although the payout rate differs depending on the settings 1 to 6, hereinafter, the setting 1 will be taken as an example to calculate the payout rate.

In the non-RT, the total number of winning numbers “1” to “9” corresponding to the winning of the replay is “8982”.
The total number of winning numbers “10” to “15” corresponding to the winning of the small winning combination A group is “16800”.
Furthermore, the total number of winning numbers “16” to “21” corresponding to the winning of the small winning combination B group is “19824”.
Then, in the non-RT gaming state, three winning combinations are always won in the winning numbers "10" to "15", and one winning combination is always won in the games having winning numbers "16" to "21".
Therefore, the expected number of payouts per game is
3 x (8982/65536) + 3 x (16800/65536) + 1 x (19824/65536)
≒1.483 (sheets)
Becomes
In addition, the payout rate is
1.483/3 ≈ 0.494
Becomes

Next, during 1BB operation and RB non-internal, the payout rate is calculated separately for AT time and non-AT time.
First, at the time of AT, 15 coins are paid out in the games won by the winning numbers “10” to “15” corresponding to the winning of the small role A group, and in the games won by the winning numbers “16” to “21”, It will be one payment.
Therefore, the expected number of payouts per game is
15 x (16800/65536) + 1 x (19824/65536)
≒4.148 (sheets)
Becomes
In addition, the payout rate is
4.148/3 ≈ 1.383
Becomes

In addition, in 1BB operation and RB non-internal, at the time of non-AT, in the game won the winning numbers “10” to “15” corresponding to the winning of the small role group A, there is a probability of “1/6” of 15 A payout of 3 sheets is made with a probability of "5/6". In addition, in the game in which the winning numbers “16” to “21” are won, one payout is made.
Therefore, the expected number of payouts per game is
15 x (16800/65536) x (1/6) + 3 x (16800/65536) x (5/6) + 1 x (19824/65536)
≒1.584 (sheets)
Becomes
In addition, the payout rate is
1.584/3=0.528
Becomes

Next, during 1BB operation and inside the RB, the payout rate is calculated separately for AT time and non-AT time.
First, at the time of AT, 15 coins will be paid out in the games won by the winning numbers “10” to “15” corresponding to the winning of the small role A group, and even in the games won by the winning numbers “16” to “21”, 15 pieces will be paid out.
Therefore, the expected number of payouts per game is
15 x (16800/65536) + 15 x (19824/65536)
≒8.383 (sheets)
Becomes
In addition, the payout rate is
8.383/3 ≈ 2.794
Becomes

Also, in the 1BB operation and inside the RB, in the non-AT, in a game in which the winning numbers “10” to “15” corresponding to the winning of the small winning combination A group are won, there is a probability of “1/6”, which is 15 pieces. The payout of “3” will be paid out with a probability of “5/6”. Further, in the games won by the winning numbers “16” to “21”, 15 pieces are paid out with a probability of “1/6”, and one piece is paid out with a probability of “5/6”.
Therefore, the expected number of payouts per game is
15×(16800/65536)×(1/6)+3×(16800/65536)×(5/6)+15×(19824/65536)×(1/6)+1×(19824/65536)×(5/ 6)
≒2.290 (sheets)
Becomes
In addition, the payout rate is
2.290/3 ≈ 0.763
Becomes

Further, during the 1BB operation and the RB operation, the payout rate is the same in the non-AT time and the AT time.
As shown in FIG. 130, during 1BB operation and RB operation, the winning number "22" is "3310" and the payout number is 15, and the winning number "23" is "16230" and the payout number is Is 3, the number of the winning number “24” is “19825”, and the payout number is 1.
Therefore, the expected number of payouts per game is
15 x (3310/65536) + 3 x (16230/65536) + 1 x (19825/65536)
≈ 1.803 (sheets)
Becomes
In addition, the payout rate is
1.803/3 ≈ 0.601
Becomes

In the above, when the payout rate exceeds "1", it is a gaming state in which medals increase, and when the payout rate is less than "1", it is a gaming state in which medals decrease.
Therefore, the payout rate exceeds “1” (the number of medals increases) at the time of AT during 1BB operation and RB non-internal, and at AT during 1BB operation and RB internal.
On the other hand, when the 1BB is not operated, the 1BB is operated and the RB is not inside the non-AT, the 1BB is operated and the RB is not inside the AT, and the 1BB is operated and the RB is operated The rate is below "1" (the number of medals decreases).
Therefore, the size relationship of the payout rate is
(1) When 1BB is not in operation (ball output rate “0.494”)
(2) Non-AT during 1BB operation and RB non-internal (ball output rate “0.528”)
(3) During 1BB operation and RB operation (ball output rate “0.601”)
(4) During 1BB operation and non-AT in RB (ball output rate "0.763")
(5) AT during 1BB operation and RB non-internal (ball output rate "1.383")
(6) AT during 1BB operation and inside RB (ball output rate "2.794")
Becomes

From the above,
(1) The payout rate exceeds "1" when the RB is not operating during AT, but the payout rate does not exceed "1" during non-AT.
(2) If the RB is won and the RB is activated even during AT, the payout rate is less than "1".
(3) The payout rate is higher when 1BB is operating during non-AT than when 1BB is not operating during non-AT.
Therefore, for example, even if the player wins 1BB without having the right to execute the AT and shifts to the 1BB game, the payout rate is less than "1" both in the normal game of the 1BB game and in the RB game. Can not be increased.
In addition, in the non-AT, the payout rate is higher when 1BB is operated than when 1BB is not operated. However, since the AT lottery is executed only during the inside of 1BB (when 1BB is not operated), the AT lottery cannot be accepted when 1BB is operated. Therefore, when the 1BB operation is performed during non-AT, it is disadvantageous to the player.
Further, when the inside of the RB is in the middle of AT (when 1BB is operated), 15 winning combinations can be won when the condition devices B1 to B6 are operated. Therefore, during AT (1BB operation), the inside of the RB is more advantageous to the player than the inside of the RB.
In addition, although the above-mentioned payout rate was calculated in the setting 1, the magnitude relationship of the payout rate is the same also in other setting values (settings 2 to 6).

FIG. 131 is a diagram showing RT transitions in the 23rd embodiment.
Non-RT and RT1 correspond to 1BB inactive. Non-RT and RT1 continue until the symbol combination of 1BB is stopped and displayed. In addition, in the twenty-third embodiment, the transition timing of the RT is set at the time of stop display of the symbol combination, that is, at the time of full stop (when all reels 31 are stopped).
In non-RT and RT1, 1BB (the above-mentioned winning number "25") is selected by lot, but if RT is won and 1BB is in the inside, RT does not shift and non-RT or RT1 is maintained respectively. .. Then, in the non-RT or RT1, when the symbol combination of 1BB is stopped and displayed, the operation shifts to 1BB operation time and RB non-internal (general game of 1BB game).

As shown in FIG. 123, RBA (winning number “26”) to RBP (winning number “41”) are randomly selected during 1BB operation and during RT non-internal. Then, if one of the RBA to RBP is won, and the won RBA to RBP is not won, the operation shifts to 1BB operation and inside the RB. During 1BB operation and inside the RB, it continues until the symbol combination of the RB carrying over the winning is stopped and displayed. Then, when the symbol combination of RB is stopped and displayed, the operation shifts to 1BB operation and RB operation (RB game).
When 1BB is activated and RB is not inside the RB, and when the symbol combination of RB is stopped and displayed in the game, 1BB is activated and 1RB is activated and RB is activated without shifting to the inside of RB. Transition.

As shown in FIG. 122, the operation of the 1BB condition device (1BB game) ends with the acquisition of more than 170 medals. Also, if the RB condition device operates while the 1BB condition device is operating (shifts to the RB game), it continues until 12 games or 8 prizes are won, provided that the number of medals does not exceed 170. To do. When the RB condition device is activated, when 12 games or eight winning combinations are won, and when more than 170 medals have not been acquired by the operation of the 1BB condition device, the 1BB condition device is again activated. The operation shifts when the RB condition device is not operating. In addition, when more than 170 medals are obtained by the operation of the 1BB condition device, whether the 1BB condition device is operating and the RB condition device is not operating, or the 1BB condition device is operating and the RB condition device is operating, The operation of the 1BB condition device is ended (even if the game of 12 times or the winning of 8 times is not reached after the operation of the RB condition device) (the 1BB game is ended).

After the operation of the 1BB condition device is completed, the process proceeds to RT1. RT1 continues until the 1400 game is exhausted or the symbol combination of 1BB is stopped and displayed. When moving to RT1, each game and the number of games are counted and stored in the number of RT games (_CT_RT_GAME) of the address “F00A(H)” described later. When the 1BB symbol combination is stopped and displayed at RT1, as described above, the operation shifts to the 1BB operation time and the RB non-inside. On the other hand, when 1400 games are exhausted at RT1, it shifts to non-RT. Once the non-RT is entered, 1BB is won again, and the RT1 is entered when the 1BB operation is completed.
In addition, in the twenty-third embodiment, the non-RT is set to be easier to win the AT than the RT1. Therefore, when the "1400" game is exhausted in RT1, it means that the player has reached the so-called ceiling, and it is easy to win the AT in non-RT.

Further, the advantageous section may be ended during RT1, but at the end of the advantageous section, the section type number, the advantageous section clear counter, the difference number counter (MY counter), and the AT-related data are cleared. On the other hand, the number of RT1 games (“_CT_RT_GAME” described above) is not cleared. For example, when the end condition of the advantageous section is satisfied at the 1200th game of RT1, the next game is the 1201st game of RT1 and the non-advantageous section.
Furthermore, in the twenty-third embodiment, the main game state described later does not shift even when shifting from RT1 to non-RT based on the digestion of 1400 games. For example, in the 1400th game of RT1, while staying in the main game state 1, the next game will be the non-RT and main game state 1.

However, when the condition for shifting the main gaming state is satisfied in the 1400th game of RT1, it goes without saying that the main gaming state shifts.
For example, firstly, in the main game state 1, when the number of RT1 and RT games is 1400, and the number of games in the advantageous section reaches 1500 games, the advantageous section ends in this game, and the next game is , Non-RT and main game state 0.
Secondly, in the main game state 1, when the number of RT1 and RT games is 1400, and the player wins the AT, the next game becomes the non-RT and main game state 2 (AT precursor).

Here, the transition determination of the advantageous section of the twenty-third embodiment is executed in the non-advantageous section of non-RT or RT1. In particular, in the transition determination of the advantageous section in the twenty-third embodiment, when the winning numbers “1” to “4” and “6” to “21” are won, the normal section is shifted to the advantageous section. ing. Therefore, in the non-RT or RT1 non-advantageous zone, if a few games are consumed, most of the game shifts to the advantageous zone. Once the advantageous zone is won, the transition to the advantageous zone is not determined unless the condition for ending the advantageous zone is satisfied and the advantageous zone is not transitioned to. Note that the transition of the advantageous section may be determined by lottery based on the winning number.

Further, the AT lottery of the twenty-third embodiment is executed in the non-RT or RT1 advantageous section. Further, in the twenty-third embodiment, carrying over the winning of 1BB is a condition for executing the AT lottery. In other words, the AT lottery is not executed when 1BB is not won and 1BB is operating. The AT lottery is executed when the winning numbers “3” to “9” corresponding to the rare replay are won.
In FIG. 127 (RT1), the AT winning probability is, for example,
Replay F condition device operation <Replay C condition device operation <Replay E condition device operation <Replay D (D1 to D3) condition device operation <Replay G condition device operation

Specifically, for example, when the Replay F condition device is operating: AT winning probability 10 to 30%
Replay C condition device operating: AT winning probability 15-30%
When the replay E condition device is activated: AT winning probability 20 to 35%
Replay D1 condition device activated: AT winning probability 30-50%
Replay D2 condition device operating: AT winning probability 40-50%
Replay D3 condition device operating: AT winning probability 35-80%
When Replay G condition device is activated: AT winning probability 100%
It is set like. There is a range in each winning probability because, for example, the winning probability is different in the performance stage (low probability, normal probability, high probability, etc.) when the condition device is activated.

In addition, when 1400 games are digested with non-AT and RT1, when the so-called ceiling is reached and the game is transferred to non-RT, AT is randomly selected with the following winning probability.
Replay F condition device activated: AT winning probability 90%
Replay C condition device activated: AT winning probability 90%
Replay E condition device activated: AT winning probability 90%
Replay D1 condition device activated: AT winning probability 75%
Replay D2 condition device activated: AT winning probability 80%
Replay D3 condition device operating: AT winning probability 85%
When Replay G condition device is activated: AT winning probability 100%
Therefore, the non-RT is set to be easier to win the AT than the RT1.

If you win the AT in non-RT or RT1 and after the AT start condition is satisfied (for example, after the AT standby counter becomes “0”), the symbol combination of 1BB is stopped and displayed, and 1BB is in operation ( When the game shifts to the 1BB game), AT can be started. Then, the AT continues until the 1BB operation is completed.
In non-RT or RT1, without having the right to execute the AT (without winning the AT), the symbol combination of 1BB is stopped and displayed, and even when the 1BB operation is in progress, when the push order bell is won (the winning number "" The push order (the push order for winning the 15-card combination) that is advantageous for 10" to "21" winning) is not displayed (the instruction function does not operate).
On the other hand, in non-RT or RT1, you have the right to execute the AT (win the AT), and after the AT start condition is satisfied, the 1BB symbol combination is stopped and displayed, and when the 1BB operation is in progress, , AT is executed, and the winning number having the correct answer pressing order is won, the correct answer pressing order for winning the winning combination of 15 sheets (higher bell) is displayed (the instruction function operates).
Even if the user has the right to execute the AT, the AT start condition is not satisfied (for example, when the AT precursor counter is larger than “0” or when the AT standby counter is larger than “0”). Even if the symbol combination of 1BB is stopped and displayed by ), the AT is not executed even if the 1BB operation is performed. That is, the push order bell is not displayed in the advantageous push order at the time of winning the bell (the instruction function does not operate).

Here, when the AT is in progress and the RB is not in the inside of the 1BB operation, the correct pressing order is displayed when the winning numbers “10” to “15” (small winning combination A1 to small winning combination A6) are won. (Actuation of indication function).
On the other hand, in AT, when 1BB is operating and in RB non-internal, even if the winning numbers “16” to “21” (small winning combinations B1 to B6) are won, the instruction function does not operate. As described above, when the small winning hands B1 to B6 condition device is operating during 1BB operation and RB non-internal operation, there is no correct pressing order, and no matter which pressing order the stop switch 42 is operated, one sheet is pressed. This is because the winning combination is won (15 winning combinations are not won).
On the other hand, when the AT is in operation and the RB is in the 1BB operation, the correct answer pressing order is displayed when the winning numbers “10” to “15” (small winning combination A1 to small winning combination A6) are won. (The indicator function operates).
Similarly, when the AT is in operation and the RB is in the 1BB operation, the winning order numbers "16" to "21" (small wins B1 to B6) are displayed when the correct answer is pressed (instruction). Function works).

In addition, the winning probability number of RB during 1BB operation is “28912” in total, and the winning probability thereof is about 44%. Therefore, when 1BB is in operation, the RB is won early. However, during the AT, it is a premise of the twenty-third embodiment that the game is consumed without winning the winning RB. When the inside of the RB is activated during the 1BB operation, as shown in FIG. 129, the total number of winning numbers “1” and “10” to “21” is, for example, “50424” in the setting 1. Therefore, there is a probability of being unwinned with a probability of about 23%, and there is a possibility of winning the RB in the game that has been won. In the non-winning game with the possibility of winning the RB, an effect is output to the player, which suggests that the game has the possibility of winning the RB. When this effect is output, the player operates the stop switch 42 to stop the RB from winning. It should be noted that, in a game having the possibility of winning an RB, the push position or the like is not notified by the display (for example, the acquired number display LED 78) on the main control board 50 side (the instruction function does not operate).
If an RB wins during 1BB operation, it shifts to the RB game. As described above, the RB game has a lower payout rate than the general game of the 1BB game. In the RB game, it is finished by winning the game 12 times or winning the role 8 times, and if the ending condition of the 1BB game (acquisition of more than 170 medals) is not satisfied at that time, it becomes the general game of the 1BB game again. Return.

FIG. 132 is a diagram showing a transition of a main game state in the 23rd embodiment.
The main gaming state of the twenty-third embodiment comprises a main gaming state 0 to a main gaming state 5.
The main game state 0 is a non-advantageous section, and the main game state 1 to the main game state 5 are advantageous sections.
Also, the main gaming states 2 and 3 have won the AT, but are non-AT gaming states. Further, the main game state 4 is a game state during AT. Furthermore, the main game states 0, 1, and 5 are non-AT and are not in AT winning states.

The main game state 0 is a non-advantageous zone and non-AT state. In the main game state 0, advantageous section lottery and AT lottery are executed. In the main game state 0, when the advantageous section is won and the AT is not won, the game state shifts to the main game state 1. On the other hand, in the main game state 0, when the advantageous section is won and the AT is won, the game state shifts to the main game state 2.

In the main game state 1, the advantageous section lottery is not executed, but the AT lottery is executed. When the player wins the AT, the game state shifts to the main game state 2. Further, when the AT is won, the number of AT sets is also selected by lottery, and the number of AT sets determined by the lottery is stored in the AT set number counter. The "AT set number" is a counter that determines how many times the main game state 4 (AT and 1BB operation) is executed.
On the other hand, in the main game state 1, when the end condition of the advantageous section is satisfied without winning the AT (for example, when the number of games of the advantageous section reaches 1500 games, or the winning lottery of the advantageous section is won). When), the main game state 0 is entered.

Even if the transition condition to the main game state 0 is satisfied in the main game state 1, RT does not shift. For example, in RT1 and main game state 1, when the end condition of the advantageous section is satisfied, the next game will be RT1 and main game state 0 unless 1400 games are reached in RT1.
The main gaming state 2 is a gaming state of an AT sign. At the time of winning the AT, the number of AT precursor games is determined by, for example, a lottery or the like, and is set in the AT precursor counter. Then, the main game state 2 is executed until the AT precursor counter becomes "0". When the AT precursor counter becomes "0", the main game state 3 is entered.

The main game state 3 is a game state during AT preparation. The main game state 3 continues until the AT standby counter becomes "0" and the symbol combination of 1BB is stopped and displayed. Here, in the twenty-third embodiment, when the AT has a plurality of sets, the main game state 4 (1BB operation and AT) to be described later is finished, and when returning to the main game state 3, the symbol combination of 1BB is swiftly set. In order to prevent the number of payouts from increasing too much, instead of displaying a stop and shifting to the main game state 4, in order to shift to the main game state 4 after performing a certain amount of payout adjustment (reduction), A certain number of games in the main game state 3 are ensured. For example, when shifting from the main game state 4 to the main game state 3, the AT standby counter is set to any one of "1" to "8" (determined by lottery), the game won in 1BB, or a small win or Subtract "1" for games that have not been won for replay. Then, when the AT standby counter becomes “0”, when the inside of 1BB is in progress, a notification for stopping and displaying the symbol combination of 1BB is given.
The reason why the payout adjustment (reduction) is performed in the main game state 3 is that when a plurality of sets of ATs are continuously executed, it is likely to be incompatible in the test shooting test. In the test shooting test, for example, the payout rate needs to be less than "220"% between arbitrary "400" game times. Therefore, in the case of executing a plurality of sets of AT, after the AT of one set ends, after the game section (the period during which payout adjustment (reduction) is performed) in which AT is not executed, the next set of ATs I'm trying to run.

Further, in the main game state 3, the addition lottery of the AT set number counter is executed. For example, when a rare combination (winning numbers “2” to “9”) is won in the main game state 3, an AT set number addition lottery is executed. When the AT set number addition lottery is won, the AT set number counter is added with the won AT set number.
In the main game state 3, when the AT standby counter becomes "0", the subsequent winning and replay condition device number "0" game, "aim for "blue BAR"! Is displayed as an image. In addition, aim at ""blue BAR"! The image is displayed on condition that the winning of 1BB has been carried over or the winning of 1BB has been won. This prompts the player to stop and display the 1BB symbol combination.

In addition, "aim for "blue BAR"! When the player cannot stop and display the symbol combination of 1BB in the game in which “” is displayed as an image, the subsequent winning and replay condition device number is “0” in the game, and “Aim for “blue BAR” again. !! Is displayed as an image. Also, first aim for "Ao BAR"! After the image is displayed, the AT set number addition lottery may not be executed. However, in the twenty-third embodiment, first, "aim for "blue BAR"!" Even after the image is displayed, the addition lottery for the number of AT sets is executed until the symbol combination of 1BB is stopped and displayed. However, the winning probability of the additional lottery of the AT set number is set so that there is no merit to the player even if the symbol combination of 1BB is intentionally stretched (the winning probability of the additional lottery of the AT set number is set to AT waiting. It is set lower than before the counter reached "0").

When the AT standby counter becomes "0" in the main game state 3 and the symbol combination of 1BB is stopped and displayed, the main game state 4 is entered. The main game state 4 corresponds to AT at the time of 1BB operation (1BB game). Therefore, the main game state 4 is executed until the number of medals acquired exceeds 170 (see FIG. 122). When the number of medals acquired exceeds 170 in the main game state 4, it is determined that the ending condition of the main game state 4 is satisfied, and the main game state is determined based on the values of the AT set number counter and the ending counter at that time. 3 (AT preparation), main game state 5 (AT pullback), main game state 0 (non-advantageous section).
The AT set number counter is decremented by "1" each time the main gaming state 4 ends. When the AT set number counter is "0", it is determined that the AT does not have the right to execute the AT, and when it is "1" or more, it is determined that the AT has the right to execute.

The ending counter is set based on the values of the difference number counter (also referred to as “MY counter”) and the advantageous section clear counter described in the other embodiments. The advantageous section must be ended when the difference counter reaches "2400 (D)" or when the number of games in the advantageous section becomes "1500". Therefore, in the present embodiment, when the difference counter value exceeds "1951 (D)" or when the advantageous section clear counter value becomes less than "200 (D)", the ending counter is set to "2". To do.
When the ending counter is "1" or more at the end of the main gaming state 4, "1" is subtracted. When the ending counter is changed from "1" to "0", it is determined that the end condition of the advantageous section (and AT) is satisfied, and the main game state 0 is entered. With this setting, the advantageous section can be ended before the difference counter value reaches "2400(D)" and before the advantageous section clear counter becomes "0".

On the other hand, at the end of the main game state 4, the AT set number counter is "1" or more, and the ending counter is changed from "1" to "0", it shifts to the main game state 3. When the state shifts to the main gaming state 3, the AT standby counter value is determined by lottery from "0" to "8" and set.
Further, when the AT set number counter is "0" at the end of the main game state 4, the main game state 5 (AT withdrawal) is entered. The main gaming state 5 is a non-AT, but when the AT is won in the main gaming state 5, the data of the number of acquired sheets and the number of sets in the previous AT are succeeded and displayed on the image display device 23 as an image.

When shifting to the main game state 5, a predetermined value, for example, "50 (D)" is set in the AT pullback counter, and each game "1" is subtracted. The ending condition of the main game state 5 is that the AT pullback counter has become “0” or that the AT has been won.
When the AT pullback counter becomes "0", the advantageous section clear counter value is determined, and when the advantageous section clear counter value is less than "600 (D)", the advantageous section is ended and the main game state is reached. Move to 0. When the advantageous zone clear counter value is less than “600 (D)”, if the game is transferred to the AT after that, the AT may not be able to continue because the remaining number of games in the advantageous zone is small. , The advantageous section ends. As described above, if the main game state 0 is entered, if several games are exhausted, the advantageous section is won again and at least the main game state 1 is entered.

On the other hand, when the AT pullback counter becomes "0" in the main game state 5, and the advantageous section clear counter value is "600 (D)" or more, the advantageous game is not ended and the main game is ended. Transition to state 1. Then, the AT lottery is continued.
Further, when the player wins the AT before the AT withdrawal counter becomes "0" in the main game state 5, the main game state 3 is entered. When the player wins AT in the main game state 5, it may move to the main game state 2 (AT sign), but in the present embodiment, it moves to the main game state 3 (AT preparation). When shifting to the main game state 3, similarly to the above, the AT waiting counter value lottery is executed, and the value determined by the lottery is stored in the AT waiting counter.

In the main game state 4 or 5, it is advantageous when shifting to the main game state 0 before the advantageous section clear counter becomes "0", and before the advantageous section clear counter becomes "0" in the main game state 1. When shifting to the main game state 0 based on winning the falling lottery of the section, before the advantageous section clear counter management of FIG. 51 is executed, the advantageous section clear counter is set (regardless of the values up to that point). A process of storing “1” is executed (preparation of advantageous section end shown in FIG. 150 described later). As a result, when the advantageous interval clear counter management of FIG. 51 is executed thereafter, the advantageous interval clear counter value is “1” before subtraction of “1” and “0” after subtraction of “1”. Therefore, it is determined that the end condition of the advantageous period is satisfied, and the process proceeds from step S424 to step S435 to execute the RWM clear process based on the end of the advantageous period.

In the main game state 0 or 1, even if the 1BB symbol combination is stopped and displayed, the main game state 4 (AT) is not entered. Therefore, in this case, the main game state 0 or 1, 1BB operation, and non-AT.

133 to 138 are diagrams showing main data according to the 23rd embodiment among the data stored in the RWM 53 in the 23rd embodiment. The data shown in FIGS. 133 to 138 is a part of data, and various data other than the illustrated data is stored in the RWM 53. In the following description (especially RWM name), “#” indicates all “1” (first reel 31) to “3” (third reel 31) and “1” to “3”. When referring to any one of
Also, the numerical value in parentheses in the "address" column indicates the number of bytes in the storage area.

In FIG. 133, the RT state number (_NB_RT_STS) of the address “F009(H)” is a storage area that stores data indicating the current RT, and when it is non-RT, “0” is stored and is RT1. At this time, "1" is stored. As shown in FIG. 131, in the twenty-third embodiment, there is a case of shifting from RT1 to non-RT, but "0" is stored as the RT state number at the end of a game that has reached "1400" game at RT1, for example, at the end of the game. To be done.
Further, when the ending condition of the 1BB operation is satisfied and the process shifts to RT1, "1" is stored as the RT state number at the end of the game of the game which satisfies the ending condition of the 1BB operation.

The RT game number (_CT_RT_GAME) of the address “F00A(H)” is a storage area of a counter for counting the RT1 number of games. When the 1BB operation is completed and the process shifts to RT1, "1400(D)" is stored in this storage area, and "1" is subtracted each time one game is completed. When the number of RT games becomes “0”, it is determined that the condition for transition to non-RT is satisfied.
The accessory condition device number (_NB_CND_BNS) at the address “F00D(H)” is a storage area for storing data indicating the type of accessory currently operating. The value stored here corresponds to the accessory condition device number shown in FIG. For example, "0" is stored when the accessory is not activated, "1" is stored when 1BB is activated, and "2" is stored when RBA is activated.

The obtainable number of sheets (_CT_BIG_PAT) at the time of 1BB operation of the address “F00E(H)” is a storage area for storing the remaining obtainable number of sheets at the time of 1BB operation (1BB game). When the 1BB operation is performed, "170(D)" is stored in this storage area. Then, during the 1BB operation (during the 1BB game), the value of this storage area is subtracted every time a medal is paid out. When the value of this storage area becomes "0" during the 1BB operation, it is judged that the termination condition of the 1BB operation is satisfied.

The number of games played during RB operation (_CT_BONUS_PLAY) at the address “F00F(H)” is a storage area that stores a counter that counts the number of games played during RB operation. When the RB is activated, "12(D)" is stored in this storage area, and "1" is subtracted for each "1" game during the RB activation. Then, when the number of games during RB operation becomes "0", the end condition of RB operation is satisfied.
The number of winning prizes (_CT_BONUS_WIN) at the time of RB operation of the address “F010(H)” is a storage area for storing a counter that counts the number of winning prizes of winning combinations at the time of RB operation. When the RB is activated, "8(D)" is stored in this storage area, and "1" is subtracted each time the winning combination of the winning combination is activated. Then, when the number of winnings during the RB operation becomes “0”, the ending condition of the RB operation is satisfied.

The input port level data A (_PT_IN_A_LV) of the address “F012(H)” is a storage area that stores ON/OFF of the signals of the start switch 41 and the stop switch 42. In the interrupt process this time, the signals of the start switch 41 and the (left, middle, right) stop switch 42 are determined, and "1" is stored when the switch is on, and "0" is stored when the switch is off. The input port level data A (previous) (_PT_IN_A_BK) of the address “F015(H)” is a storage area for storing the value of the input port level data A (_PT_IN_A_LV) in the previous interrupt processing.

The input port rising data A at the address “F017(H)” is a storage area for storing whether or not the signals of the start switch 41 and the stop switch 42 have risen. When the level data at the time of the previous interrupt processing is "0" and the level data at the current interrupt processing is "1", "1" is stored as the rising data. On the other hand, when the level data of the previous interrupt processing is "1" and the level data of the current interrupt processing is "1", the rising data is "0". Similarly, when the level data at the time of the previous interrupt processing is “0” and the level data at the time of the current interrupt processing is “0”, the rising data is “0”. Furthermore, when the level data of the previous interrupt processing is “1” and the level data of the current interrupt processing is “0”, the rising data is “0” (in this case, the falling data is “0”). 1”).

In FIG. 134, the first reel motor signal data (_PT_MOTOR1) at the address “F019(H)” is a storage area that stores which phase of the motor 32 related to the first reel is excited. In the first reel motor signal data, “1” corresponds to ON (excitation is applied), and “0” corresponds to OFF (excitation is not applied). Based on the data stored in this storage area, the motor 32 is excited in the port output process (step S462 of FIG. 151 described later) during the interrupt process.
In the present embodiment, the first reel corresponds to the left reel 31, the second reel corresponds to the middle reel 31, and the third reel corresponds to the right reel 31.

Further, in the first reel motor signal data, the D0 bit corresponds to φ1, the D1 bit corresponds to φ2, the D2 bit corresponds to φ3, and the D3 bit corresponds to φ4. One pulse data selected from a reel drive pulse table shown in FIG. 158 described later is stored in the first reel motor signal data. For example, as shown in FIG. 158, in the present interrupt processing, when the excitation for turning on φ0 and φ3 is applied, the pulse data “00001001(B)” of the address “1100(H)” is changed to the address “F019( H)”.

The second reel motor signal data (_PT_MOTOR2) at the address “F01A(H)” is a storage area that stores which phase of the motor 32 related to the second reel (middle reel 31) is excited. The content is the same as the first reel motor signal data (_PT_MOTOR1) of the address "F019(H)".
Similarly, the third reel motor signal data (_PT_MOTOR3) at the address “F01B(H)” is a storage area that stores which phase of the motor 32 related to the third reel (right reel 31) is excited. The content is the same as the first reel motor signal data (_PT_MOTOR1) of the address "F019(H)".

The first reel designation symbol position search waiting time (_TM2_TARPIC_WAIT) of the address "F039 (H)" is a timer value for measuring the waiting time for starting deceleration of the first reel 31 when executing the standby effect. Storage area. At the start of execution of the standby effect, a predetermined value is stored in this storage area, and "1" is subtracted for each interrupt process. Then, the stop of the first reel 31 is permitted on condition that the value of the storage area becomes "0". In other words, when the value of this storage area is not "0", the first reel 31 is kept rotating without being stopped.

Specifically, the reel effect execution timer table corresponding to the stop symbol is selected from reel effect execution timer tables 1 to 8 shown in FIG. 145 described later. For example, in FIG. 144, which will be described later, when the stop symbol is determined in “middle row “black BAR” complete” corresponding to standby effect number 1”, as a reel effect execution timer table corresponding to standby effect number 1, FIG. Medium reel execution timer table 1 (_TBL_TARPIC_TM1) is selected. Then, in the reel effect execution timer table 1, the designated symbol position search standby time of the first (left) reel 31 is "14112 (D)", so this value is stored in the address "F039 (H)". ..
When a predetermined value is stored in the first reel designated symbol position search waiting time at the address "F039(H)", "1" is subtracted for each interrupt process, and when the value becomes "0", the waiting time Is judged to have passed. Note that the specification may be such that instead of subtracting "1" for each interrupt process, "1" is subtracted for each of a plurality of interrupt processes.

Here, in the twenty-third embodiment, one rotation (360 degrees rotation) of the reel 31 at the constant speed corresponds to the “336” step of the motor 32. Since the motor 32 is driven by one step for every two interrupts, one rotation (360 degrees rotation) of the reel 31 at a constant speed corresponds to a "672" interrupt.
Therefore, in FIG. 145, for example, when the reel effect execution timer table 1 (_TBL_TARPIC_TM1) (standby effect 1) is selected, the left reel 31 is first stopped, and then the middle reel 31 is rotated approximately once ((“ 670" interrupt). Further, after the middle reel 31 is stopped, the right reel 31 is stopped after rotating about two times (after the “1340” interrupt). Similarly, when another reel effect execution timer table is selected, after the first reel 31 has stopped, the second reel 31 stops after rotating about one rotation or one rotation or more. Further, after the second reel 31 stops, the third reel 31 stops after rotating about two rotations or two or more rotations.
Further, the time from the stop of the second reel 31 to the stop of the third reel 31 is shorter than the time from the stop of the first reel 31 to the stop of the second reel 31. It is set long. This gives the player an expectation of which symbol the third reel 31 will stop, and gives the player time to enjoy watching the symbols of the first and second reels 31 stopped (feeling of achievement). Is possible.

The address "F039 (H)" is a storage area for the first (left) reel designated symbol position search wait time, but the second (middle) reel designated symbol position search wait time, and the third (right) reel An address "F03B(H)" and an address "F03D(H)" are provided as storage areas for the designated symbol position search standby time, respectively.
For example, in the above-described FIG. 145, when the reel effect execution timer table 1 (_TBL_TARPIC_TM1) is selected, the address “F03B(H)” is set to “14112+670” as the second (middle) reel designated symbol position search waiting time. =14782(D)" is stored. Similarly, at the address "F03D(H)", "14112+2010=16122(D)" is stored as the third (right) reel designation symbol position search standby time.

The waiting time (_TM2_WAIT) of the address "F041(H)" has carried over the winning information of 1BB, and when the symbol combination of 1BB can be stopped and displayed at the second stop, in other words, the symbol combination of 1BB is tempai. In the case of (when the symbols composing the symbol combination of 1BB at the time of the second stop are stopped on the activated line and the third stop is not yet made), in the storage area of the waiting time until the acceptance of the operation of the third stop is permitted. is there.
Here, "tempai", taking 1BB as an example, when one reel 31 is rotating and the remaining two reels 31 are stopped, the symbols forming the symbol combination of 1BB (on the effective line 2) Stop display, and when the symbols constituting the 1BB symbol combination are stopped and displayed when the one reel is stopped, the 1BB symbol combination is stopped and displayed (1BB is won). For example, when the one reel 31 is the right reel 31, it corresponds to a case where "blue BAR (upper left stage)"-"blue BAR (middle/middle stage)"-"rotating" on the activated line.

This standby time is not set in the state where the stop display of the symbol combination of 1BB is permitted (when the main gaming state 3 and the AT standby counter are "0"), but in other cases, the symbol combination of 1BB The standby time is set at the timing when the tempo is reached (at the time of the second stop). The initial value is “896(D)”. Then, the waiting time is subtracted for each interrupt processing, and when it becomes “0”, the third stop operation is accepted.
The interrupt cycle of the twenty-third embodiment is "1.117" ms.
In addition, in the twenty-third embodiment, if the symbol combination corresponding to 1BB is a game in which stop display is possible, 1BB is set not to be tempted. However, the present invention is not limited to this, and even in a game in which the symbol combination corresponding to 1BB cannot be stopped and displayed, 1BB may be enabled for tempe. For example, one BB can be tempted in a game when a small win is won. Then, in a game in which the symbol combination corresponding to 1BB cannot be stopped and displayed, it is possible not to set the waiting time even if 1BB is tempted.

Since "896(D)" is set as the standby time and "1" is subtracted for each interrupt, it waits for about 1 second (1.117 x 896 = about 1000 ms) from the timing when the 1BB symbol combination is tempted. The process (the process of not stopping the third reel 31 even if the third stop switch 42 is operated, in other words, the process of not accepting the stop operation of the third stop switch 42) is executed.
In addition, as described above, the reel 31 makes one rotation (360 degrees rotation), which corresponds to the step "336" of the motor 32 in the twenty-third embodiment. Further, in the twenty-third embodiment, one step of the motor 32 corresponds to two interrupts (2.234 ms), and the time during which the motor 32 drives for "336" steps, in other words, the time during which the reel 31 makes one rotation is “2.234×336=750.624 ms”.
Therefore, the waiting time (about 1000 ms) from the timing when the 1BB symbol combination is tempo> 1 rotation time of the reel 31 (about 751 ms)
Has become.
With this setting, it is possible to prevent the 1BB from winning due to an unexpected stop operation of the player while minimizing the waiting time.

On the other hand, the standby time is preferably set to, for example, a time (about 3 seconds) or less for which the reel 31 rotates four times. For example, when the third reel 31 is not stopped because the waiting time has not elapsed when the third stop switch 42 is operated, the player again pays attention to stop the third stop switch 42. This is because the operation is attempted, and it is desirable that the waiting time has elapsed at that time.

135 to 137, FIG. 135 shows data on the first reel 31, FIG. 136 shows data on the second reel 31, and FIG. 137 shows data on the third reel 31.
In FIG. 135, the first reel drive state (_WK_RL1_STS) at the address “F04D(H)” is a storage area that stores data indicating the drive state of the motor 32 related to the first reel 31. In the present embodiment, the excitation update timing is set once for every two interrupt processes. However, the present invention is not limited to this, and the excitation may be updated for each interrupt process, for example. When the excitation can be updated for each interrupt process, the cycle of the interrupt process may be set to every "2.235" ms. When the excitation is performed once by a plurality of interrupt processes as in the present embodiment, the D7 bit is assigned as a flag for determining whether it is the excitation update timing. In the present embodiment, when the D7 bit is "1", it indicates non-excitation update timing, and when it is "0", it indicates excitation update timing.
The D7 bit of this data is determined for each interrupt process and is updated to "1" when it is "0" and to "0" when it is "1".

Further, the lower 4 bits of D0 to D3 represent the reel drive state number. As shown in FIG. 135, "0" indicates stop, "1" indicates deceleration, "2" indicates acceleration, "3" indicates start of acceleration, "4" indicates start of deceleration, and "5" indicates constant speed. For example, when the interrupt process is the non-excitation update timing and the reel drive state is constant speed (“5”), “10000101(B)” is stored.

The first reel drive state of the address “F04D(H)” is for the motor 32 related to the first reel 31, but stores data indicating the drive state of the motor 32 related to the second reel 31. As the storage area, the drive state (_WK_RL2_STS) of the second reel at the address “F058(H)” (FIG. 136) is provided.
Further, the drive state (_WK_RL3_STS) of the third reel at the address “F063(H)” (FIG. 137) is provided as a storage area for storing data indicating the drive state of the motor 32 related to the third reel 31. ..

The first reel motor index (_FL_RL1_MT_IDX) of the address “F04E(H)” is a storage area for storing ON/OFF of the motor index signal of the first reel 31, and the signal acquired by the previous interrupt process is set to the D4 bit. The signal is stored and the signal obtained by the interrupt processing this time is stored in the D0 bit.
Here, the motor index 1 signal is a signal that is turned on when the reel sensor 33 is detecting the index of the first reel 31, and is turned off when the reel sensor 33 is not detecting the index of the first reel 31. Is.
Therefore, for example, when the first reel motor index is "00000000(B)", the motor index 1 signal is off in both the previous interrupt processing and the current interrupt processing (the reel sensor 33 detects the index. Does not mean). Further, when the first reel motor index is “00000001(B)”, the motor index 1 signal is off in the previous interrupt processing, and the motor index 1 signal is on in the current interrupt processing (reel sensor 33). Has detected the index) means (rising).

Furthermore, when the first reel motor index is "00010001(B)", it means that the motor index 1 signal is ON in both the previous interrupt processing and the current interrupt processing.
Further, when the first reel motor index is “00010000(B)”, the motor index 1 signal is on in the previous interrupt process, and the motor index 1 signal is off in the interrupt process this time (falling). Means

The first reel motor index of the address “F04E(H)” is the storage area for the left reel 31, but the storage area of the reel motor index of the second reel 31 is the address “F059(H)” (FIG. The second reel motor index (_FL_RL2_MT_IDX) of (136) is provided.
Further, as a storage area indicating the reel motor index of the third reel 31, the third reel motor index (_FL_RL3_MT_IDX) of the address “F064(H)” (FIG. 137) is provided.

The first reel drive pulse output counter (_CT_RL1_PLSOUT) at the address “F04F(H)” is a storage area that stores a value corresponding to the number of interrupts for switching the excitation of the motor 32 related to the first reel 31. Specifically, in the acceleration/deceleration pulse output counter table (TBL_PULSE_UP) shown in FIG. 156 described later, the value corresponding to the current step number is stored in this storage area. For example, in the case of the first step during acceleration, the value "25(D)" corresponding to the address "1058(H)" is stored in this storage area. Then, "1" is subtracted for every two interrupt processes, and when it becomes "0", the value "25(D)" of the next second step is stored in this storage area, and "2" is stored for each two interrupt processes. Subtract 1" at a time. Furthermore, at the time of deceleration, the value "90 (D)" corresponding to the address "1050 (H)" is stored in this storage area, and "1" is subtracted every two interrupt processing. However, when the reel 31 is stopped, at a constant speed, or when deceleration is started, "1" is stored in this storage area, and "1" is not subtracted at the time of interrupt processing.

The first reel drive pulse output counter (_CT_RL1_PLSOUT) at the address “F04F(H)” is a storage area for the motor 32 related to the first reel 31, but a drive pulse for the motor 32 related to the second reel 31. As a storage area of the output counter, a second reel drive pulse output counter (_CT_RL2_PLSOUT) is provided at the address “F05A(H)” (FIG. 136).
As a storage area of the drive pulse output counter for the motor 32 related to the third reel 31, the third reel drive pulse output counter (_CT_RL3_PLSOUT) is provided at the address “F065(H)” (FIG. 137).

The first reel drive pulse switching count (_CT_RL1_PLSCHG) at the address “F050 (H)” is a storage area that stores the number of drive pulse switchings during acceleration of the motor 32 related to the first reel 31. As shown in FIG. 156 (acceleration/deceleration pulse output counter table (TBL_PULSE_UP)) described later, when the reel 31 is accelerated, the pulse is switched eight times from the first step to the eighth step. Therefore, the initial value of the number of times the first reel drive pulse is switched is set to "9", and when "1" is first subtracted to "8", the first reel drive pulse output counter (_CT_RL1_PLSOUT) described above The value "25(D)" corresponding to the first step is stored. As described above, the first reel drive pulse output counter is decremented by "1" every two interrupt processes during acceleration or deceleration. When the first reel drive pulse output counter reaches "0", "1" is subtracted from the number of times the first reel drive pulse has been switched. In this way, “1” is decremented each time the first reel drive pulse output counter becomes “0” until the number of times of switching the first reel drive pulse becomes “0”.

The first reel drive pulse switching count (_CT_RL1_PLSCHG) at the address “F050(H)” is the storage area for the motor 32 related to the first reel 31, but the storage area for the motor 32 related to the second reel 31. As a result, the address “F05B(H)” (FIG. 136) is provided with the number of times the second reel drive pulse has been switched (_CT_RL2_PLSCHG).
As a storage area for the motor 32 related to the third reel 31, the third reel drive pulse switching count (_CT_RL3_PLSCHG) is provided at the address “F066(H)” (FIG. 137).

The first reel rotation defect detection counter (_CT_RL1_BAD) at the address “F051(H)” is a storage area of the counter for determining whether the rotation of the first reel 31 is normal or abnormal (step-out). The first reel rotation failure detection counter stores "0" as an initial value when the first reel 31 becomes a constant speed. Then, when the first reel 31 is at a constant speed, "1" is added, and when the value after adding "1" becomes "0" (that is, the value before addition is "255 (D)"). Yes, when the result of adding “1” is that the digit is carried up and the zero flag is “1”), it is determined that the rotation of the first reel 31 is not normal.
When it is determined that the value of the first reel motor index (_FL_RL1_MT_IDX) has changed after the first reel 31 has reached the constant speed, the first reel rotation failure detection counter is cleared.

The first reel rotation defect detection counter (_CT_RL1_BAD) at the above address “F051(H)” is the storage area for the first reel 31, but as the storage area for the second reel 31, the address “F05C(H)” is used. (FIG. 136), a second reel rotation failure detection counter (_CT_RL2_BAD) is provided.
As a storage area for the third reel 31, a third reel rotation defect detection counter (_CT_RL3_BAD) is provided at the address “F067(H)” (FIG. 137).

The step number (_NB_RL1_STEP) of one symbol of the first reel at the address "F052(H)" is a storage area for storing the step number when the first reel drive state is constant speed or deceleration start.
When the first reel motor index (_FL_RL1_MT_IDX_) rises, “3” is stored as the initial value (design value).
Further, when the first reel driving state is constant speed or deceleration start, "1" is subtracted at the excitation update timing, and when it becomes "0", it is determined that one symbol has moved.
When it is determined that the symbol has moved by one symbol, when the symbol numbers are "2", "7", "12", and "17", "16(D)" is stored as the initial value, and other than that. If it is a symbol number of “7(D)”, it is stored as an initial value.
The number of steps in one rotation of the motor 32 of the twenty-third embodiment is "336", and the number of symbols on the reel 31 is "20". Therefore, for four symbols, the number of steps for one symbol is "16", For 16 symbols, the number of steps for one symbol is set to “17” (4×16+16×17=336). That is, since one symbol is assigned to be 16 steps at substantially equal intervals, when the reel 31 is stopped, it is configured to stop at the center of the symbol as much as possible.

The step number (_NB_RL1_STEP) of the one symbol of the first reel at the address "F052(H)" is the storage area for the first reel 31, but the address "F05D( H)” (FIG. 136), the step number (_NB_RL2_STEP) of one symbol on the second reel is provided.
As a storage area for the third reel 31, a step number (_NB_RL3_STEP) for one symbol of the third reel is provided at the address “F068 (H)” (FIG. 137).

The first reel symbol number (for passing position) (_NB_RL1_PASPIC) of the address "F053(H)" is a storage area for storing the symbol number of the first reel 31 which is currently passing. As an initial value, “255(D)(FF(H))” is stored. Then, when it is determined that the first reel motor index (_FL_RL1_MT_IDX) has changed, "10(D)" is stored at the time of rising (D0 bit is "1", D4 bit is "0"). At the time of falling (D0 bit is "0" and D4 bit is "1"), "0" is stored.

In this way, “255(D)” is stored as the initial value until the value of the first reel motor index changes. When it is determined that the value of the first reel motor index has changed, "10(D)" is stored at the time of rising and "0" is stored at the time of falling.
Further, the first reel symbol number (for passing position) (_NB_RL1_PASPIC) is added to "1" every time it is determined that the symbol has moved by one symbol after "10(D)" or "0" is stored. ..

The first reel symbol number (for passing position) (_NB_RL1_PASPIC) of the address "F053(H)" is the storage area for the first reel 31, but the address "F05E" is used as the storage area for the second reel 31. (H)” (FIG. 136), a second reel symbol number (for passing position) (_NB_RL2_PASPIC) is provided.
As a storage area for the third reel 31, a third reel symbol number (for passing position) (_NB_RL3_PASPIC) is provided at the address “F069(H)” (FIG. 137).

The first reel symbol number (for stop position) (_NB_RL1_PASPIC) of the address "F054(H)" is a storage area for storing the symbol number of the stop position (4 phase excitation is applied). As an initial value, “255(D)(FF(H))” is stored. Then, when the first stop switch 42 is operated and the stop position is determined, the determined symbol number is stored in this storage area.

The first reel symbol number (for stop position) (_NB_PL1_STPPIC) of the above-mentioned address "F054(H)" is the storage area for the first reel 31, but as the storage area for the second reel 31, the address "F05F" (H)” (FIG. 136), the second reel symbol number (for stop position) (_NB_RL2_STPPIC) is provided.
As a storage area for the third reel 31, a third reel symbol number (for stop position) (_NB_RL3_STPPIC) is provided at the address “F06A(H)” (FIG. 137).

The first reel drive pulse data search counter (_CT_RL1_PLUS) at the address “F055(H)” is a storage area of the counter for determining the excitation phase of the first reel 31. The first reel drive pulse data search counter is incremented by "1" at each excitation update timing. Further, "0" is added when the first reel 31 is normally rotated, and "254 (D) (FE (H))" is added when the first reel 31 is reversely rotated. For example, when the counter value stored up to that point is "100 (D)", "1" is added to become "101 (D)". Further, when the first reel 31 is rotating in the reverse direction, “254 (D)” is added to become “99 (D)”. In other words, adding “254(D)” is the same as subtracting “1”. In this way, the first reel drive pulse data search counter takes a value in the range of "0" to "255 (D)".

When the logical product (AND) of the first reel drive pulse data search counter value and "00000111 (B)" is executed, the values of "0" to "255 (D)" are "0" to "7". Is converted to the value of. Then, the drive pulse data corresponding to the values of “0” to “7” is set. For example, when the converted value is “7”, the drive pulse stored in the address “1107 (H)” corresponding to the offset value “7” in the reel drive pulse data table (TBL_REEL_PULSE) in FIG. 158. The data “00001000(B)” is set, and the excitation for turning on φ3 is executed.

The first reel drive pulse data search counter (_CT_RL1_PLUS) at the above address “F055(H)” is the storage area for the first reel 31, but as the storage area for the second reel 31, the address “F060( H)” (FIG. 136), a second reel drive pulse data search counter (_CT_RL2_PLUS) is provided.
As a storage area for the third reel 31, a third reel drive pulse data search counter (_CT_RL3_PLUS) is provided at the address “F06B(H)” (FIG. 137).

The first reel rotation start waiting counter (_CT_RL1_WAIT) at the address “F056 (H)” is a counter for random delay of the first reel 31 after the standby effect.
Here, "random delay" will be described.
When the standby effect is executed and the reels 31 are automatically stopped without the player's operation of the stop switch 42, if all reels 31 are simultaneously (simultaneously) rotated after the reels 31 are automatically stopped, the push assist is performed. May lead to Therefore, when the reels 31 are automatically stopped by the standby effect and then restarted, a delay time at the start of rotation is set for each reel 31 so that the rotation start timing of each reel 31 is random. To be set. Such control is called "random delay".

When the standby effect is not executed, "0" is stored in this storage area. Further, when the standby effect is executed, a value is determined by lottery or the like from the values of “0” to “335(D)” and the determined value is stored. Then, "1" is subtracted for each interrupt process, and when it becomes "0", the restart of the first reel 31 is permitted.

The first reel rotation start waiting counter (_CT_RL1_WAIT) at the above address “F056 (H)” is the storage area for the first reel 31, but as the storage area for the second reel 31, the address “F061 (H) (FIG. 136), a second reel rotation start waiting counter (_CT_RL2_WAIT) is provided.
As a storage area for the third reel 31, a third reel rotation start waiting counter (_CT_RL3_WAIT) is provided at the address “F06C(H)” (FIG. 137).

In FIG. 138, the section type number (_NB_ADV_KND) of the address “F070(H)” is a storage area that stores a number indicating whether or not it is an advantageous section. "1" is stored in the advantageous zone, and "0" is stored in the non- advantageous zone. This storage area is the same storage area as the advantageous section type flag of the address “F061(H)” shown in FIG. 35 in the eleventh embodiment.
The AT flag (_FL_AT) of the address “F078(H)” is a flag for determining whether or not the AT is won. When the AT is won, "1" is stored, and when the AT is not won, "0" is stored. This storage area is the same storage area as the AT flag of the address "F067(H)" shown in FIG. 35 in the eleventh embodiment.

The advantageous section clear counter (_CT_ADV_CLR) of the address “F07A(H)” is a storage area of a game number counter (decrement counter) of the advantageous section. When shifting to the advantageous section, the initial value "1500 (D)" is set, and "1" is subtracted for each game during the advantageous section. Then, when it becomes “0”, the end condition of the advantageous section is satisfied. This storage area is the same storage area as the advantageous section clear counter of the address “F063(H)” shown in FIG. 35 in the eleventh embodiment.

The difference number counter (also referred to as “MY counter”) (_CT_MY) of the address “F07C(H)” is a counter (increment counter) that stores a value corresponding to the accumulated value of the difference number in the advantageous period.
The difference number counter does not simply store the cumulative value of the difference number itself, but stores a “value corresponding to” the accumulated value of the difference number. For example, when the difference number becomes a value corresponding to minus, the value is corrected to "0 (H)". Therefore, “cumulative number of difference sheets≠difference number counter value”. In other words, the difference number counter stores a value which is "0" at the time when the cumulative value of the difference number is most decreased in the advantageous section.

Further, when the difference number counter value exceeds “2400(D)”, it is determined that the condition for ending the advantageous section is satisfied. Therefore, the maximum value that can be taken by the difference counter is "2399 (D)" in the current game, and is "2414 (D)" when 15 coins are paid out in the next game.
Note that the difference counter suffices to count at least the cumulative value of the number of difference sheets in the advantageous section, and it is not necessary to count in the non-advantageous section (normal section), but it continues counting including the non-advantageous section. It may be a counter.
This storage area is a storage area similar to the difference number counter of the address "F065(H)" shown in FIG. 35 in the eleventh embodiment.

The main game state number (_NB_GAM_STS) of the address "F07E(H)" is a storage area for storing the number of the main game state. As shown in FIG. 132, in the twenty-third embodiment, the main game states 0 to 5 are provided, and the number of the main game state currently staying is stored in this storage area. When there is a transition to the main gaming state, the value in this storage area is updated.
The AT predictor counter (_CT_AT_ZN) of the address “F080(H)” is a storage area of the counter of the predictive number of AT games. When the AT is won, the number of AT predictive games is determined from the range of, for example, "0" to "33", and the determined number of games is stored in this storage area. Then, in the AT sign, that is, in the main game state 2, each game, subtracting "1" from the AT sign counter, and when it becomes "0", it is determined that the end condition of the AT sign (main game state 2) is satisfied. To do.

The ending counter (_CT_ENDING) of the address “F097 (H)” is advantageous when the difference number counter value exceeds “1951 (D)” when the AT set number counter value described later is “1” or more. This is a storage area of a counter for setting an initial value “2” when the section clear counter value becomes less than “200 (D)”.
When the ending counter is "1" or more at the end of the main gaming state 4, "1" is subtracted. When the ending counter is changed from "1" to "0", it is determined that the end condition of the advantageous section (and AT) is satisfied, and the main game state 0 is entered. Therefore, after "2" is set in the ending counter, the AT can be executed up to two sets including the set AT in which "2" is set in the ending counter.

The AT wait counter (_CT_AT_WAIT) at the address “F098(H)” is a storage area of a counter for managing AT activation. When the AT set number counter is “1” or more, after the main game state 4 (AT) ends, the main game state 3 (AT preparing) is entered. Then, in this main game state 3, a value for managing whether or not to permit the stop display of the 1BB symbol combination is the AT standby counter value. In other words, it is a counter for cutting a fixed number of balls in the main game state 3. The AT standby counter is determined and stored from the range of "0" to "8" when the main game state 4 is shifted to the main game state 3, for example.

In the main game state 3, the AT standby counter value is decremented by "1" in the game won to 1BB or the game in which the small win or replay is not won in 1BB (the game in which 1BB can be won). .. Then, after the AT standby counter becomes "0", the effect of urging the winning of 1BB in a game in which the symbol combination of 1BB can be stopped and displayed (i.e., a game in which a small win or replay has not been won) (for example, "Aim for "Blue BAR"!") is output. When the symbol combination of 1BB is stopped and displayed, the main game state 4 is entered.

In the main game state 3, when 1BB is won before the AT standby counter reaches "0", the main game state 3 remains and the main game state 4 (AT) is not entered. Therefore, 1BB is in operation and non-AT (AT is preparing). In this case, the AT standby counter is reset after the completion of the 1BB operation. It should be noted that the AT standby counter stored until then may be taken over without resetting. By doing so, even if the symbol combination corresponding to 1BB is erroneously stopped and displayed, it is possible to prevent further disadvantage to the player.

The AT set number counter (_CT_AT_SET) at the address “F09C(H)” is a storage area for storing the AT set number. At the time of winning the AT, the number of AT sets is determined by lottery, and the determined number of AT sets is stored in this storage area. Furthermore, in the main game state 3 (AT is being prepared), an AT set number addition lottery is executed according to the winning combination, and when this addition lottery is won, the winning addition number is added to the AT set number counter.

At the end of the main game state 4, it is determined whether the AT set number counter is "1" or more. When the AT set number counter is "1" or more, it is determined that the AT continuation condition is satisfied. Then, the main game state 3 is entered, and when the AT set number counter is "0", it is determined that the AT continuation condition is not satisfied, and the main game state 5 is entered. When shifting from the main gaming state 4 to the main gaming state 3, the AT set number counter is decremented by "1".
Further, even when the number of AT sets is "1" or more, when the ending counter changes from "1" to "0" at the end of the main game state 4, the end condition of the advantageous section (AT) is satisfied. When judged, the main game state 0 is entered and the AT set number counter is cleared. Here, as an example of a method of shifting to the main game state 0 and a method of clearing the AT set number counter, RWM initialization processing executed at the end of the advantageous section by the advantageous section clear counter management (step S435 in FIG. 51). Is mentioned.

The AT pullback counter (_CT_AT_BACK) of the address "F09D(H)" is a storage area of a counter of the number of remaining games to be pulled back by AT. When shifting from the main game state 4 to the main game state 5, the initial value "50(D)" is set, and in the main game state 5, every game, "1" is subtracted. Then, when the AT withdrawal counter becomes “0” without winning the AT, it is determined that the ending condition of the main game state 5 is satisfied, and the main game state 0 or 1 is entered.
When the player wins the AT in the main gaming state 5 and shifts to the main gaming state 3, the AT pullback counter is cleared.

The standby effect type (_WK_PRD) of the address “F09E(H)” is a storage area for storing the type of the standby effect number.
Here, the “standby effect” in the twenty-third embodiment means that when the start switch 41 is operated, the reel 31 is rotated in the reverse direction, and a predetermined symbol combination (for example, ““ It is a reel effect (also referred to as a freeze effect) for stopping and displaying the "black BAR" set. As the standby effect, the reel 31 is normally rotated when the start switch 41 is operated, and a predetermined symbol combination (for example, “black BAR” alignment) is stopped and displayed without the player operating the stop switch 42. Things may be included. Alternatively, as a standby effect, the reel 31 is rotated forward when the start switch 41 is operated, and a predetermined symbol combination (for example, “black BAR” complete) is stopped and displayed without the player operating the stop switch 42. It may consist of only one thing.

In the standby effect, a case of executing as an effect indicating confirmation of AT winning (for example, stopping and displaying “black BAR” or “red 7”) or an effect of inspiring AT winning expectation (for example, , “Stop displaying the “watermelon” set, etc.)”.
When it is determined to execute the standby effect, "2" is stored when any one of the standby effect numbers "1" to "4" (address "F0A0(H)" described later) is determined. , "3" is stored when any of the three combination numbers of "5" to "8" (address "F0A1(H)" described later) is determined. Further, in the standby effect start (M_TARPIC_EXE) of FIG. 143 described later, it is cleared in step S835.

The search counter update correction data (_WK_PLS_REV) at the address “F09F(H)” is a storage area that stores data that determines whether the normal rotation or the reverse rotation is performed in the standby effect. When the standby effect is normal rotation, "0" is stored, and when it is reverse rotation, "FE(H)" is stored.
When starting the standby effect, it is determined whether or not the value stored in the above-mentioned standby effect type (_WK_PRD) is "0", and when it is not "0", that is, the standby effect (in the 23rd embodiment, When executing the reverse rotation, “FE(H)” is stored in the search counter update correction data (_WK_PLS_REV).
When the standby effect is finished, this storage area is cleared (“0” is stored).

The standby effect number (_NB_PRD_NO) of the address “F0A0(H)” is a storage area of a number for managing the standby effect indicating the AT winning confirmation. As shown in FIG. 138, “1” to “4” are stored according to the stop symbol. The standby effect number “4” corresponds to the number for temporarily stopping and displaying the “red 7” group and then re-changing it to stop and display the “black BAR” group. The number of winning ATs set and the symbol combination stopped and displayed by the standby effect are set to be associated with each other.

The three-role number (_NB_TRIO) of the address “F0A1(H)” is a storage area of a number for managing the standby effect showing the AT winning expectation level. For example, in the main game state 1, when the rare replay (the winning numbers “3” to “9” in FIG. 126) is won, the three winning numbers are determined by lottery and set at the end of the game. For example, when the three winning combination number "5" is determined, the middle "Watermelon" lineup is stopped and displayed by the standby effect, triggered by the operation of the start switch 41 for starting the next game. The AT winning expectation degree and the symbol combination stopped and displayed by the standby effect are set to be associated with each other.

The winning and replay condition device number (_NB_CND_NOR) of the address “F0A9(H)” is stored when the winning number is determined in this game and the replay and winning condition device operated in this game is determined. Area. As shown in FIG. 126, when the winning numbers “1” to “24” are won, “1” to “24” are stored as the winning and replay condition device numbers of the game, respectively.
The accessory condition device number (_NB_CRRT_BNS) of the address “F0AA(H)” is a storage area for storing the accessory condition device number when the prize is won. As shown in FIG. 126, when the winning numbers “25” to “41” are won, “1” to “17” are stored as the accessory condition device numbers of the game.

The minimum game time (_TM2_GAME) of the address "F0AB(H)" is a timer for monitoring the minimum game time once, and when it is determined that the minimum game time has elapsed, the interrupt count "3672(D)" is set. To count, an initial value is set (step S767 in FIG. 140 described later). The minimum game time of this embodiment is set to about "4.1" seconds (1.117 ms x 3672 ≈ 4100 ms).
When the minimum game time is set in the game this time, in the next game, the rotation of the reel 31 is started on condition that the minimum game time is "0".

Of the data of the RWM 53 described above, when the advantageous section is ended, the data regarding the advantageous section and the AT is cleared.
In the twenty-third embodiment, as in the eleventh embodiment, the game end check process (FIG. 148) is executed at the end of the game, and the advantageous section clear counter management in step S945 is executed. The advantageous section clear counter management is the same as the processing shown in FIG. 51 or FIG.

Therefore, when the advantageous section clear counter (“_CT_ADV_CLR” of the address “F07A(H)”) becomes “0” (“Yes” in step S424 in FIG. 51 or FIG. 52), the process proceeds to step S435. Then, the data of the RWM 53 regarding the advantageous section and the AT is cleared.
In the twenty-third embodiment, as the data to be cleared at the end of the advantageous section, the section type number (_NB_ADV_KND), AT flag (_FL_AT), difference number counter (MY counter) (_CT_MY), AT precursor counter (_CT_AT_ZN), ending counter. (_CT_ENDING), AT standby counter (__CT_AT_WAIT), AT set number counter (__CT_AT_SET ), AT pullback counter (_CT_AT_BACK ), standby effect type (_WK_PRD ), standby effect number (_NB_PRD_NO), three winning number (_NB_TRIO).
On the other hand, as the data that is not cleared at the end of the advantageous section, the RT state number (_NB_RT_STS), the RT game number (_CT_RT_GAME), and the main game state number (_NB_GAM_STS) are listed.
Therefore, as described above, the current game is the 1000th game of RT1, and when the advantageous section ends in the current game, the next game becomes the non-advantageous section and the 1001st game of RT1.

Further, the RT state number (_NB_RT_STS) and the number of RT games (_CT_RT_GAME) are not initialized even when the power is turned on/off or the setting is changed.
Therefore, for example, even if the power is turned off at the 1000th game of RT1 and the setting change process is executed, the first game after the return is started from the 1001st game of RT1. However, not limited to this, when the setting change process is executed, the RT state number (_NB_RT_STS) is not initialized, but the RT game number (_CT_RT_GAME) may be initialized. Alternatively, when the setting change process is executed, both the RT state number (_NB_RT_STS) and the RT game number (_CT_RT_GAME) may be initialized.

Furthermore, the RT state number (_NB_RT_STS) and the number of RT games (_CT_RT_GAME) are not initialized only by turning on/off the power, but when the setting change process is executed, at least the number of RT games (_CT_RT_GAME) is initialized. Good.
When the power is turned on/off, the number of (non-AT) games displayed on the image display device 23 is set to "0". This point will be described later.

Next, in the twenty-third embodiment, each process during the game will be described using a flowchart.
FIG. 139 is a flowchart showing the main processing (M_MAIN) by the main control board 50. This flowchart corresponds to FIG. 41 of the eleventh embodiment. In FIG. 139, the same steps as those in FIG. 41 are designated by the same step numbers. Also, in FIG. 139, steps different from those in FIG. 41 are underlined in step numbers.
Hereinafter, differences from FIG. 41 will be mainly described.
In FIG. 139, if it is determined in step S278 that the start switch 41 has been operated, the process advances to step S751 to execute a start switch acceptance process (M_START_CTL). The start switch 41 is determined to have been operated when the D6 bit of the input port rising data A (_PT_IN_A_UP) at the address "F017(H)" in FIG. 133 becomes "1".

When the process proceeds to the start switch acceptance process (M_START_CTL) in step S751, the process proceeds to the process of FIG. 140 described later.
Next, proceeding to step S752, a reel stop acceptance check (M_STOP_CHK) is executed. This process is a process shown in FIG. 146 described later. Then, the reel stop acceptance check (M_STOP_CHK) is executed for each reel 31 until it is determined in the next step S289 that all reels 31 have stopped.
Further, in FIG. 139, the game end check process (M_GAME_CHK) (step S753) in the twenty-third embodiment executes the process shown in FIG. 148 described later.

FIG. 140 is a flowchart showing the start switch acceptance processing (M_START_CTL) in step S751 of FIG. 139.
In step S761, a lottery process for a winning combination is executed. In this process, the winning lottery means 61 performs a lottery of winning numbers. For example, when the game is non-RT this time, the winning number is determined according to the number table shown in FIG. When the winning number is determined, the winning and replay condition device number corresponding to the determined winning number is stored in the storage area of the address "F0A9(H)", and the accessory condition device number corresponding to the determined winning number is stored. , In the storage area of the address “F0AA(H)”.

In the next step S762, the main control board 50 determines the transition of the advantageous section. As described above, when the winning numbers “1” to “4” and “6” to “21” are won, it is determined to shift from the normal section to the advantageous section.
Here, when it is decided to shift to the advantageous section, "1" is set to the section type number (address "F070(H)").

In the next step S763, a game start time process in the main game state is executed. This processing executes processing such as lottery and counter updating according to the main game state of the current game.
For example, when the main game state is 0, 1, or 5, the AT lottery is executed. As described above, when the rare replay (any of the winning numbers “3” to “9”) is performed, the AT lottery having the number “1” or more is executed. When the AT is won, the AT flag (address "F078(H)") is set to "1", and the AT set number determined by lottery is stored in the address "F09C(H)".

When the main gaming state 2 is set, "1" is subtracted from the AT precursor counter (address "F080(H)").
Furthermore, when it is the main game state 3, "1" is subtracted from the AT standby counter (address "F098(H)").
Further, when in the main game state 5, "1" is subtracted from the AT pullback counter (address "F09D(H)").

In the next step S764, a symbol stop signal set (S_IF_SET) is executed. This process is a process shown in FIG. 141, which will be described later, and is a process for outputting a test signal regarding the operation timing and the pushing order of the stop switch 42 to the tester side. Note that when the gaming machine is actually installed in the hall (store), the gaming machine is not connected to the testing machine, and thus the test signal is not actually received by the testing machine. However, since the symbol stop signal set (S_IF_SET) exists in the program of the main processing, even after the gaming machine is installed in the hall, a test signal for each game, the operation timing of the stop switch 42 and the pressing order is provided. The process itself for outputting is executed.
In the next step S765, standby effect start (M_TARPIC_EXE) is executed. This process is a process shown in FIG. 143, which will be described later, and corresponds to a process of executing a standby effect when the start switch 41 is operated.

In the next step S766, the main control board 50 determines whether or not the minimum game time has elapsed. This process is a process of determining whether or not the value stored in the address “F0AB(H)” is “0”. If it is determined that the minimum game time is "0", then the flow proceeds to step S767. In step S767, the initial value "3672 (D)" of the minimum game time is stored in the address "F0AB (H)". From this point, "1" is subtracted for each interrupt process, and it is determined in step S766 of the next game whether or not the minimum game time has become "0". In the next step S768, the main control board 50 sets the acceleration start state. This process stores "3" (00000011 (B)) indicating acceleration start in the first reel drive state (_WK_RL1_STS ), the second reel drive state (_WK_RL2_STS ), and the third reel drive state (_WK_RL3_STS ). Is. Then, the processing according to this flowchart is ended.

141 is a flowchart showing the symbol stop signal set (S_IF_SET) in step S764 in FIG. 140.
Here, prior to the explanation of FIG. 141, the stop acceptance designation tables 1 and 2 will be explained.
142 is a diagram showing a symbol stop signal table, (A) shows the symbol stop signal table 1 (TBL_ORD_INF1), (B) shows the symbol stop signal table 2 (TBL_ORD_INF2).

As shown in FIG. 141(A), the stop acceptance designation table 1 (TBL_ORD_INF1) stores two types of symbol stop signal data. Further, each symbol stop signal data is composed of four data.
First, the symbol stop signal data at the time of (1) "character condition device number = 1, and main game state number 3 and AT standby counter = 0" is data "0, 16, 7, 2". .. Here, "feature condition device number = 1, and main game state number 3 and AT standby counter = 0" means that the inside of 1BB, the main game state 3 (AT preparation), and the AT standby counter Is “0”, that is, when 1BB can be won.
This data is data for aiming the "blue BAR" as a set to the effective line.
The four data of the symbol stop signal data are data of "pushing order, stop operation position of left reel 31, stop operation position of middle reel 31, stop operation position of right reel 31".

First, the data of the pressing order has “0” to “5”. “0” indicates the pressing order 123, “1” indicates the pressing order 132,..., “5” indicates the pressing order 321. Here, each symbol stop signal data of the stop acceptance designation table 1 (TBL_ORD_INF1) of (A) is the symbol stop signal data at the time of the game in which the instruction function is not actually operating, but as a pressing order, the pressing order It is set to 123. Instead of the push order 123, push order data indicating another push order may be used.
Further, the stop operation position of the left reel 31, the stop operation position of the middle reel 31, and the stop operation position of the right reel 31 all point to the symbol numbers aimed at the lower stage.
For example, in the symbol stop signal data of (1) of the stop acceptance designation table 1, the data indicating the stop operation position of the left reel 31 is “16”. Here, as shown in FIG. 114, if the 16th "watermelon" of the left reel 31 is aimed to stop in the lower left stage, the 18th "blue BAR" can be stopped in the effective line (upper left stage). Become.
In the above example, the data indicating the stop operation position centering on the lower stage is stored, but the data indicating the stop operation position centering on the middle stage or the upper stage may be stored. In any case, the effective line of the present embodiment is an irregular line that descends to the right, whereas the data indicating the stop operation position is set in a horizontal straight line (set along the effective line. However, when the tester side conducts the test according to the test signal, it is possible to perform the stop operation at a predetermined timing without being influenced by the active line. As a result, the processing load on the test machine side and the processing load on the gaming machine side can be reduced.

Further, in the symbol stop signal data, the data indicating the stop operation position of the middle reel 31 is “7”. If the 7th "watermelon" of the middle reel 31 is aimed to stop in the middle lower stage, the 8th "blue BAR" can be stopped in the effective line (middle middle stage).
Furthermore, in the symbol stop signal data, the data indicating the stop operation position of the right reel 31 is “2”. When aiming so that the second “blue BAR” of the right reel 31 stops at the lower right stage, this “blue BAR” can be stopped on the effective line (lower right stage).
Therefore, the above-mentioned symbol stop signal data is data for aiming at "blue BAR" assembling in the pushing order 123.

In addition, if it is a game which is in 1BB and has not won a small win and replay in this game, if each reel 31 is stopped based on the above-mentioned symbol stop signal data, the "blue BAR" is complete. Stop display. On the other hand, even within 1BB, in the game in which the small win or replay is won in the game this time, even if each reel 31 is stopped based on the symbol stop signal data described above, "blue BAR" The set is not stopped.

The symbol stop signal data “0, 6, 127, 127” of (2) is the symbol stop signal data under the conditions other than the above (1). This symbol stop signal data is the symbol stop signal data that is not used for "blue BAR" alignment.
In the symbol stop signal data “0, 6, 127, 127”, “0” is data indicating the pushing order 123 as in the above. Further, the data indicating the stop position of the left reel 31 is “6”. Here, as shown in FIG. 114, if the 6th "watermelon" of the left reel 31 is aimed to stop in the lower left stage, the 18th "blue BAR" will not stop on the activated line.
Furthermore, the data “127” indicating the stop operation position of the middle and right reels 31 means that the operation timing does not matter (arbitrary operation position). Therefore, the left reel 31 is set so that "blue BAR" does not stop on the activated line, which means that the operation timing of the stop switch 42 of the middle and right reels 31 is arbitrary. Although the data indicating the stop operation position of the middle reel 31 and the right reel 31 is “127”, it is possible to store the data indicating a predetermined stop operation position instead of the arbitrary operation position. Is.

As described above, the symbol stop signal is a signal including the pressing order of the stop switch 42 and the stop operation position of each reel 31, and is a test signal transmitted to the testing machine. On the tester side, when this symbol stop signal (test signal) is received, a simulation of operating the stop switch 42 according to this symbol stop signal is executed. Then, when a simulation of operating the stop switch 42 according to the symbol stop signal is executed, it is judged (confirmed) whether or not the reel 31 is stopped at the correct position, and whether or not the payout rate is within an appropriate range. Judgment (confirmation). Further, by outputting the symbol stop signal before determining whether or not the minimum game time has elapsed, on the test machine side, it is possible to immediately perform the stop operation after the minimum game time has elapsed.

Further, in the stop acceptance designation table 2 (TBL_ORD_INF2) of FIG. 142(B), six kinds of symbol stop signal data are stored, and in the pressing order 123, the pressing order 132,..., The pressing order 321 respectively. It corresponds.
When the winning number "10" is won during AT or when the winning number "16" is won during AT and inside the SRB, the symbol stop signal data "0, 127, 127, 127" corresponding to the pushing order 123 Is selected.
When the winning number “11” is won during AT, or when the winning number “17” is won during AT and inside the SRB, the symbol stop signal data “1, 127, 127” corresponding to the pushing order 132 , 127” is selected.
Furthermore, when the winning number “12” is won during AT, or when the winning number “18” is won during AT and inside the SRB, the symbol stop signal data “2, 127,” corresponding to the pushing order 213 is selected. 127, 127” is selected.

Furthermore, when the winning number “13” is won during AT, or when the winning number “19” is won during AT and inside the SRB, the symbol stop signal data “3, 127, 127” corresponding to the pushing order 231. , 127” is selected.
Similarly, when the winning number "14" is won during AT, or when the winning number "20" is won during AT and inside the SRB, the symbol stop signal data "4, 127," corresponding to the pushing order 312 127, 127” is selected.
Similarly, when the winning number "15" is won during AT, or when the winning number "21" is won during AT and inside the SRB, the symbol stop signal data "5,127" corresponding to the pushing order 312 , 127, 127” are selected.

Thus, in the game when performing the push order notification during AT, there is a process for outputting the push order data corresponding to the push order and the stop operation position data indicating that the stop operation position is arbitrary. To be executed. Then, by outputting the stop operation position data indicating that the stop operation position is arbitrary, the difference between the test on the test machine side and the game method performed by the player after the game machine is actually installed in the hall. It is possible to reduce the number.

The description is returned to FIG. 141, and the symbol stop signal set (S_IF_SET) will be described.
First, in step S771, the stop acceptance designation table 2 shown in FIG. 141(B) is set.
In the next step S772, it is determined whether or not there is a push order instruction. Here, when the small winning combination A group is won during AT, or when the small winning combination B group is won during AT and inside the SRB, the pushing order instruction number (in FIGS. 133 to 138 is displayed in a predetermined storage area of the RWM 53. (Not shown) is stored, so this push order instruction number is stored in the A register. Then, when the A register value is not "0", it is determined to be "Yes" (with a push order instruction), and when it is "0", it is determined to be "No" (no push order instruction).
If it is determined that the pushing order is instructed, the process proceeds to step S773, and if it is determined that the pushing order is not instructed, the process proceeds to step S775.

In step S773, the offset value is set. Here, it is assumed that the pressing order instruction numbers are set to “1”, “2”,..., “6” for the six pressing orders 123, 132,..., 321, respectively. .. In this case, the offset values are "0", "1",..., "5". Therefore, "1" is subtracted from the A register and the offset value is set.
Next, proceeding to step S774, the symbol stop signal data corresponding to the offset value is acquired. For example, the symbol stop signal data corresponding to the offset value “0” is “0, 127, 127, 127” in FIG. 142(B), and the symbol stop signal data corresponding to the offset value “1” is “1”. , 127, 127, 127”,..., The symbol stop signal data corresponding to the offset value “5” is “5, 127, 127, 127”. Then, the process proceeds to step S781.

On the other hand, if the process proceeds from step S772 to step S775, the stop acceptance designation table 1 is set. This process is a process of setting the stop acceptance designation table 1 in place of the stop acceptance designation table 2 initially set in step S771.
Next, proceeding to step S776, it is determined whether or not the winning and replay condition device number is "0". This processing determines whether or not the winning and replay condition device number (_NB_CND_NOR) stored at the address “F0A9(H)” is “0”. When it is determined that there is "0" (that is, when the small win or replay is not won in the game this time), the process proceeds to step S7777, and when it is determined that it is not "0", the process proceeds to step S780.

In step S777, it is determined whether or not the accessory condition device number is "1" (whether or not the player wins 1BB). This processing determines whether or not the accessory condition device number (_NB_CRRT_BNS) stored in the address “F0AA(H)” is “1”. If it is determined to be "1", the process proceeds to step S778, and if it is determined not to be "1", the process proceeds to step S780.

In step S778, it is determined whether or not the winning of 1BB is permitted in the game this time. Here, "1 BB winning is permitted" corresponds to the main game state 3 (AT is preparing) and the AT standby counter is "0". Therefore, whether the value of the address "F07E(H)" (main game state number) is "3" and whether the value of the address "F098(H)" (AT standby counter) is "0" To judge. When it is determined that the main game state number 3 and the AT standby counter are "0", the process proceeds to step S779, and when it is determined that the main game state number 3 and the AT standby counter is not "0", the process proceeds to step S780.
In step S779, the symbol stop signal data "0, 16, 7, 2" is acquired. Then, the process proceeds to step S781. On the other hand, in step S780, the symbol stop signal data “0, 6, 127, 127” is acquired. Then, the process proceeds to step S781.

In the next step S781, the serial communication circuit data register is set. Here, the address of the transmission register in the serial communication circuit of the chip built in the main CPU 55 is stored in a predetermined register.
Next, proceeding to step S782, processing for outputting the pressing order of the test signals is executed. The process here is a process of writing the pushing order data "0" to the address of the transmission register when the symbol stop signal data is "0, 16, 7, 2", for example.
Next, proceeding to step S783, processing for outputting the stop operation position of the first reel 31 (the left reel 31 in this embodiment) of the test signal is executed. The process here is a process of writing the stop operation position "16(D)" of the left reel 31 to the address of the transmission register when the symbol stop signal data is "0, 16, 7, 2", for example. is there.

Next, proceeding to step S784, processing for outputting the stop operation position of the second reel 31 (in the present embodiment, the middle reel 31) is executed. The process here is a process of writing the stop operation position "7" of the middle reel 31 to the address of the transmission register when the symbol stop signal data is "0, 16, 7, 2", for example.
Next, proceeding to step S785, processing for outputting the stop operation position of the third reel 31 (the right reel 31 in this embodiment) is executed. The process here is a process of writing the stop operation position "2" of the right reel 31 to the address of the transmission register when the symbol stop signal data is "0, 16, 7, 2", for example.
Then, the processing according to this flowchart is ended.
In steps S782 to S785, the pushing order and the stop operation position of the reel 31 are written in the transmission register, so that the processing for transmitting these data to the tester is executed. In the interrupt process (I_INTR) of FIG. 151, which will be described later, the process of transmitting these data to the tester may be executed by the test signal output of step S842.

As described above, in the situation where the winning of 1BB is permitted, the symbol stop signal data for winning the 1BB is transmitted, and in the situation where the winning of 1BB is not permitted, the winning of 1BB is not allowed. Send the symbol stop signal data. As a result, it is possible to transmit a test signal according to how the player hits in the market. Therefore, the payout on the test machine and the payout on the market can be made closer to each other.

Note that the process of FIG. 141 is one process of the main process, and therefore is performed for each game. When the slot machine 10 and the tester are electrically connected, each game and the symbol stop signal (test signal) are output to the tester by the processing of FIG. 141.
On the other hand, when the slot machine 10 and the test machine are not connected, for example, even when the slot machine 10 is installed in the hall, each game, the processing of FIG. 141 is executed. However, since the slot machine 10 and the tester are not connected, the symbol stop signal (test signal) is not output to the outside.

FIG. 143 is a flowchart showing the standby effect start (M_TARPIC_EXE) in step S765 in FIG.
First, in step S821, a standby effect type is acquired. This process is a process of storing the data of the standby effect type (_WK_PRD) of the address "F09E(H)" in the A register.
Next, proceeding to step S822, it is determined whether or not the standby effect type is "0". Here, it is determined whether the A register value is "0". When it is determined that the A register value is "0", the process according to this flowchart is ended, and when it is determined that it is not "0", the process proceeds to step S823. When the standby effect type is "0", it means that there is no standby effect when the start switch 41 is operated, and when it is not "0", it means that there is a standby effect.

In step S823, "-2" is stored in the search counter update correction data. This process is a process of storing "FE(H)" in the search counter update correction data (_WK_PLS_REV) of the address "F09F(H)". “FE(H)” is data for reverse rotation.
The "control command set 1" in the next step S824 is a process for transmitting a command to the sub-control board 80, as in step S303 of FIG. 41 (the eleventh embodiment). Here, the information of the standby effect number (_NB_PRD_NO) of the address “F0A0(H)” or the three-role number (_NB_TRIO) of the address “F0A1(H)” is transmitted to the sub-control board 80.
In the next step S825, "0" is stored in the triple number (_NB_TRIO) of "F0A1(H)".

Next, proceeding to step S826, based on the reel effect data table (TBL_TARPIC_DAT), the addresses #F054(H), “F05F(H)” and “F06A(H)” # reel symbol number (for stop position) The designated position (stop position of the reel 31) is stored in (_NB_RL#_STPPIC).
FIG. 144 is a diagram showing a reel effect data table (TBL_TARPIC_DAT) stored in the ROM 54. As shown in FIG. 144, the reel effect data table (TBL_TARPIC_DAT) stores a designated position (stop position) corresponding to the standby effect number. The "designated position (stop position)" corresponds to the symbol number.
For example, in the figure, the addresses "1000 (H)" to "1002 (H)" are designated stop positions of each reel 31 when the standby effect number (_NB_PRD_NO) is "1"("blackBAR" complete) Indicates. The value “8(H)” stored at the address “1000(H)” indicates the stop symbol designating position of the left reel 31, and the value “8(H)” at the address “1001(H)” is the middle reel 31. The stop symbol designating position of "3(H)" of the address "1002(H)" indicates the stop symbol designating position of the right reel 31.

Further, the symbol number at the time of normal rotation is different from the symbol number at the time of reverse rotation. In the twenty-third embodiment, the index (also referred to as “initial” or “detection piece”) provided on each reel 31 is within a range of about half of the entire circumference (360 degrees) of the reel 31 (about 180 degrees). Is formed in. By detecting/non-detecting the index, the current position of the reel 31 can be grasped if the reel 31 rotates about a half turn.
Although details will be described later, in steps S897 and S899 of FIG. 155 (reel drive control), the reference symbol number when the rising of the # reel motor index is detected (when the index is detected) is set to “10”. ing. Similarly, the reference symbol number when the fall of the # reel motor index is detected is set to "0".

Therefore, when the reel 31 is rotating normally, the symbol number “10” (for example, “Replay” on the left reel 31 in FIG. 114) is detected at the moment when the rising of the # reel motor index is detected. Judge that it is passing through the middle tier.
Similarly, when the reel 31 is rotating forward, at the moment when the trailing edge of the # reel motor index is detected, the symbol of the symbol number “0” (for example, in FIG. 114, the left reel 31 is “replay”). ) Is passing through the middle tier.

On the other hand, when the reel 31 is rotating in the reverse direction, when it is determined that the symbol of the symbol number “10” is passing at the moment when the rising of the # reel motor index is detected, actually, As shown in FIG. 114, the symbol of the symbol number "1" at the time of forward rotation is passing. Similarly, when it is determined that the symbol with the symbol number “0” is passing at the moment when the trailing edge of the # reel motor index is detected, the symbol number “11” during normal rotation is actually the symbol number “11”. You will pass through the middle tier.
Thus, as shown in FIG. 114, when the reel 31 rotates forward and backward, the symbol numbers passing through the middle stage are different when the # reel motor index rises and falls (for 9 symbols). There will be a gap). Therefore, in the reel effect data table of FIG. 144, the stop position is stored in consideration of the deviation. For example, when it is determined that the reel 31 is stopped at the symbol number "8" when it is rotated in the reverse direction, the reel can be actually stopped at the symbol number "3" as shown in FIG.

The reel effect data table of FIG. 144 defines the stop symbol position during the standby effect, that is, during the reverse rotation of the reel 31. For example, in FIG. 144, when the stop symbol position at the time of the standby effect number “1” is defined as “8, 8, 3”, actually, “black BAR (number “3” at normal rotation)”-“black” "BAR (No. "3" during normal rotation)"-"Black BAR (No. "8" during normal rotation)" stops.
The same applies to "2" to "8" other than the standby effect number "1".
For example, when the standby effect number "2", the stop symbol position is "18, 18, 8", but the symbol number "18" during reverse rotation is the symbol number "13" during normal rotation (red 7). The symbol number “8” during reverse rotation corresponds to the symbol number “3” (red 7) during forward rotation.
As described above, in FIG. 143, in step S826, the reel symbol number (for stop position) is stored based on the reel effect data table (TBL_TARPIC_DAT).

The description returns to FIG. 143.
After step S826, the process proceeds to step S827, and the designated symbol position search waiting time is saved. The "designated symbol position search standby time" is, as described above, the standby time until the designated symbol position (stop position) of the reel 31 is searched after starting the standby effect (rotating the reel 31) ( In other words, it is about the rotation time of the reel 31).
FIG. 145 is a diagram showing reel effect execution timer table 1 (TBL_TARPIC_TM1) to reel effect execution timer table 8 (TBL_TARPIC_TM8) stored in ROM 54. The data values shown in FIG. 145 are decimal numbers. Reel effect execution timer table 1 (TBL_TARPIC_TM1) to reel effect execution timer table 8 (TBL_TARPIC_TM8) correspond to standby effect numbers "1" to "8", respectively. For example, when the standby effect number is "1", the reel effect execution timer table 1 (TBL_TARPIC_TM1) is used.
In FIG. 145, for example, addresses “1018(H)” and “1019(H)”, “101A(H)” and “101B(H)”, and “101C(H)” and “101D(H)”. Indicates the timer values of the left reel 31, the middle reel 31, and the right reel 31, respectively. Note that FIG. 145 shows how much the timer value of the left reel 31 is larger than the timer value of the left reel 31 with reference to the timer value of the left reel 31, but in reality, the address is “1018 (H)”. The timer values of "1019(H)", "101A(H)" and "101B(H)", "101C(H)" and "101D(H)" are "14112(D), 14782(D)". , 16122(D)”.

This timer value specifies the waiting time until the deceleration of the reel 31 is started. For example, when the standby effect number is “1”, the left reel 31 can start decelerating after “14112 (D)” has elapsed from the start of the standby effect, that is, “1.117×14112=about 15763 ms”. ing.
The timer value is also subtracted during the acceleration of the reel 31 in the standby effect. As shown in FIG. 156, which will be described later, the acceleration processing of the reel 31 requires a total of “62 times×2 interrupts=about 139 ms” in the first to eighth steps. The timer value of each reel 31 is set to at least a time longer than the time required for this acceleration processing.
Further, in the reel effect execution timer tables 1 to 4, the standby time of the middle reel 31 is set longer than the standby time of the left reel 31. Further, the waiting time of the right reel 31 is set longer than the waiting time of the middle reel 31. As a result, when the reel 31 stops, it stops in the order of “left→middle→right”. Further, in the reel effect execution timer tables 5 to 8, the waiting time of the middle reel 31 is set longer than the waiting time of the right reel 31. Further, the waiting time of the left reel 31 is set longer than the waiting time of the middle reel 31. As a result, when the reel 31 stops, it stops in the order of “right→middle→left”.
In this way, by setting the waiting time of each reel 31 in the reel effect execution timer table, the stop order of the reel 31 can be determined, and the stop order and the stop timing of the reel 31 can be made regular. ..
On the other hand, when the waiting time of each reel 31 is not set, it becomes impossible to secure a sufficient constant speed time after the reel 31 is started, and it becomes impossible to output a necessary effect while the reel 31 is rotating. .. Further, when the reels 31 are stopped from the order in which the designated symbol position comes to the stop position, the reels 31 may stop in a disjoint manner, for example, “right→left→middle”.

Furthermore, the difference between the waiting time of the reel 31 that stops first and the waiting time of the reel 31 that stops second is “670” interrupt in the reel effect execution timer table 1 and “670” in the reel effect execution timer tables 2-4. "1008" interrupt, "1176" interrupt is set in the reel effect execution timer tables 5-8. The number of interruptions per revolution of the reel 31 is “672” as described above. Therefore, after the first reel 31 is stopped, the second reel 31 is set to be stopped after rotating about one rotation or more.
Further, the difference between the waiting time of the reel 31 that stops second and the waiting time of the reel 31 that stops third is "1340" interrupt in the reel effect execution timer table 1 and "1340" in the reel effect execution timer tables 2-4. The interrupt is set to “1008”, the reel effect execution timer tables 5 to 7 are set to “1176” interrupt, and the reel effect execution timer table 8 is set to “1848” interrupt. Therefore, after the second reel 31 stops, the third reel 31 is set to stop after rotating about two times or more.

Even if, for example, the middle reel 31 goes out of step after the left reel 31 has stopped (the second reel rotation failure detection counter determines that an abnormality has occurred), the set timer value remains unchanged during this period. Subtracted. When the constant speed cannot be reached easily after the step out, and the middle reel 31 cannot be stopped even if the timer value becomes "0", the timer value of the right reel 31 becomes "0". ", the right reel 31 is stopped prior to the middle reel 31 as an irregularity. Therefore, the stop order of the reels 31 in this case is “left→right→center”. By dealing in this way at irregular times such as step out, it is possible to prevent the time required for the standby performance from being inadvertently extended due to step out. As a result, the time until the game can be started can be shortened.

Furthermore, the fourth timer value of each reel effect execution timer table, for example, in the reel effect execution timer table 1, the values stored by the addresses "101E(H)" and "101F(H)" are after all stoppages. Shows the waiting time. For example, when the standby effect number is "1", restarting is possible after "1.117 x 5371 = about 5999 ms" has elapsed after the entire stop.
In step S827 of FIG. 143, for example, when the standby effect number is "1", the first reel-designated symbol position search standby time (_TM2_TAR1_WAIT) at the addresses "F039 (H)" and "F03A (H)" is set to " 14112 (D)" is stored, "14782 (D)" is stored in the second reel designated symbol position search waiting time (_TM2_TAR2_WAIT) of the addresses "F03B (H)" and "F03C (H)", and the address "F03D" is stored. (16) (D) is stored in the third reel designation symbol position search waiting time (_TM2_TAR3_WAIT) of (H)” and “F03E(H)”.

In the next step S828, acceleration start is set. Here, the following processing is executed.
(1) Disable interrupts.
(2) “10000011(B)” is stored in the A register.
(3) The A register value is stored in the first reel drive number (_WK_RL1_STS) of the address “F04D(H)”.
(4) The A register value is stored in the second reel drive number (_WK_RL2_STS) of the address "F058(H)".
(5) The A register value is stored in the third reel drive number (_WK_RL3_STS) of the address “F063(H)”.
(6) Enable interrupts.
This is because if the interrupt processing is entered between the above (3) to (5), the reels 31 will not start rotating all at once. For this reason, interrupt processing is prevented from entering while the reel drive number is being updated.
By the above processing, the first reel drive number (_WK_RL1_STS) to the third reel drive number (_WK_RL3_STS) are all "10000011(B)", and when the next interrupt processing becomes "00000011(B)", The acceleration of each reel 31 is actually executed.

At the start of acceleration, the lower four digits of the reel drive number are "0011(B)", but at the next acceleration, "0010(B)", and at constant speed, "0101(B)".
After the reel 31 becomes constant speed, the constant speed state is maintained until the reel designated symbol position search standby time set in step S827 is reached, and when the reel designated symbol position search standby time becomes “0”, Start decelerating the reels. At the start of deceleration of the reel 31, the reel drive number becomes "0100 (B)", and when the deceleration state is entered, it becomes "0001 (B)". Then, when the reel 31 stops, the reel drive number becomes "0000 (B)".

In the next step S829, an end check of all reels 31 is executed. Here, the following processing is executed.
(1) Store "0" in the A register.
(2) The logical sum (OR) operation of the A register value and the first reel drive state (_WK_RL1_STS) is performed. Then, the result of the logical sum is stored in the A register.
(3) The logical sum of the A register value and the second reel drive state (_WK_RL2_STS) is calculated. Then, the result of the logical sum is stored in the A register.
(4) The logical sum of the A register value and the third reel drive state (_WK_RL3_STS) is calculated. Then, the result of the logical sum is stored in the A register.
(5) The logical product (AND) operation of the A register value and "01111111(B)" is performed.

Here, when all reels 31 are stopped, the first reel driving state (_WK_RL1_STS), the second reel driving state (_WK_RL2_STS), and the third reel driving state (_WK_RL3_STS) are all "10000000 (B)" or "00000000(B)". Therefore, in the calculation of the above (5), the calculation result becomes “0” only when all reels 31 are stopped.
In addition, in the calculation of the above (5), the number to calculate the logical product for determining whether or not all reels 31 have stopped is not limited to “01111111(B)”, but “00001111(B)”. Even in this case, the same calculation result as above can be obtained. In other words, by determining whether or not the lower 4 bits are “0”, it is possible to determine whether or not all reels 31 have stopped.
Further, in the present embodiment, since the actual reel drive control is executed once every two interrupts, the most significant bit of the reel drive state (_WK_RL#_STS) is "0" or "1" for each interrupt process. Become. Therefore, not limited to such a specification, for example, when the most significant bit is always “0”, “11111111( B)” can also be used.

In the next step S830, it is determined whether or not all reels 31 have stopped. This process determines that all reels 31 have stopped when the calculation result of (5) above is "0" (when the zero flag is "1").
When it is determined in step S830 that all reels 31 have stopped, the process proceeds to step S831, and when it is determined in step S830 that all reels 31 have not stopped, the above process of step S829 is executed again.
In step S831, a production end waiting time is set. This process is a process of acquiring the production end waiting time corresponding to the standby production number in the standby production of this time from the reel production execution timer table (TBL_TARPIC_TM1 to 8) and storing it in the BC register. For example, when the standby effect number in the standby effect this time is "1", it is stored by the addresses "101E(H)" and "101F(H)" of the reel effect execution timer table 1 (TBL_TARPIC_TM1) in FIG. 145. The value “5371 (D)” (waiting time at the end of effect) that has been set is stored in the BC register.

Next, proceeding to step S832, a 2-byte time wait is executed. In this process, the process of subtracting "1" from the BC register value for each interrupt process is executed until the BC register value becomes "0".
Then, when the BC register value becomes "0", the 2-byte time waiting is ended, and the process proceeds to step S833.
In step S833, the standby effect type RWM address is set. This process is a process of storing "F0A0(H)" which is the address of the standby effect number (_NB_PRO_NO) in the HL register.
In the next step S834, it is determined whether or not the value stored in the address indicated by the HL register value (that is, the standby effect number (_NB_PRO_NO)) is "4". If it is determined to be "4", the process according to this flowchart is ended. On the other hand, if it is determined that it is not “4”, the flow proceeds to step S835.
Here, when the standby effect number "4" is selected as the standby effect, as shown in FIG. 144, after the "red 7" is aligned, the "black BAR" is aligned. Therefore, in the case of the standby effect number "4", the process proceeds to the next process without performing the process of clearing the data related to the standby effect start process or initializing the symbol number.

On the other hand, when the process proceeds to step S835, the standby performance type (_WK_PRD) of the address "F09E(H)", the standby performance number (_NB_PRO_NO) of the address "F0A0(H)", and the address "F09F(H)" are searched. Counter update correction data (_WK_PLS_REV) is cleared. Specifically, the process of storing "0" in each of the above addresses is executed.
Next, proceeding to step S836, the data of the symbol number (for the passing position) and the symbol number (for the stop position) is initialized.
In particular,
First reel symbol number (for passage position) of address "F053 (H)" (_NB_RL1_PASPIC),
First reel symbol number (for stop position) at address "F054 (H)" (_NB_RL1_STPPIC),
Second reel symbol number (for passing position) of address "F05E(H)" (_NB_RL2_PASPIC),
Second reel symbol number (for stop position) at address "F05F(H)" (_NB_RL2_STPPIC),
Third reel symbol number (for passing position) of address "F069 (H)" (_NB_RL3_PASPIC),
Third reel symbol number (for stop position) at address "F06A(H)" (_NB_RL3_STPPIC)
The initial value “11111111(B)” (FF(H)) is stored in all of the above.

Next, proceeding to step S837, a random delay time is set. This processing is performed by the first reel rotation start waiting counter (_CT_RL1_WAIT) at the address “F056(H)”, the second reel rotation start waiting counter (_CT_RL2_WAIT) at the address “F061(H)”, and the address “F06C(H)”. The third reel rotation start waiting counter (_CT_RL3_WAIT) is set to the value determined by the lottery. Specifically, any one value is determined from "0" to "335(D)", and the value is stored in each of the above three addresses. When the value is stored in the above address, "1" is subtracted for each interrupt processing, and when it becomes "0", the reel 31 can be restarted.

The standby effect start process shown in FIG. 143 described above is executed before the determination of whether or not the minimum game time has elapsed (step S766), as shown in FIG. In other words, the standby effect start processing is executed even when the minimum game time has not elapsed. Then, after the end of the standby effect, it is determined in step S766 whether or not the minimum game time has elapsed. In the twenty-third embodiment, since the standby effect is executed by the timer value shown in FIG. 145, the minimum game time (4.1 seconds) is always elapsed at the end of the standby effect.
In this way, when the standby effect is executed, it is started without waiting for the minimum game time. It is possible to reduce the occurrence of

FIG. 146 is a flowchart showing the reel stop acceptance check (M_STOP_CHK) in step S752 of FIG. 139.
First, in step S791, it is determined whether the waiting time (_TM2_WAIT) stored by the addresses "F041(H)" and "F042(H)" is "0" (whether the zero flag is "1"). to decide. If it is "0", the process proceeds to step S792, and if it is not "0", the process according to this flowchart is ended. In other words, as long as the standby time (_TM2_WAIT) stored by the addresses “F041(H)” and “F042(H)” is not “0”, the stop process of the reel 31 is performed even if the stop switch 42 is operated. Do not run.

The reason for controlling in this way is as follows.
In the twenty-third embodiment, 1BB non-internal in non-RT or RT1 wins 1BB with a relatively high probability (“19930/65536”) as shown in FIGS. 126 and 127. When 1BB is won and 1BB is in the inside, in the game where the small win or replay is not won in the game (game with winning and replay condition device number "0"), the 1BB symbol combination is stopped and displayed. It will be possible.
On the other hand, in the 23rd embodiment, AT is executed in a 1BB game. Therefore, when the player is not in AT, he does not want to win 1BB even in the inside of 1BB. Even if 1BB is won in the non-AT, the 1BB game itself is executed, but the AT is not executed. Further, since the AT lottery is not executed during the operation of 1BB, it becomes disadvantageous for the player to be in the operation of 1BB during non-AT. As described above, the payout rate is slightly higher when the 1BB is operated than when the 1BB is not operated, but since it is a game period in which the AT lottery is not executed, it is substantially disadvantageous to the player.

Therefore, when the stop display of the symbol combination of 1BB is not permitted, specifically, when the main game state is not "3" (AT preparing), or even when the main game state is "3", AT standby When the flag is not "0", in order to avoid the symbol combination of 1BB being stopped and displayed as much as possible, the symbol combination of 1BB is tempted (when the symbols of 1BB "blue BAR" when the two reels 31 are stopped). If the third stop switch 42 is operated, the stop operation is not effective even if the third stop switch 42 is operated.

When it is determined in step S791 that the waiting time is "0" and the process proceeds to step S792, index passing checks of all motors are performed. Here, the following processing is executed.
(1) The first reel symbol number (for passing position) (_NB_RL1_PASPIC) is stored in the A register.
(2) The logical sum (OR) operation of the A register value and the second reel symbol number (for passing position) (_NB_RL2_PASPIC) is performed. Then, the calculation result is stored in the A register.
(3) The logical sum (OR) operation of the A register value and the third reel symbol number (for passing position) (_NB_RL3_PASPIC) is performed. Then, the calculation result is stored in the A register.
(4) Add "1" to the A register value.

Here, the first reel symbol number (for passing position) (_NB_RL1_PASPIC), the A register value and the second reel symbol number (for passing position) (_NB_RL2_PASPIC), and the third reel symbol number (for passing position) (_NB_RL3_PASPIC) are , "FF(H)", that is, "11111111(B)" before the # reel motor index is changed.
Therefore, if at least one data is "111111111(B)", the calculation result up to (3) above is "11111111(B)", and if "1" is added as shown in (4), it becomes "0". become. Therefore, the calculation result is “0” before the # reel motor index changes for at least one reel 31, and the above result after the # reel motor index changes for all reels 31. The calculation result is a value other than "0".

As described above, when there is a change in the # reel motor index, the # reel symbol number (for passing position) is “10 (D)” (at the time of rising) or “0” (at the time of falling). Time) is memorized. Then, every time it is determined that one symbol has been moved, the #1 reel symbol number (for the passing position) is decremented. In this way, after the # reel motor index changes, the # reel symbol number (for passing position) is “0” (00000000(B)) to “19(D)” (00010011(B)). It will circulate. Therefore, after the change of the # reel motor index, the logical sum operation of (1) to (3) above does not result in "11111111(B)".

Further, as another method of the above operation (4), there is a method of performing a logical product (AND) operation with "11100000 (B)". With this method, when the calculation result is not "0", it is possible to determine "No" in step S793 described later. Furthermore, as another method of the above operation (4), there is a method of performing an operation of shifting "1" bits to the left. With this method, when the calculation result is not "0", it is possible to determine "No" in step S793 described later. In other words, before the # reel motor index changes, the upper 3 bits of the # reel symbol number (for the passing position) are “111”, so the upper 3 bits of the calculation in (4) above It is determined whether at least 1 bit among them is "1". If there is a "1" in the upper 3 bits, it is not possible to accept the stop of the stop switch 42 in step S793 described later, and if there is no "1" in the upper 3 bits, it can be determined that the stop can be accepted. Becomes

Next, proceeding to step S793, it is determined whether or not the stop acceptance of the stop switch 42 is possible. This determination is whether or not it is "0" (whether the zero flag is "1") in the calculation of (4) in step S792. In other words, when the # reel motor index changes for all reels 31, the stop acceptance of the stop switch 42 is permitted.
In step S793, if it is determined that the stop switch 42 can accept the stop, the process proceeds to step S794, and if it is determined that the stop switch 42 cannot accept the stop, the process according to this flowchart ends.

In step S794, the operation of the stop switch 42 (corresponding to the reel 31 not yet stopped controlled) is performed based on the value of the D0 to D2 bits of the input port rising data A (_PT_IN_A_UP) of the address "F017(H)". Determine whether it was done or not. When it is determined that the stop switch 42 has been operated, the processing proceeds to step S795, and when it is determined that the stop switch 42 has not been operated, the processing according to this flowchart ends.
In step S795, the stop position is determined based on the result of the lottery for the current game (addresses "F0A9(H)" and "F0AA(H)") and the reel position at the moment when the stop switch 42 is operated.
Next, proceeding to step S796, a transition is made to a stop symbol set (M_STOPPIC_SET).

FIG. 147 is a flowchart showing the stop symbol set (M_STOPPIC_SET) in step S796 of FIG. 146.
As described above, this flowchart restricts that the symbol combination of 1BB is stopped and displayed when the symbol combination of 1BB is in a situation where the symbol combination of 1BB can be stopped and displayed in the case where the symbol combination of 1BB is tempted. However, in a situation in which it is not desired to stop and display the symbol combination of 1BB, the waiting time until the third stop switch 42 becomes effective is set. If the waiting time is set here and the third stop switch 42 is operated before the waiting time elapses, "No" is determined in the step S791 of FIG. 146, and the stop control of the third reel 31 is not executed.

First, in step S801, it is determined whether or not the stop operation of the second stop switch 42 has been performed. Here, in step S794 of FIG. 146, it is determined whether or not the stop switch 42 that is determined to have a rising edge is the second stop switch 42 (the second operated stop switch 42). When it is determined in step S801 that the second stop has been performed, the process proceeds to step S802, and when it is determined that the second stop has not been performed, the process according to the present flowchart ends.

In step S802, it is determined whether or not 1BB can be won. Specifically, at the time of the second stop, it is determined whether or not the symbol combination of 1BB is tempered on the activated line or is tempered. For example, when it is determined whether or not the tempo has been reached, after the second reel 31 is stopped, the “blue BAR” (the symbols forming the symbol combination of 1BB) of the first reel 31 and the second reel 31 are both in the activated line. When it is stopped, it is determined that 1BB has been tempted (1BB can be won). On the other hand, before the second reel 31 is stopped (regardless of whether it is stopped or not), it may be determined whether or not to make a tempe. For example, the "blue BAR" is stopped on the activated line when the first reel 31 is stopped, and the second stop switch 42 is operated at an operation timing at which the "blue BAR" on the second reel 31 can be stopped on the activated line. When it is played, it is determined that 1BB is a tempo (1BB can be won).
When it is determined that 1BB can be won, the process proceeds to step S803, and when it is determined that 1BB is not, the process according to this flowchart ends.

In step S803, it is determined whether or not the winning and replay condition device number (_NB_CND_NOR) of this game is "0". Here, it is determined whether or not the value of the address “F0A9(H)” is “0”. When it is determined that the winning and replay condition device number is “0”, the process proceeds to step S804, and when it is determined that the device number is not “0”, the process according to this flowchart is ended.
Therefore, even if it is determined in step S802 that 1BB has been tempted, in the game at the time of winning the small winning combination, the result is "No" in step S803, and thus the standby time is not set in step S810. In the twenty-third embodiment, in a game in which a small winning combination is won, a small winning combination priority control is performed (in a game in which a winning combination of 1BB is carried over, in a game in which a small winning combination is won, priority is given to the winning of a small winning combination so that 1BB is not won) Since 1 is executed, 1BB is never won. Therefore, it is not necessary to set the waiting time in the game in which the small win is won.
In step S804, the accessory condition device number (_NB_CRRT_BNS) is acquired. This process is a process of acquiring the value of the address “F0AA(H)” and storing it in the A register.
In the next step S805, it is determined whether or not the acquired accessory condition device number is less than "2", in other words, "1". Here, the comparison operation of the A register value and “2” is performed, and when it is determined that the A register is smaller, it is determined as “Yes” and the process proceeds to step S806, and when it is determined as “No”, the The process according to the flowchart ends.

In addition, in the twenty-third embodiment, the symbol combination of 1BB is not tempted unless the accessory condition device number is "1". Therefore, when the accessory condition device number is "0" in the game this time, it is determined to be "No" in step S802. Therefore, in step S805, it is not determined whether the accessory condition device number is "1" (of course, in step S805, it is determined whether the accessory condition device number is "1"). It is also possible), and it is determined whether it is less than “2”.

In step S806, the main game state number is acquired. This process is a process of storing the value of the main gaming state (_NB_GAM_STS) of the address "F07E(H)" in the A register. Then, the process proceeds to step S807, and it is determined whether or not the A register value is "3" (AT in preparation). Here, the comparison operation of the A register value and "3" is performed, and when the A register value and "3" are the same value, "Yes" is determined. When it is determined that the main game state number is "3", the flow proceeds to step S808, and when it is determined that it is not "3", the flow proceeds to step S809.

In step S808, the value of the AT standby counter (_CT_AT_WAIT) of the address "F098(H)" is acquired. Then, it is determined whether or not the AT standby counter value is "0". When the AT standby counter value is "0", the processing according to this flowchart is ended. On the other hand, when it is determined that the AT standby counter is not "0", the process proceeds to step S809.
In step S809, “896(D)” is stored in the HL register. Next, proceeding to step S810, the HL register value (896(D)) is stored in the waiting time (_TM2_WAIT) of the addresses "F041(H)" and "F042(H)". Then, the processing according to this flowchart is ended.
When the waiting time is stored in the addresses “F041(H)” and “F042(H)”, “1” is subtracted for each interrupt process. Further, it is determined whether or not the time set here is “0” in step S791 of FIG. 146.
In the above processing, when the main game state is "3" and the AT standby counter is "0", the standby time is not stored. That is, in this case, the winning of 1BB is permitted.

FIG. 148 is a flowchart showing the game end check processing (M_GAME_CHK) in step S753 of FIG. 139.
First, in step S941, main game state game end processing is executed. This processing is processing for determining whether or not the end condition of the advantageous section is satisfied, and is processing shown in FIG. 149 described later.
Next, proceeding to step S942, 1BB operation management is executed. The 1BB operation management is a process of determining whether or not the ending condition of the 1BB game is satisfied when the current game is the 1BB game. Specifically, based on whether or not the D2 bit of the operating state flag (in the twenty-third embodiment, the “FL_ACTION” shown in FIG. 35 is provided, as in the eleventh embodiment) is “1”. It is determined whether or not 1BB is in operation.
When it is determined that the 1BB operation is being performed, the number of obtainable sheets during the 1BB operation (“_CT_BIG_PAY” of the address “F00E(H)”) is read and it is determined whether or not the number is “0”.
Then, when it is determined that the obtainable number has become “0” (when the obtainable number satisfies the 1BB operation end condition), the process of clearing the D2 bit of the operation state flag is executed.

Next, in step S943, it is determined whether the RB is operating. Here, it is determined whether or not the RB is operating by determining whether or not the D3 bit of the operating state flag (FIG. 35) is "0". If it is determined that the RB is not operating (the RB operating state flag is "0"), the process proceeds to step S945, and if it is determined that the RB is operating, the process proceeds to step S944.

In step S944, RB operation management is executed. This process determines whether or not the number of games when the RB operation of the address "F00F(H)" is "12", or the number of winnings when the RB operation of the address "F010(H)" is "8". If it is determined that the number of RB games is less than "12" and the number of winnings of the small winning combination is less than "8", the process of step S944 ends, and the process proceeds to step S945. On the other hand, in step S944, when it is determined that the number of games played by the RB reaches "12" or the number of winnings of the small winning combination reaches "8", the D3 bit of the operation state flag is set to "0". , And proceeds to step S945.
A step S945 executes advantageous section clear counter management. This processing is the processing shown in FIG. 51 or FIG. 52 shown in the eleventh embodiment, and includes the updating processing of the advantageous section clear counter and the difference number counter, the initialization processing when the ending condition of the advantageous section is satisfied, and the like. Execute. Then, the processing according to this flowchart is ended.

FIG. 149 is a flowchart showing the main game state game end processing in step S941 of FIG. 148.
First, in step S951, it is determined whether or not the advantageous section clear counter (_CT_ADV_CLR) of the addresses "F07A(H)" and "F07B(H)" is less than "600". When it is determined that it is less than "600", the process proceeds to step S952, and when it is determined that it is not less than "600", the process proceeds to step S955.
In step S952, it is determined whether or not the main game state 1 (advantageous zone normal (non-AT)). This process is a process of determining whether or not the main game state number of the address "F07E(H)" is "1". When it is determined that the main gaming state 1 is set, the process proceeds to step S957, and when it is determined that the main gaming state 1 is not set, the process proceeds to step S953.

In step S953, it is determined whether or not the main gaming state 5 (AT pullback). This process is a process of determining whether or not the main game state number of the address "F07E(H)" is "5". If it is determined to be in the main gaming state 5, the process proceeds to step S954, and if it is determined to be not in the main gaming state 5, the process according to this flowchart is ended.
In step S954, it is determined whether the AT pullback counter is "0". This process is a process of determining whether or not the value of the address “F09D(H)” is “0”. When it is determined that the AT pullback counter is "0", the process proceeds to step S957, and when it is determined that it is not "0", the process according to this flowchart is ended.

On the other hand, when proceeding from step S951 to step S955, it is determined whether or not the ending condition of the main gaming state 4 is satisfied. This process determines whether or not the number of obtainable images at the time of 1BB operation of the address "F00E(H)" is "0", and when it is "0", the ending condition of the main gaming state 4 (1BB operation) It is determined to satisfy. When it is determined that the ending condition of the main gaming state 4 is satisfied, the process proceeds to step S956, and when it is determined that the ending condition of the main gaming state 4 is not satisfied, the process of this flowchart is ended.
In step S956, it is determined whether the ending counter has changed from "1" to "0". This process determines whether the ending counter of the address "F097(H)" has been updated from "1" to "0" in the current game. When it is determined that the ending counter has changed from "1" to "0", the process proceeds to step S957, and when it is determined that the ending counter has not changed from "1" to "0", the process according to this flowchart ends.
In step S957, the advantageous section end preparation (M_ADVEND_STBY) is executed. This process is a process shown in FIG. 150 described later. Then, after executing the preparation for ending the advantageous section, the processing according to this flowchart is ended.

FIG. 150 is a flowchart showing the advantageous zone end preparation (M_ADVEND_STNBY) in step S957 of FIG. 149.
In step S961, “1” is stored in the advantageous zone clear counter. This processing executes the following processing.
(1) Store "1(H)" in the HL register. As a result, the H register value becomes "0 (H)" and the L register value becomes "1 (H)".
(2) Next, the L register value “1(H)” is stored in the lower address (F07B(H)) of the advantageous period clear counter, and the H register value “0(H)” is stored in the upper address (F07A(H)). ”Is remembered.
Then, the processing according to this flowchart is ended. From the above, the upper byte of the advantageous section clear counter is “00000000(B)” and the lower byte is “00000001(B)”.

By storing "1" in the advantageous period clear counter by the above-described preparation of the advantageous period end, it becomes unnecessary to store the data indicating whether or not the termination condition of the advantageous period is satisfied in the predetermined address of the RWM 53.
If the data indicating whether or not the end condition of the advantageous section is satisfied is stored in a predetermined address of the RWM 53, the capacity of the RWM 53 is compressed accordingly.
Further, when the end condition of the advantageous section is satisfied, a process of storing data indicating that the end condition of the advantageous section is satisfied at a predetermined address of the RWM 53 is required. Furthermore, it is necessary to read each game and the data stored at the predetermined address and determine whether or not the end condition of the advantageous section is satisfied. Therefore, the program capacity is required accordingly, and the capacity of the ROM 54 is pressed.

On the other hand, in the twenty-third embodiment, only "1" is stored in the advantageous period clear counter in preparation for ending the advantageous period, and "1" is subtracted in step S422 in the advantageous period counter management executed thereafter, for example, in FIG. When the processing is executed, the value before the subtraction becomes "1" and the value after the subtraction becomes "0", so that "No" is obtained in step S423, "Yes" is obtained in step S424, and the process proceeds to step S435. It becomes possible to execute the clearing process of the RWM 53 at the end of the advantageous section.

FIG. 151 is a flowchart showing an interrupt process (I_INTR) in the 23rd embodiment, which is a flowchart corresponding to FIG. 53 of the 11th embodiment. 151, the same steps as those in FIG. 53 are designated by the same step numbers.
In FIG. 151, the reel drive control in step S461 of FIG. 53 is the reel drive management (I_REEL_ADM) of step S841, and this specific processing will be described in detail.
Further, in FIG. 151, a test signal output is provided in step S842. Note that the processing is omitted in FIG. 53 of the eleventh embodiment, and the test signal output is not provided in the eleventh embodiment.
The test signal output in step S842 may include the output of the pushing order in the current game and the data of the designated position of the reel 31. Further, for example, the output of the condition device information or the like may be included, but the description thereof is omitted in the twenty-third embodiment.

Furthermore, in the 23rd embodiment, the interrupt cycle is "1.117" ms, which is different from the other embodiments (2.235 ms).
Here, when the interrupt cycle is “2.235” ms, the drive control of the reel 31 is executed for each interrupt (for example, in the eleventh embodiment, step S461 in FIG. 53), but in the twenty-third embodiment. As described above, when the interrupt cycle is “1.117” ms, the drive control of the reel 31 (processing after step S872 of FIG. 154, which will be described later) is executed once every two interrupts.

FIG. 152 is a flowchart showing reel drive management (I_REEL_ADM) in step S841 of FIG. 151.
Here, the program shown in FIG. 152 (including FIG. 153, FIG. 154 to FIG. 155, FIG. 157, and FIG. 159, which will be described later) is used not only in the reel control during the standby effect but also in the normal reel control. Therefore, it is possible to execute the normal reel control and the standby effect (reverse rotation of the reel 31) by the program shown in FIG. 152 without providing a program dedicated to the standby effect.
In FIG. 152, in step S851, the number of reels is set. The number of reels is "3". Here, a process of storing "00000100(B)" in the C register is performed.
In the next step S852, the reel control data address set (C_RLDAT_SET) is executed. This process is a process shown in FIG. 153, which will be described later, and is a process of storing the value of the reel drive state to be controlled or its address in each register. By the process of step S852, each register value becomes as follows.
A register value: value of reel drive state (_WK_RL#_STS) of reel 31 to be controlled DE register value: address of reel drive state (_WK_RL#_STS) of reel 31 to be controlled HL register value: control target Address of reel drive status (_WK_RL#_STS) of reel 31

In the next step S853, reel drive control (I_REEL_CTL) is executed. This process is a process for actually accelerating, constant speed, decelerating, and stopping the reel, and is a process shown in FIGS. 154 to 155 described later.
In the next step S854, it is determined whether or not the processes of steps S852 and S853 have been executed for all reels 31. In this process, first, a process of shifting the C register value to the right by "1" is executed. For example, since the initial value is "00000100 (B)" as described above, in the first step S854, a shift of "1" to the right results in "00000010 (B)". Next, it is determined whether or not the value after shifting "1" to the right has become "0". When it is determined to be "0", it is determined that the processes of steps S852 and S853 have been executed for all reels 31, and the process according to this flowchart ends. On the other hand, if it is determined that the value is not “0”, the process returns to step S852.

FIG. 153 is a flowchart showing the reel control data address set (C_RLDAT_SET) in step S852 of FIG.
First, in step S861, the start RWM address request set is performed. Here, the following processing is executed.
(1) The address of the first reel drive state (_WK_RL1_STS), that is, "F04D(H)" is stored in the HL register.
(2) The C register value is stored in the A register. The initial value of the C register value is "00000100(B)" as described above.
(3) Shift the A register value to the right by "1" and store the result in the A register. As a result, the A register value becomes "00000010 (B)" in the first calculation.
(4) The A register value is multiplied by “11(D)” and the multiplication result is stored in the A register. Here, when "00000010 (B)", that is, "2 (D)" is multiplied by "11 (D)", "22 (D)", that is, "16 (H)" is obtained.

The “11(D)” is based on the address interval stored in the RWM 53. Specifically, the address for storing the first reel drive state is “F04D(H)”, and various information regarding the first reel is stored up to “F057(H)”. The address for storing the second reel drive state is "F058 (H)", and various information regarding the second reel is stored up to "F062 (H)". Furthermore, the address for storing the third reel drive state is "F063(H)", and various information regarding the third reel is stored up to "F06D(H)".
In this way, the interval between the address “F04D(H)” for storing the first reel drive state and the address “F058(H)” for storing the second reel drive state is the “11” address, and the second The interval from the address "F058(H)" for storing the reel driving state to the address "F063(H)" for storing the third reel driving state is "11" address. This makes it possible to obtain the reel drive state information for the reel to be controlled, for example, by repeatedly executing the same process in the subsequent processes.

Further, various information for each reel 31 is also arranged at the same intervals. For example, the address of the first reel drive pulse output counter is the address “F04E(H)” obtained by adding “2” to the address “F04D(H)” in the first reel drive state. Similarly, the address of the second reel drive pulse output counter is the address “F05A(H)” obtained by adding “2” to the address “F058(H)” in the second reel drive state. Similarly, the address of the third reel drive pulse output counter is the address "F065(H)" obtained by adding "2" to the address "F063(H)" in the third reel drive state. The same applies to other information.
Thereby, for example, in step S881 (FIG. 154) described later, “6” is added to the address of the # reel driving state to calculate the address of the # reel symbol number (for passing position) (_NB_RL#_PASPIC). However, for the first reel 31, for example, "6" is added to the address "F04D(H)" in the first reel drive state, and the address "F053(H" for the first reel symbol number (for passing position) is added. )” can be requested. Similarly, for the second reel 31, add "6" to the address "F058(H)" of the second reel drive state, and the address "F05E(H)" of the second reel symbol number (for passing position). Can be asked.
In this way, by repeatedly executing the same module, processing for three reels can be executed.

Next, proceeding to step S862, designated address data is set. Here, the following processing is executed.
(1) The A register value is added to the HL register value, and the addition result is stored in the HL register. In the first calculation, the A register value is “16(H)”, so adding “16(H)” to the HL register value “F04D(H)” gives “F063(H)”.
(2) The data stored at the address indicated by the HL register value is stored in the A register.
(3) Store the H register value in the D register.
(4) Store the L register value in the E register.
By this process,
A register value: value of third reel drive state (_WK_RL3_STS) HL register value: address value of third reel drive state (_WK_RL3_STS) (H register value is upper address, L register value is lower address) "F063(H )"
DE register value: "F063(H)" which is the address value of the third reel drive state (_WK_RL3_STS) (D register value is upper address, E register value is lower address)
Becomes
Then, the processing according to this flowchart is ended.

The reel control data address set (C_RLDAT_SET) in FIG. 153 is executed three times in total until it is determined as “Yes” in step S854 in FIG.
The second calculation by the reel control data address set (C_RLDAT_SET) is as follows.
(1) Step S861
a) The address of the first reel drive state (_WK_RL1_STS), that is, "F04D(H)" is stored in the HL register.
b) Store the C register value in the A register. The second time, the C register value is "00000010 (B)".
c) Shift the A register value to the right by "1" and store the result in the A register. As a result, the A register value becomes “00000001(B)”.
d) The A register value is multiplied by "11(D)", and the multiplication result is stored in the A register. Here, when "0000001 (B)", that is, "1 (D)" is multiplied by "11 (D)", "11 (D)", that is, "0B (H)" is obtained.

(2) Step S862
a) Add the A register value to the HL register value and store the addition result in the HL register. Here, in the second calculation, the A register value is "0B(H)", so if "0B(H)" is added to the HL register value "F04D(H)", "F058(H)" is obtained. Become.
b) The data stored at the address indicated by the HL register value is stored in the A register.
c) Store the H register value in the D register.
d) Store the L register value in the E register.
By this process,
A register value: second reel drive status (_WK_RL2_STS) value HL register value: second reel drive status (_WK_RL2_STS) address value (H register value is upper address, L register value is lower address) "F058 (H )"
DE register value: "F058 (H)" which is the address value of the second reel drive state (_WK_RL2_STS) (D register value is upper address, E register value is lower address)
Becomes

The third operation of the reel control data address set (C_RLDAT_SET) is as follows.
(1) Step S861
a) The address of the first reel drive state (_WK_RL1_STS), that is, "F04D(H)" is stored in the HL register.
b) Store the C register value in the A register. The third time, the C register value is “00000001(B)”.
c) Shift the A register value to the right by "1" and store the result in the A register. As a result, the A register value becomes "00000000(B)".
d) The A register value is multiplied by "11(D)", and the multiplication result is stored in the A register. Here, when "00000000 (B)" is multiplied by "11 (D)", it becomes "0".

(2) Step S862
a) Add the A register value to the HL register value and store the addition result in the HL register. Here, in the third calculation, the A register value is "0", and therefore, "0" is added to the HL register value "F04D(H)" to obtain "F04D(H)".
b) The data stored at the address indicated by the HL register value is stored in the A register.
c) Store the H register value in the D register.
d) Store the L register value in the E register.
By this process,
A register value: value of first reel driving state (_WK_RL1_STS) HL register value: address value of first reel driving state (_WK_RL1_STS) (H register value is upper address, L register value is lower address) "F04D(H )"
DE register value: "F04D(H)" which is the address value of the first reel drive state (_WK_RL1_STS) (D register value is upper address, E register value is lower address)
Becomes

154 and 155 are flowcharts showing the reel drive control (I_REEL_CTL) in step S853 of FIG. 152. FIG. 155 is a flowchart following FIG. 154.
In FIG. 154, in step S871, it is determined whether or not the interrupt processing this time is the excitation update timing. Here, the following processing is performed.
(1) An exclusive OR (XOR) operation of the A register value (value of the #th reel drive state (_WK_RL#_STS)) and “10000000(B)” is performed, and the operation result is stored in the A register.
Thus, when the D7 bit of the A register value before the operation is “0”, the operation results in “1”, and when the D7 bit of the A register value before the operation is “1”, the operation results in the “0”. It becomes. The D0 to D6 bits do not change before and after the calculation.
(2) The A register value is stored in the address indicated by the HL register value (the address indicated by the #th reel drive state (_WK_RL#_STS )).
(3) It is determined whether or not the D7 (most significant) bit stored in the address indicated by the HL register value is "0", and when it is "0", it is determined that it is the excitation update timing. ..

As described above, the D7 bit of the # reel drive state (_WK_RL#_STS) takes a value of “0” or “1” for each interrupt processing. Therefore, once every two interrupts, the D7 bit becomes "0", and the excitation update timing comes.
Then, when it is determined that it is the excitation update timing, the process proceeds to step S872, and when it is determined that it is not the excitation update timing, the processing according to this flowchart ends. In other words, the processing after step S872 of reel drive control (I_REEL_CTL) is executed once every two interrupts. Therefore, the counter and the data updated in the processing of step S872 and thereafter can be updated every two interrupts. The control for driving the motor 32 (output process from the output port) is executed for each interrupt.

In the next step S872, a reel rotation start waiting counter is acquired. Here, the following processing is executed.
(1) The HL register value is saved in the stack area.
(2) Add “9” to the HL register value to make the HL register value the address value of the # reel rotation start waiting counter (_CT_RL#_WAIT ).
Next, proceeding to step S873, the countdown (“1” subtraction) of the counter value stored at the address indicated by the HL register value is executed.
It should be noted that "0" is stored in the # reel rotation start standby counter (_CT_RL#_WAIT) when there is no standby effect, and when there is a standby effect, it is for random delay of the # reel 31 after the standby effect. The counter value is stored.
Then, the processing proceeds to step S874, and it is determined whether or not there is a standby at the start of reel rotation. Here, when the value before subtraction of "1" in step S873 is not "0" (when the carry flag does not become "1"), it is determined that there is no standby at the start of reel rotation, and the process proceeds to step S875. On the other hand, if it is determined that there is a standby at the start of reel rotation, the processing according to this flowchart is ended.

In the next step S875, it is determined whether or not the reel 31 is stopped. Here, the following processing is executed.
(1) The value saved in the stack area (the address value of the #th reel drive state (_WK_RL#_STS)) is restored to the HL register.
(2) The data stored at the address indicated by the HL register value is stored in the A register.
(3) When the A register value is "0", it is determined that the reel 31 is stopped.
When the process proceeds to step S875, the D7 bit in the # reel drive state (_WK_RL#_STS) is "0".
When it is determined in step S875 that the reel 31 is not stopped, the process proceeds to step S876, and when it is determined that the reel 31 is stopped, the process according to this flowchart ends.

In step S876, it is determined whether the reel 31 is accelerating or decelerating. Here, when the A register value (the value of the #th reel driving state (_WK_RL#_STS)) is less than “3”, it is determined that the reel 31 is accelerating or decelerating.
If it is determined that the reel 31 is accelerating or decelerating, the process proceeds to step S882, and if it is determined that the reel 31 is not accelerating or decelerating, the process proceeds to step S877.

In step S877, it is determined whether the reel 31 is in constant speed or starts deceleration. Here, it is determined whether or not the A register value is "0". When it is not "0", it is determined that the reel 31 is in constant speed or starts decelerating, and when it is "0", the reel 31 is It is determined that 31 is not in the constant speed or does not start deceleration.
If it is determined that the reel 31 is in constant speed or deceleration start, the process proceeds to step S892, and if it is determined that the reel 31 is not in constant speed or deceleration start, the process proceeds to step S878.
In step S878, acceleration setting processing is executed. Here, the following processing is executed.
(1) Store the E register value in the L register. Since the E register value is the lower address value of the reel drive state (_WK_RL#_STS), the address of the #th reel drive state (_WK_RL#_STS) is stored in the HL register by this processing.
(2) “2(D)” is stored in the address indicated by the HL register value. As a result, the value indicating the reel drive state becomes "2" (value corresponding to acceleration).

In the next step S879, the reel drive pulse output counter and the reel drive pulse switching count are initialized. Here, the following processing is executed.
(1) "1" is stored at the address indicated by the value obtained by adding "2" to the HL register value. Here, the address indicated by the value obtained by adding “2” to the HL register value becomes the address of the # reel drive pulse output counter (_CT_RL#_PLSOUT).
(2) "9" is stored at the address indicated by the value obtained by adding "3" to the HL register value. Here, the address indicated by the value obtained by adding “3” to the HL register value becomes the address of the #th reel drive pulse switching count (_CT_RL#_PLSCHG).

Next, proceeding to step S880, it is determined whether or not a standby effect is being produced. In this process, it is determined whether or not the standby effect type (_WK_PRD) of the address "F09E(H)" is "0", and when it is "0", it is determined that the standby effect is not in progress. If it is determined that the standby effect is not being performed, the process proceeds to step S881, and if it is determined that the standby effect is being performed, the process proceeds to step S882.
In step S881, the symbol number (for the passing position) and the symbol number (for the stop position) are initialized. Here, the following processing is executed.
(1) The initial value “255(D)” (FF(H)) is stored in the address obtained by adding “6” to the HL register value. Here, the address obtained by adding "6" to the HL register value is the address of the # reel symbol number (for passing position) (_NB_RL#_PASPIC).
(2) The initial value “255(D)” (FF(H)) is stored in the address obtained by adding “7” to the HL register value. Here, the address obtained by adding “7” to the HL register value is the address of the # reel symbol number (for stop position) (_NB_RL#_STPPIC).

In the next step S882, the reel drive pulse output counter is decremented by "1". Here, the following processing is executed.
(1) The HL register value is set as the address of the # reel drive pulse output counter (_CT_RL#_PLSOUT).
(2) Subtract "1" from the data stored at the address indicated by the HL register value.
Next, proceeding to step S883, it is determined whether or not the reel drive pulse output counter is "0". This process determines whether or not the result of subtracting "1" in (2) above is "0". If it is determined to be "0", the flow proceeds to step S884, and if it is determined to be not "0", the process according to this flowchart is ended.

In the next step S884, it is determined whether or not the number of times of reel drive pulse switching is "0". Here, the following processing is executed.
(1) The HL register value is set to the address value of the # reel drive pulse switching count (_CT_RL#_PLSCHG).
(2) The data stored at the address indicated by the HL register value is stored in the A register.
(3) Store the A register value in the B register.
(4) When it is determined that the A register value is "0", it is determined that the number of times of reel drive pulse switching is "0".
If it is determined that the number of times of reel drive pulse switching is “0”, the process proceeds to step S914 (FIG. 155), and if it is determined not to be “0”, the process proceeds to step S885.

In step S885, "1" is subtracted from the reel drive pulse switching count. This process is a process of subtracting "1" from the data stored at the address indicated by the HL register value (the address of the #th reel drive pulse switching number (_CT_RL#_PLSCHG)). The value obtained by subtracting “1” is stored in the A register.
In the next step S886, the acceleration/deceleration pulse output counter table (TBL_PULSE_UP) is set.
FIG. 156 is a diagram showing an acceleration/deceleration pulse output counter table (TBL_PULSE_UP).
In FIG. 156, the numerical value “90 (D)” of the address “1050 (H)” indicates the pulse output counter value during deceleration. Further, the numerical values of the addresses "1058 (H)" to "1051 (H)" indicate the pulse output counter values of the first to eighth steps during acceleration.
Then, in step S886, the start address "1050 (H)" of the acceleration/deceleration pulse output counter table (TBL_PULSE_UP) is stored in the HL register.

In the next step S887, designated data is acquired from the acceleration/deceleration pulse output counter table (TBL_PULSE_UP). In this process, the data (pulse output counter value) stored at the address of the value obtained by adding the A register value (# reel drive pulse switching count) to the HL register value (1050 (H)) is stored in the B register. It is a process to do.
Next, proceeding to step S888, the reel drive pulse output counter is stored. Here, the following processing is executed.
(1) Store the E register value in the L register.
(2) Store the D register value in the H register.
By this processing, the address of the #th reel drive state (_WK_RL#_STS) is stored in the HL register.
(3) The B register value (pulse output counter value) is stored in the address indicated by the value obtained by adding “2” to the HL register value.
Here, the address indicated by the HL register value is the address of the #th reel drive state (_WK_RL#_STS), and the address added with “2” is the address of the #th reel drive pulse output counter (_CT_RL#_PLSOUT). It becomes an address.

In the next step S889, it is determined whether or not the acceleration is completed. In this process, it is determined whether or not the A register value (the number of times the # reel drive pulse has been switched) is “0”, and when it is “0”, it is determined that the acceleration is completed. When it is determined that the acceleration is completed, the process proceeds to step S890, and when it is determined that the acceleration is not completed, the process proceeds to step S892.
In step S890, a constant speed is set. In this process, "5" is stored in the address indicated by the HL register value (the # reel driving state (_WK_RL#_STS)).
In the next step S891, the reel rotation failure detection counter is cleared. This process is a process of storing "0" in the address of the value obtained by adding "4" to the HL register value (the address of the #th reel rotation defect detection counter (_CT_RL#_BAD)).
In the next step S892, the reel drive pulse is updated (I_PULSE_INC). This process is a process shown in FIG. 157 described later.

Next, proceeding to step S893, it is determined whether or not the reel 31 is at a constant speed. Here, the following processing is executed.
(1) Store the E register value in the L register.
(2) The data stored in the address (the # reel motor index (_FL_RL#_MT_IDX)) indicated by the value obtained by adding “1” to the HL register value is stored in the A register.
(3) Add “4” to the HL register value. As a result, the HL register value becomes the address of the #th reel rotation failure detection counter (_CT_RL#_BAD).
(4) When the data stored at the address indicated by the DE register value is "5", it is determined that the constant speed is in progress.
Here, the address indicated by the DE register value is the address in the #th reel driving state (_WK_RL#_STS) in step S888.
When it is determined that the vehicle is traveling at constant speed, the process proceeds to step S894, and when it is determined that the vehicle is not traveling at constant speed, the process proceeds to step S903.

In step S894, "1" is added to the reel rotation failure detection counter. This process is a process of adding "1" to the value stored in the address indicated by the HL register value.
Next, proceeding to step S895 in FIG. 155, it is determined whether or not it is time to detect a reel rotation failure. This process determines whether or not the result of adding "1" to the reel rotation failure detection counter in step S894 is "0", and when it is "0" (when the zero flag is "1"). It is determined that the reel rotation failure is detected.
If it is determined that the reel rotation is not required, the process advances to step S878 to execute the acceleration process again. On the other hand, when it is determined that the reel rotation failure is not detected, the process proceeds to step S896.

In step S896, it is determined whether or not the # reel motor index (motor index # signal) has changed. This process determines whether or not there is a change in the motor index # signal based on the A register value (the value of the # reel motor index (_FL_RL#_MT_IDX)), and when it is determined that there is a change, the process proceeds to step S897. If it is determined that there is no change, the process proceeds to step S903.
In step S897, the reference symbol number "10" and the reference step number "3" at the time of passing through the index are set. This process is a process of storing "10(D)" in the D register and "3(D)" in the E register.
Here, “10 (D)” stored in the D register is the value stored in the # reel symbol number (for passing position) (_NB_RL#_PASPIC) thereafter. Further, "3(D)" stored in the E register is a value stored in the step number (_NB_RL#_STEP) of the first symbol on the # reel after this, and both are design values.

In the next step S898, it is determined whether or not it is the rising time of the # reel motor index. This process is based on the A register value (the value of the # reel motor index (_FL_RL#_MT_IDX)) and when the D0 bit is “1” and the D4 bit is “0”, the # reel motor index rises. Judge that it is time. If it is determined that the # reel motor index is rising, the process proceeds to step S900, and if it is determined that the # reel motor index is not rising, the process proceeds to step S899.

In step S899, the reference drawing number “0” and the reference step number “3” when passing through the index are set. This process is a process of storing "0" in the D register and "3(D)" in the E register. That is, "0" is stored in the value that becomes the # reel symbol number (for passing position) (_NB_RL#_PASPIC), and the value that becomes the step number (_NB_RL#_STEP) of the 1 symbol of the # reel is "3 (D )” is memorized.
In the next step S900, the #th reel rotation failure detection counter (_CT_RL#_BAD) is cleared. This process is a process of storing "0" in the data stored in the address indicated by the HL register value (the address of the #th reel rotation defect detection counter (_CT_RL#_BAD)).

In the next step S901, the # reel drive pulse data search counter (_CT_RL#_PLUS) is acquired. This process is a process of storing the data stored at the address of the value obtained by adding "4" to the HL register value in the A register.
Here, the HL register value is the address value of the #th reel rotation defect detection counter (_CT_RL#_BAD) as described above, and if "4" is added to this address value, the #reel drive pulse data search counter It becomes the address value of (_CT_RL#_PLUS).

In the next step S902, the reference symbol number and reference step number when passing through the index are stored. Here, the following processing is executed.
(1) The E register value is stored at the address of the value obtained by adding “1” to the HL register value. Here, the address of the value obtained by adding “1” to the HL register value is the step number (_NB_RL#_STEP) of the first symbol on the # reel. The E register value "3" is stored at this address.
(2) The D register value is stored at the address of the value obtained by adding “2” to the HL register value. Here, the address of the value obtained by adding “2” to the HL register value is the # reel symbol number (for passing position) (_NB_RL#_PASPIC). The D register value (“10(D)” set in step S897 when the # reel motor index rises, “0” set in step S899 when it falls) is stored in this address. Then, the processing according to this flowchart is ended.
As described above, when steps S896 to S902 are executed, the step number (_NB_RL#_STEP) of one symbol on the # reel and the # reel on every rise and fall of the # reel motor index. A reference value (design value) is set to the symbol number (for passing position) (_NB_RL#_PASPIC).

Thus, in the twenty-third embodiment, both the rising and falling times of the reel motor index are detected, and the step number and the passing position symbol number of one symbol are updated respectively, so only when the reel motor index rises. In some cases, the reel 31 can be stopped before it makes one rotation, as compared with the case of detecting. Further, even if there is a problem in the rotation of the reel 31, it is possible to immediately correct the rotation.
As described above, the reel drive control (I_REEL_CTL) is executed regardless of the normal time (during normal rotation) or the standby effect (during reverse rotation). Therefore, in step S898, it is determined whether or not it is the rising time regardless of whether it is the normal time (during normal rotation) or the standby performance (reverse rotation), and in step S902, at the rising time or rising time. A predetermined value is set according to the time.

On the other hand, if it is determined at step S893 that the speed is not constant, and if it is determined at step S896 that the # reel motor index has not changed, then the flow proceeds to step S903. In step S903, it is determined whether the index has passed (whether the reel sensor 33 has detected the index). Here, the following processing is executed.
(1) The data stored in the address of the value obtained by adding “2” to the HL register value is stored in the A register.
The HL register value is the address value of the #th reel rotation defect detection counter (_CT_RL#_BAD), and if "2" is added to this address value, the # reel symbol number (for passing position) (_NB_RL#_PASPIC) It becomes an address value.
(2) Add "1" to the value stored in the A register.
(3) When the result of adding "1" in (2) above is "0", it is determined that the index has not passed since the # reel motor index has not changed from the initial value.

Here, as described above, the initial value “255 (D)” (FF (H)) is stored in the # reel symbol number (for passing position) (_NB_RL#_PASPIC), and the # reel motor index of the # reel motor index is stored. When the value changes, "0" or "10(D)" is stored in step S902, and thereafter, "0" to "19(D)" are cycled. In other words, after the value of the # reel motor index changes, if the reel 31 is rotating normally, the # reel symbol number (for passing position) (_NB_RL#_PASPIC) is “255”. (D)” does not occur (when the acceleration process is executed again due to step-out, "255(D)" is stored again as the initial value).
Therefore, if you add "1" to the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and it becomes "0," it can be determined that the # reel motor index has not changed. Becomes

If it is determined in step S903 that the index has already passed, the process proceeds to step S904, and if it is determined that the index has not yet passed, the process according to this flowchart ends.
In step S904, "1" is subtracted from the number of one symbol step. Here, the following processing is executed.
(1) "1" is added to the HL register value, and the addition result is stored in the HL register. Here, the HL register value before the addition of "1" is the address value of the # reel rotation failure detection counter (_CT_RL#_BAD), so if "1" is added, the number of steps of one symbol on the # reel (_NB_RL #_STEP) address value.
(2) Subtract "1" from the value stored at the address indicated by the HL register value.

In the next step S905, it is determined whether or not one symbol has moved. Here, as a result of the subtraction of "1" in step S904, when the value of the number of steps (_NB_RL#_STEP) of one symbol on the # reel becomes "0" (when the zero flag becomes "1"), It is judged that one symbol has moved. When it is determined that one symbol has moved, the process proceeds to step S906, and when it is determined that one symbol has not moved (the subtraction result is not "0"), the process proceeds to step S909.
In step S906, the number of one symbol step "16(D)" is stored. This process is a process of storing "16(D)" in the address indicated by the HL register value (the number of steps of one symbol on the # reel (_NB_RL#_STEP)).

In the next step S907, the symbol number is updated. Here, the following processing is executed.
(1) "1" is added to the HL register value, and the value after addition is stored in the HL register. As a result, the address indicated by the HL register value becomes the # reel symbol number (for passing position) (_NB_RL#_PASPIC).
(2) The special addition process of adding "1" to the value stored at the address indicated by the HL register value is executed. Here, in this example, the "special addition process" means that the upper limit value is set to "19(D)" (corresponding to the maximum value of the symbol number), and "1(D)" is set to "19(D)". Is an operation that adds "0". Specifically, the calculation is performed as follows.
Example 1) 0+1=1
Example 2) 10+1=11
Example 3) 19+1=0
As a result, it is possible to circulate between “0” and “19(D)” without determining whether or not the symbol number is the maximum value.

Next, proceeding to step S908, the number of one symbol step is corrected. In step S906, "16 (D)" is stored in the step number (_NB_RL#_STEP) of one symbol on the # reel.
Here, in the twenty-third embodiment, the number of steps of one symbol is set to "16" for the four symbols having the symbol numbers "2", "7", "12", and "17", and the other 16 symbols For, the number of steps for one symbol is set to "17".
Therefore, in step S908, the symbol number after the update in step S907 is determined, and when the symbol numbers are "2", "7", "12", and "17", in the step S906, the #1 reel The "16(D)" stored in the number of steps of the symbol (_NB_RL#_STEP) is maintained. On the other hand, when it is a symbol number other than the above-mentioned four symbol numbers, “17(D)” is stored in the step number (_NB_RL#_STEP) of one symbol on the # reel.
The number of steps for one rotation of the reel 31 is set to "336" in accordance with the number of steps of the motor 32. The number of symbols is "20". Therefore, by setting the number of steps to "16" for 4 symbols and the number of steps to "17" for 16 symbols,
16 x 4 + 17 x 16 = 336
Is set so that

In the next step S909, it is determined whether or not the deceleration start symbol position has been reached. Here, in order to compare the passing symbol number and the deceleration start symbol, the following process is executed.
(1) "1" is subtracted from the HL register value (# reel symbol number (for passing position) (_NB_RL#_PASPIC)), and the subtraction result becomes the HL register value. As a result, the HL register value becomes the address of the step number (_NB_RL#_STEP) of one symbol of the # reel.
Further, the value stored in the address indicated by the HL register value is stored in the B register. The number of steps of one symbol on the # reel is stored in the B register for use in the deceleration start inspection (I_REDUCE_CHK) processing in step S910 described later.
(2) "1" is added to the HL register value, and the addition result is used as the HL register value. As a result, the HL register value becomes the address of the # reel symbol number (for passing position) (_NB_RL#_PASPIC).
(3) The value stored in the address indicated by the HL register value is stored in the A register.
(4) "1" is added to the HL register value, and the addition result is used as the HL register value.
(5) The value stored in the address (# reel symbol number (for stop position) (_NB_RL#_STPPIC)) indicated by the HL register value is compared with the A register value, and if the values are the same, it is determined as “Yes” To do.

In the next step S910, a deceleration start inspection (I_REDUCE_CHK) is executed. This process is an inspection as to whether or not the condition that deceleration can be started is satisfied, and is the process shown in FIG. 159 described later.
Then, in the next step S911, it is determined whether or not it is the time to start deceleration. In this processing, when the zero flag is "1" as a result of the deceleration start inspection in step S910, it is determined that the deceleration is started.
Although the details will be described later, the zero flag is "1" when the standby effect type is "0". When the standby effect type is not "0" (at the time of reverse rotation standby effect), the # reel designation symbol position search standby time (TM2_TAR#_WAIT) is "0", and the current step number is "13" ( If the value is the design value), the zero flag becomes “1”.

When it is determined that the deceleration is started, the process proceeds to step S912, and when it is determined that the deceleration is not started, the process according to this flowchart is ended.
In step S912, deceleration is set. This process is a process of storing "1" in the A register.
In the next step S913, pulse data during deceleration is set (4 phase ON). This process is a process of storing "00001111(B)" in the B register.
In the next step S914, the reel drive state is set. This process is a process of storing the A register value at the address indicated by the DE register value. Here, the DE register value is the address of the #th reel drive state (_WK_RL#_STS). As a result, the # reel drive state becomes “1” (value indicating deceleration).

Next, proceeding to step S915, the reel drive pulse is set. This process is a process of storing the B register value in the #th reel motor signal data (_PT_MOTOR#).
In the next step S916, it is determined whether or not the deceleration start state is changed to the deceleration state. In this process, it is determined whether or not the B register value is "0", and when it is not "0", it is determined that the deceleration has started and the deceleration has started. If it is determined that deceleration has started from the start of deceleration, the process proceeds to step S917, and if not, the process according to this flowchart ends.
As described above, since "00001111(B)" is stored in the B register in step S913, when the process proceeds to step S916 via step S913, it is determined that it is not "0", and deceleration is starting from deceleration start. It is determined that On the other hand, when it is determined to be “Yes” in step S884 and the process proceeds to step S914, the B register value is “0” in step S884, and thus “No” is determined in step S916.
In step S917, an output request when the reel rotation is stopped is set. This process is a process for transmitting the symbol number of the reel 31 to be stopped to the sub control board 80. Then, the processing according to this flowchart is ended.

FIG. 157 is a flowchart showing the reel drive pulse update (I_PULSE_INC) in step S892 of FIG. 154.
First, in step S921, "1" is added to the reel drive pulse data search counter. Here, the following processing is executed.
(1) Add “8” to the HL register value and store the addition result in the HL register. Here, the HL register value before adding “8” is the address value of the # reel driving state (_WK_RL#_STS ), and when “8” is added, the HL register value is for the # reel driving pulse data search. It becomes the address value of the counter (_CT_RL#_PULS).
(2) Add "1" to the value stored at the address indicated by the HL register value.
Here, for example, if the value stored in the # reel drive pulse data search counter (_CT_RL#_PULS) is “255 (D)”, the result of adding “1” is “0”. Becomes

Next, proceeding to step S922, the search counter update correction data is added. Here, the following processing is executed.
(1) The value of the search counter update correction data (_WK_PLS_REV) at the address “F09F(H)” is stored in the A register. Here, when the value of the search counter update correction data (_WK_PLS_REV) is “0”, it means that it is forward rotation data, and when it is “FE(H)”, it is reverse rotation data. Means that.
(2) The A register value is added to the value (the # reel drive pulse data search counter (_CT_RL#_PULS)) stored at the address indicated by the HL register value, and the addition result is stored in the A register.

Here, since the A register value is "0" when the reel 31 is in the normal rotation, the A register value becomes the same value stored in the address indicated by the HL register value before the addition.
On the other hand, when the reel 31 is in the reverse rotation, the A register value is "FE(H)", so that the value stored in the address indicated by the HL register value before addition is substantially "2". "" is subtracted.
For example,
Value stored at the address indicated by the HL register value: 100 (D)
A register value: FE (H) or 254 (D)
When
The A register value is “98(D)”.

In the next step S923, the # reel drive pulse data search counter (_CT_RL#_PULS) is updated. This process is a process of storing the A register value at the address indicated by the HL register value.
By the above-described processing of steps S921 to S923, the # reel drive pulse data search counter (_CT_RL#_PULS) is incremented by "1" at the time of forward rotation, and is decremented by "1" at the time of reverse rotation.
Next, proceeding to step S924, a reel drive pulse data search offset is generated. This process is a process of performing a logical product (AND) operation of the A register value and "00000111(B)". Then, the result of the logical product operation is stored in the A register.
The A register value is a value of the # reel drive pulse data search counter (_CT_RL#_PULS), and is a value in the range of “0” to “255 (D)”. When this value and "00000111 (B)" are ANDed (AND), the operation result becomes a value of "0" to "7".

Specifically, it is as follows, for example.
Example 1) When the A register value is "00000000(B)", the logical product (AND) operation with "00000111(B)" yields "00000000(B)".
Example 2) When the A register value is "00000010 (B)", the logical product (AND) operation with "00000011 (B)" yields "00000010 (B)".
Example 3) When the A register value is "000100001 (B)", the logical product (AND) operation with "00000011 (B)" yields "00000001 (B)".
Example 4) When the A register value is "111111111(B)", the logical product (AND) operation with "00000111(B)" yields "00000111(B)".
That is, the maximum value after the logical product (AND) operation is “00000111 (B)” (7 (D)).

Next, proceeding to step S925, the reel drive pulse table is set. This process is a process of storing the address of the reel drive pulse table (TBL_REEL_PULSE) in the HL register.
FIG. 158 is a diagram showing a reel drive pulse table (TBL_REEL_PULSE). As shown in FIG. 158, eight types of reel drive pulse data are stored in the reel drive pulse table (TBL_REEL_PULSE). The upper 4 bits (D4 to D7 bits) of the reel drive pulse data are unused bits. The D0 bit corresponds to φ0 data, the D1 bit corresponds to φ1 data, the D2 bit corresponds to φ2 data, and the D3 bit corresponds to φ3 data. Then, “1” indicates on and “0” indicates off.
For example, “00001001(B)” stored in the address “1100(H)” means that φ0 and φ3 are turned on. Note that φ0 to φ3 correspond to the excitation phases of the 4-phase stepping motor.
Then, in step S925, "1100 (H)" which is the head address of the reel drive pulse table (TBL_REEL_PULSE) is stored in the HL register.

In the next step S926, reel drive pulse data is acquired. In this process, the result obtained by adding the A register to the HL register value is set as the HL register value, and the value of the address indicated by the HL register value is stored in the B register.
Here, the A register value is the offset value generated in step S924 (a value obtained by converting the reel drive pulse in the range of "0" to "255 (D)" into "0" to "7").
For example, when the A register value is "1", the value "0000001(B)" of "1101(H)" obtained by adding "1(H)" to the HL register value "1100(H)" is stored in the B register. Remember.
Next, proceeding to step S927, reel drive pulse data is set. This process is a process of storing the B register value in the #th reel motor signal data (_PT_MOTOR#). Then, the processing according to this flowchart is ended.

FIG. 159 is a flowchart showing the deceleration start inspection (I_REDUCE_CHK) in step S910 of FIG. 155.
First, in step S931, it is determined whether or not the standby effect type is "0". Here, it is determined whether or not the value stored in the standby effect type (_WK_PRD) of the address “F09E(H)” is “0”. When the value is “0”, it is determined as “Yes”. The process according to this flowchart is finished. On the other hand, if it is determined that the value is not "0", the process proceeds to step S932.
In step S932, it is determined whether the search standby time is "0". In this processing, it is determined whether or not the # reel designation symbol position search waiting time (_TM2_TAR#_WAIT) is "0", and when it is "0", it is determined to be "Yes" and the process proceeds to step S933. On the other hand, when it is determined that the value is not "0", the process according to this flowchart is ended.

In step S933, the deceleration start step number "13(D)" is set. Here, the following processing is executed.
(1) Set "13(D)" in the A register.
(2) A comparison operation is performed with the B register value.
Then, the processing according to this flowchart is ended.
The B register value is the number of steps of one symbol on the # reel (_NB_RL#_STEP) stored in step S909 of FIG. 155. When the comparison operation results in "0", the zero flag becomes "1". When the zero flag becomes "1", it is determined as "Yes" in step S911 in FIG. 155. In other words, the deceleration is set to start when the current number of steps becomes "13(D)" (design value).

Next, the control of the sub control board 80 that is unique to the twenty-third embodiment will be described.
(1) Output for Preventing Depression In the twenty-third embodiment, there is a case where an output for preventing depression is performed after one AT is set and before the next set is started. Here, in the twenty-third embodiment, the "output for preventing slipping-in" is equivalent to displaying an image such as "Pachinko/pachi-slot is a moderately enjoyable game. Be careful of slipping in." on the image display device 23. To do. In addition to the image display, you may output a voice such as "Pachinko/Pachislot is a moderately enjoyable game. Be careful not to get stuck." It may be either only image display, only sound, both image display and sound, but it is understood that at least image display is preferable.
Since the output for preventing the intrusion is generally executed when a certain number or more of medals have been paid out, in the twenty-third embodiment, one set of AT (main game state 4, 1BB operation) ends. At this time, if the output condition for preventing the intrusion is satisfied, the intrusion prevention output is executed.

FIG. 160 is a flowchart for controlling the intrusion prevention output during AT by the sub control board 80.
First, in step S971, it is determined whether or not AT is in progress. When it is determined that the vehicle is in AT, the process proceeds to step S972, and when it is determined that the vehicle is not in AT, the process according to this flowchart ends.
The sub control board 80 receives a command regarding the main game state from the main control board 50. When a command indicating that the main gaming state is "4" is received, it is determined that the AT is in progress.

In step S972, it is determined whether a notification indicating that the AT is continued is output. In the twenty-third embodiment, when the AT for the next time is fixed, in other words, when the AT set number counter is “1” or more, a notification indicating that the AT will be executed next time is also issued during the AT. There are cases of outputting (cases of notifying the continuation of AT) and cases of not outputting.
The sub control board 80 receives the command of the AT set number counter from the main control board 50. Under the situation where the next AT has not been decided (when the AT set number counter is "0"), the AT continuation notification is not output, but under the situation where the next AT has been decided (AT set number When the counter is “1” or more), it is determined whether or not to output the AT continuation notification by, for example, lottery. When it is decided to output the AT continuation notification, an effect for outputting the AT continuation notification is selected and the effect is output.

An example of outputting the AT continuation notification is, for example, an effect in which the main character and the enemy character confront each other and the main character wins. When the main character and the enemy character confront each other, and the production in which the main character wins is output, the next AT is settled, and the AT does not end at this AT (however, according to the notified push order). If the player does not operate the stop switch 42, there is a possibility that the advantageous section itself will end in the middle of the current AT due to the advantageous section clear counter management.) Further, when the main character and the enemy character confront each other and an effect that the main character loses is output, there are cases where the AT ends at the current AT and cases where the AT continues.

If it is determined in step S972 that the AT continuation notification is output, the process proceeds to step S973, and if it is determined that the AT continuation notification is not output, the process proceeds to step S974.
In step S973, the AT continuation notification flag is turned on. The AT continuation notification flag is provided in the storage area of the RWM 83 of the sub control board 80, and is a flag for determining whether or not the AT continuation is notified.

In step S974, it is determined whether one set of AT is completed. This determination is based on the command transmitted from the main control board 50, when the end condition of the main game state "4" is satisfied (at the end of the operation of the 1BB game (at the end of the game)), one set of AT It is judged that has ended. When it is determined that one set of AT is completed, the process proceeds to step S975, and when it is determined that it is not completed, the process according to this flowchart is completed.
In step S975, it is determined whether the AT continuation notification flag is on. When it is determined that the AT continuation notification flag is not on, the process proceeds to step S976, and when it is determined that it is on, the process proceeds to step S977.

In step S976, the AT end effect is output. Here, the "AT end effect" is an effect that suggests that the AT is ended and the non-AT is entered. Therefore, even if the AT set number counter is "1" or more at this time, if the AT continuation notification flag is not on, in other words, if the AT continuation notification is not output during the AT of this set, The AT end effect is output. Note that the AT does not necessarily end even if the AT end effect is output.

Next, the process proceeds to step S978, and the above-described intrusion prevention effect is output.
In the next step S979, it is determined whether or not it has the AT set number (whether or not the AT set number counter is “1” or more). If it is determined that the number of AT sets is not included, the processing according to this flowchart is ended. On the other hand, when it is determined that the AT set number is included, the process proceeds to step S980.
In step S980, an AT revival effect is output. That is, although the AT end effect is output in step S976, the reverse effect for negating the AT end effect is output.
On the other hand, when it is determined in step S975 that the AT continuation notification flag is ON, the process proceeds to step S977 to clear the AT continuation notification flag, and the processing according to this flowchart ends. Since the AT continuation notification has already been output when passing through step S977, it is not necessary to output the AT revival effect as in step S980. However, of course, at the end of one set of AT, an effect indicating that the AT continues may be output again.

Further, the AT end effect in step S976, the intrusion prevention effect in step S978, and the AT revival effect in step S980 may be sequentially output at predetermined time intervals without the operation of the player. Alternatively, after the AT end effect and the intrusion prevention effect are output, the player waits for the operation of the operation switch (the bet switch 40, the start switch 41, the adjustment switch 43), and when the operation switch is operated, the process proceeds to step S979. You may proceed.
Further, the slip-in prevention output in step S978 is secured for a certain period of time. For example, when the process proceeds to step S978, a predetermined timer value is set, the predetermined timer value is subtracted for each interrupt process, and the process of step S978 is performed on condition that the predetermined timer value becomes "0". It may be finished.
Specifically, it is preferable that the slip-in prevention output continues for at least 3 seconds.
Further, if the power is cut off while outputting the slip-in prevention, the slip-in prevention is not output when the power is restored. When the power is cut off while the slip-in prevention is being output and then the power is restored, the above predetermined timer value is cleared (cleared).

Therefore, even if the specification is such that the process proceeds from step S978 to S979 when the operation switch is operated, if the predetermined timer value is not "0" at the time the operation switch is operated, Continue to output the slip-in prevention of S978. Then, when the predetermined timer value becomes “0”, the process proceeds to step S979.
Further, even if the predetermined timer value becomes "0" after the output of the depression prevention is started in step S978, the depression prevention output may be maintained when the operation switch is not operated, or Alternatively, it may be switched to a demo screen such as displaying the logo of the game machine maker.

Further, when the 1BB game is over, the main control board 50 executes a wait process (also called "freeze process" or "standby process") for about 1 second. While the wait process is being executed, no matter what operation switch is operated, control based on that operation is not executed. Further, the blocker 45 is controlled so that the medals are returned even if the medals are thrown in while the weight process is being executed. The control of the main control board 50 is different from the control of the sub control board 80 because the power is cut off during the execution of the wait processing (for example, “0.3” seconds after the start of the wait processing). If the power is restored after that, the wait process is continuously executed when the power is restored (when the power is restored without shifting to the setting change mode). The timer managed on the main control board 50 side is not cleared when the power is cut off during the wait processing and then the power is restored (power restoration without shifting to the setting change mode). On the other hand, when the power supply is returned to the setting change mode, the wait processing timer value is cleared.

By controlling as described above, since the output for preventing the intrusion is secured for a certain period of time, the player can be surely shown the image display for preventing the intrusion.
It should be noted that the weight processing by the main control board 50 is about 1 second, and when the output for preventing the slip-in is about 3 seconds, the operation of the operation switch is effective when the wait processing is completed even during the output for preventing the slip-in. become. Therefore, when the operation switch is operated immediately after the end of the wait process, the next effect may be executed while continuing the output for preventing the intrusion. For example, after the output of the depression prevention in step S978 is started, the weight processing by the main control board 50 is finished, the operation switch becomes effective, and the AT revival effect in step S980 is output based on the operation of the bet switch 40, for example. In such a case, the AT revival effect is output while the depression prevention is output.

In the twenty-third embodiment, the output for preventing the intrusion is conditioned on the output of the AT end effect. Therefore, in the case of "Yes" in step S975, since the AT end effect is not output (step S976 is not executed), the stick-in prevention display is also not output.

As described above, when the player is informed of the continuation of the next AT at the end of one set of ATs (when the player knows the continuation of the AT), the inset prevention output is not executed, In other cases, since the depression prevention is output on condition that the AT end screen is output, it is possible to prevent the continuation of the AT from being determined based on the presence or absence of the depression prevention output.
In other words, if AT is stopped when the indentation prevention is output and AT is not ended when the intrusion prevention is not output, the continuation of the AT is known depending on the presence or absence of the intrusion prevention output.
Further, when the player knows that the AT continues, even if the output for preventing the intrusion is not effective, there is an effect that unnecessary output is not required.

(2) Output of confrontation production (variation of output timing at production end)
In the twenty-third embodiment, a confrontation effect may be output during the AT as an effect indicating whether or not the AT will continue next time.
The confrontation effect of the twenty-third embodiment is an effect that indicates that the AT will continue next time when the main character side character and the enemy character confront each other and the main character side character wins. Here, when the protagonist side character outputs the winning effect, it means that the above-mentioned AT continuation notification is output, and the AT continuation notification flag is turned on. On the other hand, if the enemy character wins, it is not decided that the AT will continue next time. However, even if the enemy character wins, this does not mean that the AT ends in this set. When the enemy character wins, the AT continuation notification flag is not turned on at that time.

In the case of outputting the confrontation effect, in the game that outputs the end of the confrontation effect (the effect indicating whether or not the main character wins), the output timing of the effect is controlled as follows.
First, in the game in which the effect indicating whether or not the main character wins is output, when the start switch 41 is operated, measurement of the timer is started. The timer measurement is executed by the timer of the sub-main board of the sub-control boards 80. In FIG. 1, the sub-control board 80 includes a sub-main board and an image control board (sub-sub-board) which is a subordinate board of the sub-main board and which is specialized for controlling the image display device 23. Prepare

Next, the sub-main board of the sub-control board 80 receives from the main control board 50 a command indicating that all reels 31 have stopped. The sub-main board judges whether or not the timer value has passed 10 seconds, and when it judges that the timer value has passed 10 seconds, a command for permitting image progress is issued to the sub-sub-board (whether the main character wins or not). Or, in other words, a command for permitting output of the end of the confrontation effect is transmitted. When the sub-sub board receives the command, the sub-sub board outputs an effect indicating whether or not the main character wins.
On the other hand, when a command indicating that all reels 31 have stopped is received and the timer value has not passed 10 seconds, the process stands by until the timer value passes 10 seconds. Then, when the timer value exceeds 10 seconds, the sub-main board transmits the command to the sub-sub-board.
Note that “10 seconds” is an example, and various settings such as 5 seconds and 15 seconds can be set.

FIG. 161 is a flowchart showing the control of the confrontation effect output.
First, in step S991, it is determined whether the start switch 41 has been operated. When the start switch 41 is operated, a command indicating that the start switch 41 has been operated is transmitted from the main control board 50 to the sub control board 80 (sub main board). Therefore, when the command is received, , It is determined that the start switch 41 has been operated. If it is determined that the start switch 41 has been operated, then the flow proceeds to step S992.
Here, when the sub-main board receives a command indicating that the start switch 41 has been operated, it selects an effect to be output in the game this time, and sends a command corresponding to the selected effect to the sub-sub-board. The sub-sub board controls the output of the effect based on the received command (command corresponding to the effect). Further, when the sub-main board receives a command indicating that the stop switch 42 has been operated from the main control board 50, it transmits a command indicating that the stop switch 42 has been operated to the sub-sub-board. When receiving a command indicating that the stop switch 42 has been operated, the sub-sub board switches the effect as necessary (may not be switched depending on the effect content).

In step S992, it is determined whether or not the current game is a game that outputs the end of the confrontation effect. In this process, the confrontation effect has already been output before the previous game, and it is determined whether or not the present game corresponds to a game that outputs an effect indicating the end of the confrontation effect. When it is determined that the game outputs the end of the contradictory effect, the process proceeds to step S993, and when it is determined that the game does not output the end of the contradictory effect, the process according to this flowchart ends.

In step S993, the sub main board sets a timer value. Then, the timer value is subtracted for each interrupt processing. For example, assuming that the interrupt period of the sub-main board is 1 ms, "10000 (D)" is set as the timer value and "1" is subtracted for each interrupt process. Then, the process proceeds to step S994.
In step S994, it is determined whether all reels 31 have stopped. When all reels 31 are stopped, a command (hereinafter, referred to as “all reel stop command”) indicating that all reels 31 are stopped is transmitted from the main control board 50 to the sub control board 80 (sub main board). Therefore, when the all reel stop command is received, it is determined that all reels 31 have stopped. If it is determined that the all reels stop command has been received, the process proceeds to step S995.

The determination as to whether or not all reels 31 have stopped in the main process is performed in step S289 in FIG. 139.
Here, the following patterns can be used to determine that all reels 31 have stopped.
(1) When the level data of the stop switch 42 that has been finally stopped is off.
(2) When the level data of all the stop switches 42 is off.
(3) When the level data of all the stop switches 42 is off and the level data of the other switches (the bet switch 40, the start switch 41, and the settlement switch 43) are off.
(4) In addition to any one of (1) to (3) above, the # reel driving state (_WK_RL#_STS) of all reels 31 is information (“0”) indicating stop.
Then, in the twenty-third embodiment, when the above conditions (2)+(4) are satisfied, the main control board 50 determines that all reels 31 have stopped, and sends an all-reel stop command to the sub-main board. ..

In step S995, it is determined whether the timer value has become "0". When it is determined that the timer value is not "0", the process waits until it is determined that the timer value is "0". When it is determined that the timer value has become “0”, the process proceeds to step S996. In step S996, the sub-main board transmits a command permitting the output of the end of the confrontation effect to the sub-sub-board. Upon receiving the command, the sub-sub board outputs the end of the confrontation effect. Then, the processing according to this flowchart is ended.

As described above, when the timer value is “0” when the all reel stop command is received (when 10 seconds or more has elapsed since the start switch 41 was operated), the confrontation is performed after the all reel stop command is received. The ending of the production is output. On the other hand, if the timer value is not “0” when the all reel stop command is received, wait for the timer value to become “0” even after the all reel stop command is received. The result of the showdown is output.
In addition, in the twenty-third embodiment, the end of the confrontation effect is not output until the all reel stop command is received even after the timer value becomes “0”, but the invention is not limited to this, and the timer value is “0”. ", the end of the confrontation effect may be output even before the all reel stop command is received.

As described above, the all-reel stop command is the main command when the level data of all the stop switches 42 is off and the # reel drive state (_WK_RL#_STS) of all reels 31 is information indicating stop. It is configured to be transmitted from the control board 50 to the sub-main board.
As a result, in the game in which the end of the confrontation effect is output, the player presses and holds the last stop switch 42 (meaning the stop switch 42 that was operated last) (the same applies hereinafter) and releases it. Thus (provided that 10 seconds have elapsed since the start switch 41 was operated), it is possible to output the end of the confrontation effect.
Therefore, if the player who does not want to immediately see the end of the confrontation effect keeps pressing the last stop switch 42 (without releasing his hand), the end of the confrontation effect is not output. Then, at the timing when the hand is released from the last stop switch 42, the end of the confrontation effect can be output.
On the other hand, not limited to this, the all reels stop command may be transmitted when the last stop switch 42 is turned on (when the rising data of the last stop switch 42 is turned on). By doing so, it is possible to output the end of the confrontation effect at the timing when the last stop switch 42 is turned on.

(3) Volume Setting In the twenty-third embodiment, the volume from the speaker 22 can be set. The tone settings include an administrator (store manager) mode in which an installation manager (hall manager) of the slot machine 10 performs tone settings, and a player mode in which a player playing a game in the slot machine 10 performs tone settings. ..
162, (A) shows an image display by the image display device 23 showing the administrator mode relating to the tone setting, and (B) shows an image display by the image display device 23 showing the player mode relating to the tone setting. FIG.

In the figure, in (A), the tone setting in the administrator mode is a setting change state that can be executed by turning on/off the setting key switch when the power is turned on/off, or a setting key This is one of the system menus that can be executed under at least one of the setting confirmation states that can be executed by turning on the switch.
There are three volume levels that can be selected as the administrator mode: "high", "standard", and "low" (not limited to these three levels, of course).
The administrator selects the volume using the cross key of the slot machine 10 and presses the chance button to confirm the volume.
Here, although not shown in FIG. 1, the sub-control board 80 is provided with a cross key (also referred to as “selection button”) and a chance button (also referred to as “effect button” and “enter button”) electrically. Connected to each other. The cross key is a switch operated when moving the cursor position on a menu screen or the like. The chance button is a switch that is operated when the performance is developed, and is also used as a switch that is operated when the target selected on the menu screen or the like is determined.

Further, in the administrator mode, when the volume is changed using the cross key, the test sound is output at the changed volume. The type of test sound may be, for example, a cursor movement sound, or may be a predetermined sound (pattern) that is set in advance. For example, if the currently selected volume is "normal" and you use the four-way controller to change the cursor position from "volume" to "high," test with the volume corresponding to "high." Output sound. This allows the administrator to know what the "loud" volume is. Similarly, when the cursor position is changed from “normal” to “small”, the test sound is output at the volume corresponding to “small”. By doing so, the administrator can confirm how much the set volume is.

Further, the volume of the test sound is based on the volume of a predetermined effect sound. Here, the "predetermined effect sound" is, for example, a game start sound output when the start switch 41 is operated, a stop sound output when the stop switch 42 is operated, a tempo sound of a combination of symbols, and a winning sound of a winning combination ( Or payout sound), the sound of BGM during AT, and the like.
Therefore, for example, if the volume is set to "standard" in the administrator mode and the volume is set to "volume 3" in the player mode described later, and the volume of the test sound is 80 decibels, The volume of the predetermined effect sound is also set to about 80 decibels. On the other hand, the error sound will be described later.

Further, for example, when "large" is selected in the administrator mode, even if an operation of moving the cursor position further upward by operating the cross key is performed, the cursor position remains "large". However, when "large" is selected and the cursor is moved upward by operating the cross key, the test sound is output again at the volume corresponding to "large".
Then, when the volume of any one of "high", "standard", and "low" is selected, when the chance button is operated, the volume may be fixed. It should be noted that if any of the volumes "high", "standard", and "low" is selected, moving the cursor position to the right with the cross key makes it possible to select "close". When the cursor position is “closed” and the chance button is operated, the volume may be set. In this case, the volume setting in the administrator mode is terminated, and the system menu (not shown) is returned to. Also, if you can move the cursor position to the setting of other items (for example, energy saving mode) instead of "Close", move the cursor position to "Set other items" and operate the chance button. Then, the volume may be fixed at the volume indicated by the cursor position at that time. In this case, the volume setting in the administrator mode is ended and the process proceeds to the setting of other items (not shown).

The volume selected in the administrator mode can be stored in a predetermined area of the RWM 83 of the sub control board 80. This predetermined area is configured so as not to be erased when the setting is changed or the power is cut off. With this configuration, the hall side can omit the work of resetting the volume once the volume is set once. Further, on the main control board 50 side, even when a non-recoverable error occurs and the storage area including the set value is initialized by the clear processing of the RWM 53 accompanying the setting change, the RWM 83 of the sub control board 80 The predetermined area may not be initialized. Also, when the volume is selected in the administrator mode, for example, when the cross key is set to "large" among "large", "standard", and "small", it corresponds to "large" in the predetermined area. Data may be stored, or data corresponding to "large" may be stored in the predetermined area when the volume is determined.

After the volume is set in the administrator mode as described above, the player can set the volume during the game standby. FIG. 162(B) shows the display screen (player mode) at this time.
When the cross key is operated during the game standby, for example, a menu screen is displayed (not shown in FIG. 162), and by selecting “tone setting” from the menu screen, it is possible to shift to the volume setting screen.
In the volume setting in the player mode, the volume can be set in five stages of "volume 1" to "volume 5". Moving the cursor with the cross key to select the volume and confirming the volume with the chance button is the same as in the administrator mode. In the administrator mode, a test sound corresponding to the selected volume is output every time the cursor is moved, but it is not performed in the player mode. However, the present invention is not limited to this, and in the player mode as well as in the administrator mode, a test sound corresponding to the selected volume may be output.

FIG. 162(C) is a diagram showing the relationship between the volume setting value in the administrator mode and the volume setting value in the player mode. In the figure, for example, the volume when the volume is set to "loud" in the administrator mode and the volume is set to "volume 5" in the player mode is set to "100" (reference value). Each numerical value shown in FIG. 162(C) indicates a value corresponding to the sound volume, and does not indicate a decibel (dB) itself.
In the example of FIG. 162(C), the maximum volume is “100” and the minimum volume is “20”. The volume in each mode and the range between the maximum value and the minimum value are not limited to this, and can be set variously.
As shown in FIG. 162(C), one of the characteristic points of the twenty-third embodiment is that the volume is set to "high" in the administrator mode when the player selects "volume 1". Even if it is, the point is that the volume is set to the minimum volume "20". Thus, when the lowest volume (volume 1) is selected in the volume setting in the player mode, the minimum volume is set regardless of the volume setting value in the administrator mode.

In other words,
a) When the volume is set to "high" in the administrator mode and is set to "volume 1 (minimum volume)" in the player mode (setting pattern A),
b) When the volume is set to "normal" in the administrator mode and is set to "volume 1 (minimum volume)" in the player mode (setting pattern B),
c) When the volume is set to "low" in the administrator mode and is set to "volume 1 (minimum volume)" in the player mode (setting pattern C), the volume of the predetermined effect sound that is output Are the same as "20".
However, the setting is not limited to this, and the volume for setting pattern A is set to "22", the volume for setting pattern B is set to "21", the volume for setting pattern C is set to "20", etc. You may.
In any case, the volumes of the predetermined effect sounds output in the case of the setting patterns A to C are substantially the same (“substantially the same” is a concept including “the same”). For example, when the maximum volume is "100", the minimum volume is within "±3" based on "20".

Therefore, if the player wants to play the game at the lowest volume possible, he or she can select "Volume 1" to play the game at the minimum volume without being affected by the volume difference between the halls. You can
It should be noted that the minimum volume "20" is such that, in a general hall environment (a somewhat noisy environment), a player having normal hearing hears voices such as the character's dialogue, the correct pressing sequence, and "Aim!" The volume is audible.

As shown in FIG. 162(C), one of the characteristic points of the twenty-third embodiment is the degree of change in the volume level. For example, when the volume is set to "standard" in the administrator mode and the volume is changed from "volume 1" to "volume 2" in the player mode, the volume changes from "20" to "50" (the amount of increase "30"). On the other hand, when the volume is changed from "volume 4" to "volume 5" in the player mode, the volume changes from "80" to "90" (increase amount "10"). As described above, when the volume is changed from the minimum volume "volume 1" to "volume 2", the amount of increase is larger than when the volume other than "volume 1" is changed to a volume one level higher. It is set. Therefore, by changing the minimum volume to another volume, it is possible to immediately change to a larger volume.
In the example of FIG. 162(C), when the volume is set to “low” in the administrator mode, when the volume is changed from “volume 1” to “volume 2” in the player mode, In each of the cases where the volume other than 1” is changed to a volume one level higher, the volume increase amount is set to “5”. Thus, depending on the volume setting of the administrator mode, the amount of increase is not always the largest when the "volume 1" is changed to "volume 2" in the player mode.
On the other hand, when the volume is set to "low" in the administrator mode, the volume in the player mode is, for example,
Volume 1:20
Volume 2:30
Volume 3:35
Volume 4:40
Volume 5:45
It is also possible to make the setting so that the amount of increase becomes the largest when the "volume 1" is changed to the "volume 2".

In the twenty-third embodiment, if the volume is not set in the player mode after setting the volume in the administrator mode, the volume in the player mode is set to “volume 5” as a default.
Further, when the time during which no game is played (game standby state) continues for 10 minutes, the volume setting up to that time in the player mode is cleared, and the default "volume 5" is restored. This is because the volume is returned to the default when the players are replaced. Therefore, the default of the player mode may be "volume 3" or the like.
When the power of the slot machine 10 is turned on/off, the volume in the player mode is set to “volume 5” which is the default.
On the other hand, the volume in the administrator mode is maintained at the previous value unless reset. For example, when the volume is set to "low" in the administrator mode, the volume is "low" even after the power is turned on/off, the setting is changed, and the setting is confirmed.

FIG. 163 is a flowchart showing control of volume setting in the administrator mode.
First, in step S1001, the current volume is read. For example, "small" is "0", "standard" is "1", and "large" is "2" stored in a predetermined area of the RWM 83, and this volume setting data is read. Next, in step S1002, the current volume is displayed as an image. For example, when the volume data stored in the RWM 83 is "1", it is displayed as an image that the current setting value is "standard" as in the example of FIG. 162(A).
Next, in step S1003, it is determined whether the cross key has been operated. When it is determined that it has been operated, the process proceeds to step S1004, and when it is determined that it has not been operated, the process proceeds to step S1007.

In step S1004, it is determined whether the volume setting can be changed. For example, when the setting of the current volume is "standard" and it is further selected by the cross key, it is determined that the volume setting can be changed. On the other hand, when the setting of the current volume is "high" and it is further selected by the cross key, it is determined that the volume setting cannot be changed. If it is determined that the volume setting can be changed, the process proceeds to step S1005, and if it is determined that the volume setting cannot be changed, the process proceeds to step S1006.
In step S1005, the volume setting value is updated. As described above, when the setting of the current volume is "standard" and the upper level is selected by the cross key, the volume setting is updated to "high". Then, the process proceeds to step S1006.

In step S1006, the test sound is output at the volume currently set. As described above, for example, when the volume is changed from “standard” to “loud”, the test sound is output at the volume corresponding to the changed “loud”. On the other hand, for example, when the current volume is set to “high” and the higher volume is selected with the cross key (“No” in step S1004), the current volume is “high”. Output a test sound at the volume corresponding to.
Next, in step S1007, it is determined whether the chance button has been operated. If it is determined that the chance button has been operated, the processing according to this flowchart (volume setting in the administrator mode) is terminated. On the other hand, if it is determined that the chance button has not been operated, then the flow returns to step S1003.

The above volume setting is for a predetermined effect sound. On the other hand, the volume of the error (recoverable error and non-recoverable error) sound is fixed and is not changed by the volume setting in the manager mode or the player mode. This is because, for example, a person performing a goto action may set the volume to the minimum volume in the player mode described above before performing the goto action.
For example, the error sound is uniformly set to a volume corresponding to "100" when it is set to "loud" in the administrator mode and set to "volume 5" in the player mode ( For example, the error sound is uniformly set to "90" decibels, etc.).
However, not limited to this, the volume of the error sound cannot be changed in the player mode, but the volume of the error sound may be set in the administrator mode. However, even if the error sound is set to the lowest volume in the administrator mode, the error sound is set to a volume that sufficiently reaches the surroundings.
Further, when the volume (“high”, “standard”, “low”) is set in the administrator mode shown in FIG. 162(A), the volume of the error sound also changes (“high”, “standard”, “low”). The volume may be changed according to the above). Alternatively, in the administrator mode, a dedicated menu screen for setting the volume of the error sound may be provided.

(4) Effect when the symbol combination of 1BB is tempeed When the 1BB is tempted, the sub-control board 80 outputs a flash (light emission from the effect lamp 21) and a tempai sound (sound from the speaker 22). The flash and tempai sounds are executed regardless of whether or not the transition condition to the main game state 4 (AT, 1BB operation) is satisfied. As a result, the player can know the fact that the 1BB is tempted even if the 1BB happens to be tempted when the game casually proceeds.

Further, as described above, in the case where 1BB is a tempai, when the transition condition to the main gaming state 4 is satisfied, the standby operation in which the stop operation of the third reel 31 is not accepted even if the third stop switch 42 is operated Although the time is not set, when the transition condition to the main game state 4 is not satisfied, the standby time is set (steps S809 to S810 in FIG. 147). As a result, it is possible to prevent 1BB from winning due to an unexpected stop operation by the player.

In addition, if the conditions for transition to AT are satisfied, aim for "blue BAR" as described above! Is displayed as an image, and the voice "Aim" is also output.
Here, since there are many cases where the transition condition to the main gaming state 4 is not satisfied during the game, when the above-mentioned flash and tempai sound are output every time 1BB is tempted, the player: It is possible to recognize that the flash and tempai sound are effects for avoiding the winning of 1BB.
However, if the conditions for transitioning to the main gaming state 4 are satisfied, aim for ""blue BAR"! Since the image display of "" and the sound of "aiming" are output, even if the flash and tempai sounds are output at the same time, the player can recognize that 1BB may be won in the game this time. it can.

In addition, in the case where 1BB is tempai, if the transition condition to the main gaming state 4 is not satisfied, a flash and tempai sound is output, and if the transition condition to the main gaming state 4 is satisfied, these flash and tempai It is possible that no sound is output. However, since the effect for not stopping the symbol combination is not allowed by the rule, in the twenty-third embodiment, when 1BB is tempted, whether or not the transition condition to the main game state 4 is satisfied. Instead, the flash and tempai sounds are output uniformly.

(5) During the 1BB game (when the AT start condition is satisfied/not satisfied), the sub-control board 80 stops displaying the 1BB symbol combination when the transition condition to the main game state 4 is satisfied. When, AT (1BB game) is started from the next game.
In the case of shifting to the main game state 4 (AT, 1BB game), before winning the SRB, when the small winning combination A group (winning numbers “10” to “15”) is won, the correct pressing order is notified. As the notification method, for example, the correct pressing order is displayed as an image, and which stop switch 42 is operated next is output by voice.
On the other hand, in the case of shifting to the main game state 4 (AT, 1BB game), before winning the SRB, even if the small winning group B (winning numbers “16” to “21”) is won, the correct answer is pressed. Do not inform the order. This is because, in a game in which the SRB has not been won, there is no correct pressing order (pressing order for winning the high-rank bell) even if the small winning group B is won (see FIG. 125).

Then, in the case of shifting to the main game state 4 (AT, 1BB game), when the SRB is won and the inside of the SRB is reached, both the small win group A wins and the small win group B wins , Informs the correct push order. When you win the SRB for the first time, the winning of the SRB will be carried over after the next game. After the next game of the game won by SRB, the correct answer pushing order is notified at the time of winning the small winning group B.

On the other hand, even when the condition for shifting to the main game state 4 (AT, 1BB game) is not satisfied, when the 1BB symbol combination is stopped and displayed, the 1BB game is started. However, even if 1BB wins, the main gaming state does not shift, so when 1BB wins in RT1 and main gaming state 1, for example, 1BB operation and main gaming state 1 are entered.

When shifting to the 1BB game without shifting to the main gaming state 4, the main control board 50 does not operate the instruction function, and the sub control board 80 does not execute AT. Therefore, even when a small winning combination having the correct answer pushing order (small winning group A when the SRB is not inside, small winning groups A and B while inside the SRB) is won, the winning number display LED 78 is pressed. The instruction number is not displayed, and the correct output order is not notified by the effect output device such as the image display device 23.
Further, when the game shifts to the 1BB game without shifting to the main game state 4, the sub control board 80 maintains the normal effect contents during the non-AT (effect contents up to that point). Therefore, from the player's side, it is as if the normal game (non-AT, non-special game) is continuing even during the 1BB game.

(6) Display of the number of games played at RT1 (non-AT) As described above, the number of games played at RT1 is counted, and when the number of games played at RT1 reaches "1400", it is determined that the RT1 end condition is satisfied. Move to non-RT.
RT1 starts at the end of 1BB operation (end of AT). Therefore, the number of RT1 games is substantially the number of non-AT games.
Then, in the twenty-third embodiment, the number of non-AT games is displayed by the image display device 23. This allows the player to easily know how many games have passed since the non-AT. In addition, it is possible to easily know how many games are left until the "1400" game (game until shifting to non-RT) which is a so-called ceiling is reached.

Although there is a case where the advantageous section is ended during the RT1 to shift to the non-advantageous section, the number of games of RT1 (“_CT_RT_GAME” of the address “F00A(H)”) is not cleared at the end of the advantageous section. Therefore, even when the advantageous section shifts to the non-advantageous section during RT1, the number of games of RT1 is maintained and is continuously counted even after the shift to the non-advantageous section. The same applies when shifting from this non-advantageous section to the advantageous section.

Further, in the twenty-third embodiment, the number of non-AT games displayed on the image display device 23 as the non-AT game number is not the data of the RT game number “_CT_RT_GAME” of the address “F00A(H)”, and the RWM83 of the sub control board 80 is not used. I remember. At the end of the 1BB operation, an initial value “0” is set as the number of non-AT games (increment counter) in the RWM 83, the number of games is updated as the game is exhausted, and the number of non-AT games is stored in the image display device 23. To do.
However, when the power is turned on/off, the sub-control board 80 initializes a predetermined area of the RWM 83 when returning from the power failure regardless of whether or not the setting change process is executed. The data of the number of AT games played is also initialized (cleared). Therefore, the number of non-AT games displayed on the image display device 23 becomes “0” when the power is restored.
In addition, in the menu screen that can display the specifications of the gaming machine, the game history, and the like, the number of non-AT games can be displayed as one of the game histories, and the number of games is the number of games displayed as an image on the image display device 23. (Displayed based on the data of the number of non-AT games stored in the RWM 83). Therefore, when the power is turned on/off, the number of non-AT games displayed on the menu screen is also "0".

Therefore, for example, when the RT1 game count “_CT_RT_GAME” on the RWM 53 (main control board 50 side) is “100” and the non-AT game count displayed on the image display device 23 is “100”, the power is turned on. When turned off/off, the number of games played by RT1 "_CT_RT_GAME" remains "100", but becomes "0" displayed on the image display device 23. Next, when the first game 1 is executed, the number of games “_CT_RT_GAME” of RT1 is updated to “101”, and the number of games displayed on the image display device 23 is updated to “1”. Thus, when the power is turned on/off, the number of RT1 games “_CT_RT_GAME” in the RWM 53 and the number of non-AT games displayed on the image display device 23 (the number of games stored in the RWM 83) are displayed. It will be different. With such a configuration, it is possible not to know how many games have been played up to the ceiling in the morning (when the hall is opened).

In addition, in the twenty-third embodiment, even when the setting change process is executed, the RT state number “_NB_RT_STS” and the number of games RT_1 “_CT_RT_GAME” are not cleared. However, not limited to this, when the setting change process is executed, the number of games “_CT_RT_GAME” of RT1 may be cleared. If the number of games “_CT_RT_GAME” of RT1 is cleared when the setting change process is executed, the data of the number of games “_CT_RT_GAME” of RT1 after the setting change process and the number of non-AT games displayed on the image display device 23 are displayed. Will match. With this configuration, the number of games played in the morning (when the hall is opened) can be grasped from the number of games played until the ceiling is reached. Therefore, in the morning, whether the player plays the game on the table or not. It is possible to be motivated (use it as a criterion).

Although the twenty-third embodiment has been described above, the twenty-third embodiment is not limited to the above description, and various modifications such as the following are possible.
(1) When winning the small winning combination A group, the winning combination has a correct pressing order during 1BB operation, and the small winning combination group B has a correct pressing order within 1BB operation and inside the SRB. However, the present invention is not limited to this, and the small winning combination B group may have a correct answer pushing order during the 1BB operation (whether inside the SRB or not) like the small winning combination A group.
On the contrary, as for the small winning combination A group, like the small winning combination B group, a winning combination having a correct answer order may be provided only during 1BB operation and inside the SRB.

(2) The payout rate at 1BB non-operation, non-AT and 1BB operation, and AT and 1BB operation is an example and is not limited to the above embodiment. However, in order to prevent a transition to 1BB operation (1BB game) even though the player has not won an AT, the payout rate in non-AT and 1BB operation is preferably less than "1". ..
On the other hand, when the 1BB operation is started, even if the AT is not AT, the payout rate is set higher than that when the 1BB is not operated, so that the "1BB operation makes the player advantageous state". Will be satisfied.

(3) In the above embodiment, the AT lottery is not executed during the non-AT and 1BB operation or the AT and 1BB operation, but the present invention is not limited to this, and the AT lottery is performed even when the non-AT and 1BB operation is in progress. You may execute. However, in order to prevent the 1BB operation from being easily performed during non-AT, it is preferable to set the AT winning probability during non-AT and 1BB operation to be lower than the AT winning probability during 1BB non-operation.
Furthermore, during AT and 1BB operation, it is possible to execute the lottery with the number of AT sets added.

(4) Even if the inside of the SRB is reached during AT and 1BB operation, the twenty-third embodiment is premised on digesting the game without winning the SRB. This is because, if the SRB is won and the game shifts to the RB game, the payout rate is reduced.
Here, when the SRB is tempted during AT, 1BB operation and inside the SRB, the waiting time may be set using the process shown in FIG. 147 in order to avoid winning the SRB.
On the other hand, when the game is transferred to the 1BB game without having the right to execute the AT, when the SRB is won, a process for avoiding the winning of the SRB even if the SRB is tempted (setting of waiting time ) Does not need to be executed.
Further, when the SRB is tempted inside the AT and the 1BB operation and inside the SRB, the attention process to the player by the output of the flash or the sound may be executed similarly to the case where the 1BB is tempted.

(5) In the above embodiment, the standby time when 1BB is tempted when the transition condition to the AT is not satisfied is set to "896 (D)" (about 1000 ms). The reason is that the time required for the reel 31 to make one rotation at a constant speed is “1.117×2×336=about 750 ms”, so that the standby time is set to be longer than the one rotation time of the reel 31. .. With this setting, when the "blue BAR" symbol on the third reel 31 first reaches the activated line after the second stop switch 42 is operated, the waiting time has not yet elapsed, so that Even if the third stop switch 42 is operated at the timing, the winning of 1BB can be avoided.
However, not limited to this, the waiting time can be set arbitrarily. For example, it may be set to about 3 seconds in order to secure a sufficient time for avoiding the winning of 1BB.

(6) In the example of the stop symbol set (M_STOPPIC_SET) in FIG. 147, the standby time is stored in step S810 on condition that it is determined in step S801 that the second stop switch 42 has been stopped. In this case, the determination in step S802 is “Yes” when the second stop switch 42 is operated at the timing when 1BB is tempered, and when the second reel 31 is actually stopped and 1BB is actually tempered. There are two methods of determining “Yes” when doing, but either method may be used.
For example, in step S802, when it is determined to be “Yes” before the second reel 31 actually stops, at the time of step S810, the case where the second reel 31 is not yet stopped, The case where it has already stopped is mentioned.

(7) It is possible to use the specifications inside the 1BB by setting the waiting time at the time of 1BB temp and not stopping the third reel 31 within the waiting time.
Here, the "1BB internal mid-spec" means that the game is executed while the winning of 1BB is carried over, and both the non-AT and the AT are executed while being in the 1BB. In the case of the internal specifications of 1BB, it is premised that the game proceeds without winning 1BB. In such a case, the standby time is set as shown in step S810 of FIG. 147, and the standby symbol set (M_STOPPIC_SET) is not moved unless the standby time has elapsed as shown in step S791 of FIG. 146. For example, it is possible to effectively suppress the shift from the inside of the 1BB to the 1BB operating state.

(8) The standby effect is performed by rotating the reel 31 in the reverse direction. However, the present invention is not limited to this, and the rotation direction of the reel 31 in the standby effect may be forward rotation. When the standby effect is executed in the normal rotation (when the reel 31 is not rotated in the reverse direction), the storage area for the search counter update correction data at the address “F09F(H)” in FIG. 138, in FIG. The process of step S823 (storage of search counter update correction data) and the process of step S933 (correction of the number of deceleration start steps) in FIG. 159 are unnecessary.
However, if the standby effect is performed in the reverse rotation, the player can easily recognize the standby effect. Further, even if the standby effect is performed in the normal rotation, the player can easily recognize that it is the standby effect if it is executed at a rotation speed different from the rotation speed of the normal game.
In the standby effect, the reel effect data table shown in FIG. 144 is used to preset which symbol number to stop for each reel 31, so that the stop position of the reel 31 before the standby effect does not matter. is there. In other words, even if the stop result before the execution of the standby effect (previous game) is uneven, a predetermined symbol combination (for example, "black BAR" set) is stopped and displayed by the standby effect. That is, it is not necessary to stop the preparation eye in the previous game of the game that executes the standby effect.

The slip-in prevention output in (9) is not limited to the example described above, and may be executed even when the AT continuation notification is output, for example. Alternatively, the slip-in prevention output may be executed even when the AT end effect is not output.

(10) In the confrontation effect output control shown in FIG. 161, in this example, the timer value is set based on the operation of the start switch 41 (steps S991 and S993). However, the present invention is not limited to this, and the timer value may be set (the timer may be counted) based on the operation of another operation switch, for example, the bet switch 40 or the first or second stop switch 42.
Also, instead of setting the timer value (starting the timer count) when one of the operation switches is operated, the timer count may be started at a predetermined timing after the operation switch is operated. Good.

For example, first, when the operation switch is the bet switch 40, the timer may start counting 1 second after the bet switch 40 is operated.
Secondly, when the operation switch is the start switch 41, after the start switch 41 is operated, the timer may start counting at the timing when the output of the game effect this time is started.
Furthermore, thirdly, when the operation switch is the first or second stop switch 42, when the reel 31 corresponding to the first or second stop switch 42 is stopped, or when the first or second stop switch 42 is operated. The timer may start counting at the timing when the effect based on is started.

(11) Further, in the twenty-third embodiment, when the timer value is “0”, the third stop switch 42 is turned off (when the hand is released). When it was done). However, the present invention is not limited to this, and when the other (operated) stop switch 42 is operated before the third stop switch 42 is switched from on to off, even if the third stop switch 42 is switched from on to off. The end of the confrontation effect may not be output. For example, while the player himself continues to press the third stop switch 42 so as not to output the end of the confrontation effect, the adjacent player (friend) operates the other stop switch 42 by mischief. It is possible to provide a new game in which the production ending is not output.

(12) Furthermore, in the game that outputs the end of the showdown effect, the payout process is executed based on that the third stop switch 42 is switched from ON to OFF, and when a hopper error (no medals) occurs, The output of the production end is interrupted, and the continuation of the production end is output after the hopper error is released, or the production end is output again from the beginning after the hopper error is released.
Further, when the third stop switch 42 is turned off from on immediately before the timer value becomes “0” and the payout process is executed, the timer is counted even while the payout process is being executed. Therefore, when the timer value becomes "0" during the payout process, the production end is output based on the timer value becoming "0" (regardless of whether the payout process is completed). To be done.

(13) Furthermore, in the game that outputs the end of the confrontation effect, the output of the effect end is started based on that the third stop switch 42 is switched from ON to OFF, but the present invention is not limited to this, and the third stop switch 42 Is turned on, or when the third stop switch 42 is turned from on to off, for example, an icon of a push button (sub button) is displayed as an image (at this point, the production ending is not output), and the push button The effect ending may be output when is operated.

(14) In the example of FIG. 132, in the main game state 5 (AT pullback), when the AT pullback counter is "0" and the advantageous zone clear counter is less than "600", the main game state 0 is entered. I chose However, not limited to this, in the main game state 5, when the AT pullback counter becomes "0", the advantageous period clear counter is cleared regardless of the value of the advantageous period clear counter, and the state shifts to the main game state 0. You may. Further, in the main game state 1, if the probability is high, the main game state 1 may not be terminated (not shifted to the main game state 0) even if the advantageous section clear counter becomes less than "600".
(15) In the twenty-third embodiment, since the number of reels 31 is three, in step S801 of FIG. 147, it is determined whether or not after the second stop. However, the present invention is not limited to this, and when the reels 31 are composed of four reels 31 as shown in FIG. 59 (thirteenth embodiment), in step S801 of FIG. 147, it is determined whether or not after the third stop. It will be.

(16) In the twenty-third embodiment, the volume setting in the administrator mode has three levels, but the volume setting is not limited to this and may have any number of levels (e.g., five levels, ten levels, etc.). Further, although the volume setting in the player mode is set to 5 steps, the present invention is not limited to this, and any number of steps (for example, 3 steps, 10 steps, etc.) may be set.
(17) The numerical values (setting values, timer values, etc.) mentioned in the twenty-third embodiment are all examples, and the values are not limited to these values.
(18) The twenty-third embodiment can be implemented alone or in combination with other first to twenty-second embodiments.

<Twenty-fourth Embodiment>
FIG. 164 is a diagram showing a hardware configuration of the main CPU 55 in the slot machine 10 of FIG.
165 is a diagram showing the structures of the ROM 54 and the RWM 53 in FIG. 164 in more detail.
In the twenty-fourth embodiment, when the address of the built-in memory or the data stored in the storage area of the RWM 53 is represented by a hexadecimal number, "(H)" (an acronym for "hexadecimal") indicating the hexadecimal number is attached. ..

In FIG. 164, the main CPU 55 is composed of a one-chip microprocessor (MPU) (hereinafter, also simply referred to as “chip” as necessary), and has an ALU (arithmetic unit) 55d and a built-in memory therein. (But not limited to). Note that the term “internal memory” refers to a user memory unless otherwise specified.
The main CPU 55 executes a program necessary for the progress of the game, performs calculations, and the like. Specifically, the control processing of the inserted medals, the lottery processing of the winning combination, the drive control processing of the reel 31, the payout processing at the time of winning, etc. are executed.

The ALU 55d is an arithmetic unit of the main CPU 55 that executes logical operations, four arithmetic operations, and the like. Further, as shown in FIG. 164, an internal bus (including an address bus, a data bus, and a control bus) 55a in the main CPU 55 is connected to an ALU 55d, and the internal bus 55a and a predetermined storage area in the internal memory are connected. linked. Here, "connecting" refers to forming a path through which information can be communicated (hereinafter the same). The entire storage area of the built-in memory may be connected to the internal bus 55a, or a part of the storage area of the built-in memory (for example, excluding the storage area having confidentiality) and the internal bus 55a are connected. May be.

When a predetermined storage area in the built-in memory is connected to the internal bus 55a and the ALU 55d, the information stored in the predetermined storage area is output (transmitted) to the outside by a program executed by the main CPU 55. It is possible.
The "program executed by the main CPU 55" is stored in a built-in memory (for example, the ROM 54) in the main CPU 55 or outside the main CPU 55 (slot machine 10). This includes both cases where the program is configured to be executed.

Although not shown in FIG. 164, the memory area of the main CPU 55 is divided into a boot area and a user area. The boot area is a storage area used by a chip manufacturer and may include a boot ROM, a boot RWM, and the like.
For example, the boot ROM may store a program for checking security, a program for diagnosing a failure, a program for executing authentication and verification, and the like. The boot RWM may be used as a work area (data area, stack area, etc.) of the boot program.

The user area is a storage area used by the manufacturer of the slot machine 10 (however, not all of the user area is used by the manufacturer of the slot machine 10), and the (built-in) ROM 54, (built-in) RWM 53. , A built-in register area 56, a decode area 57, and the like. Note that the ROM, RWM, and other storage means may be provided outside the one-chip microprocessor (on the main control board 50), instead of being provided inside the one-chip microprocessor.

As shown in FIG. 164, the user area of the built-in memory is composed of storage areas of addresses “0000(H)” to “FFFF(H)”. Here, the "1" address of the user area has a storage capacity of "1" bytes. Therefore, the entire user area is "65536" bytes.
The addresses of the ROM 54 and the unused area following the user area, the RWM 53 and the unused area subsequent thereto, the internal register area 56 and the unused area subsequent thereto, the decode area 57 and the unused area subsequent thereto are stored in the user area. It is continuous with.
In the user area, the storage capacities of the ROM 54 and the RWM 53 shown in FIGS. 164 and 165 and the storage capacities of the respective areas are examples, and the present invention is not limited to this.

The ROM 54 is a storage area for storing a program (user program) created by the user, that is, the manufacturer of the slot machine 10.
The storage capacity of the ROM 54 is set to about “12 Kbytes” in the present embodiment, and has a continuous storage area of addresses “0000 (H)” to “2FFF (H)”.
As shown in FIG. 165, the storage area of the ROM 54 has a use area and an outside use area. Further, both the used area and the outside of the used area have a control area and a data area. The control area of the usage area may be referred to as a first control area, and the control area outside the usage area may be referred to as a second control area.

The "use area" refers to a storage area in which information other than information necessary for preventing unauthorized modification or other changes is stored or will be stored (same in the ROM 54 and the RWM 53).
The “control area” refers to a storage area other than the data area in the usage area, and is an area in which various programs executed by the main control board 50 are stored. The control area may be referred to as a "program area". Specifically, programs relating to game progress and effects (programs for executing main processing (for example, FIG. 41) and interrupt processing (for example, FIG. 53)) are stored. Therefore, the instructions of the programs shown in FIGS. 168 to 171 described later are stored in the control area in the usage area of the ROM 54.
Furthermore, the “data area” refers to a storage area in the usage area in which only information other than the program is stored or will be stored, and is an area in which data used during execution of the program is stored. is there.

Further, in the control area (second control area) outside the usage area, a program not related to the progress of the game, for example, a program for controlling the lighting of the management information display LED 74 (role ratio monitor), a program used during the test, and A program for preventing fraud is stored.
The program management area of the ROM 54 is an area for storing information and the like required for the main CPU 55 to execute the user program. A header, a manufacturer code, a product code, a program code end address, etc. are stored in the program management area.

The RWM 53 is used as a work area for a user program. The RWM 53 has a backup function and can retain the information stored in the RWM 53 even after the power of the chip (slot machine 10) is cut off.
As shown in FIG. 165, the storage area of the RWM 53 has a used area and an outside of the used area, like the ROM 54. Further, each of the used area and the outside of the used area has a work area and a stack area.
The work area in the usage area of the RWM 53 is, for example, a storage area for storing data necessary for a game as shown in FIG. 35 (11th embodiment) or FIGS. 133 to 138 (23rd embodiment). (In addition, in FIG. 35, a part of the storage area of the data regarding the advantageous section overlaps with FIG. 138.).

In addition, the stack area of the use area of the RWM 53 is used when the value of the register is saved and then returned to the register again, or when the predetermined instruction is executed and after the execution of the instruction. This is an area used when storing a caller's address to be returned (also referred to as return address or return address).
Furthermore, in the work area outside the use area of the RWM 53, data for displaying a ratio on the management information display LED 74 (role ratio monitor), specifically, a ring buffer, a game number counter, a payout number counter, and ratio data. Etc. have storage areas.
The storage capacity of the RWM 53 is set to about “1 Kbyte” in the twenty-fourth embodiment and has a storage area of addresses “F000(H)” to “F3FF(H)”.

Here, as shown in FIG. 165, in the use area of the RWM 53, the work area has a range of addresses “F00(H)” to “F1CF(H)”, but FIG. 35 (the eleventh embodiment) and FIG. As shown in 133 to 138 (the twenty-third embodiment), most of the storage area for storing the data necessary for the progress of the game is the storage area of which the upper address is “F0(H)”.
On the other hand, the storage area of the data for displaying the ratio on the management information display LED 74 (role ratio monitor) is the storage area of which the upper address is “F2(H)”.

In FIG. 164, a built-in register area 56 which is continuous from the RWM 53 with an unused area is provided with storage areas of addresses “FE00(H)” to “FEBF(H)” in the present embodiment, and in the twenty-fourth embodiment. It has a storage capacity of "192 bytes".
Further, the decode area 57, which is continuous from the internal register area 56 with an unused area, is a storage area composed of "46 bytes" of addresses "FED0(H)" to "FEFD(H)".

Further, as shown in FIG. 164, the main CPU 55 is provided with a general-purpose register area (storage area). The general-purpose register area may be provided outside the built-in memory or inside the built-in memory, for example, inside the built-in register area 56.
The registers provided in the general-purpose register area are composed of A register, B register, C register, D register, E register, F register, H register, L register, and Q register (1 byte each). Register type is not limited to this). Another general-purpose register is SP (stack pointer), but the description thereof is omitted in the twenty-fourth embodiment.

The ROM 54, RWM 53, built-in register area 56, decode area 57, and general-purpose register described above are connected to the internal bus 55a and can be accessed by a program (main program) executed by the main CPU 55. Therefore, the information stored in the ROM 54 can be read by the main program. Further, the main program can read the information stored in the RWM 53 and write the information in the RWM 53. Furthermore, the information in the internal register area 56 can be read by the main program (however, it is limited to a part of the area). Furthermore, the main program can read information from the decode area 57 and write information to the decode area 57. Similarly, the main program can read information from the register and write information to the register.

Further, even when data is stored in the register when the power switch 11 is turned off, these register values are initialized to “0” when the power switch 11 is turned on.
In the twenty-fourth embodiment, when the power switch 11 of the slot machine 10 is turned on, the Q register value at power-on is “0 (H)”, but immediately after power-on until the user program is activated. The initial value “F0(H)” is stored in the Q register at a predetermined timing during the period.

Furthermore, after the power is turned off, when the power switch 11 is turned on, the unused area of the user area is initialized. Here, it is conceivable that data may be stored due to noise or the like even in an unused area. If a value is stored in the unused area, it may lead to fraud. For these reasons, the unused area is initialized when the power is turned on (normally once a day).

FIG. 166 is a diagram for explaining the register in detail. In the figure, (A) shows A to F, H, L, and Q registers.
In the main CPU 55 of the present embodiment, A, B, C, D, E, H, and L registers (7 registers) can be used as registers for temporarily storing data during calculation. Further, the F register is a flag register having a carry flag and a zero flag. Furthermore, as described above, the Q register is a register that stores the high-order address “F0(H)” of the work area in the usage area of the RWM 53 and is used at the time of an instruction.
Here, the A register and the F register, the B register and the C register, the D register and the E register, and the H register and the L register are respectively referred to as a pair register. The F register is a register for storing the value of a specific flag, and a 2-byte value is not stored in the AF register together with the A register.

The A register is used when storing a 1-byte value. For example, the A register is used in the process shown in step S772 of FIG. 141 (23rd embodiment).
On the other hand, the BC register, DE register, and HL register may store 2-byte data as a pair register. Here, when 2-byte data is stored in the BC register, the B register is in the higher order and the C register is in the lower order. Similarly, when 2-byte data is stored in the DE register, the D register becomes the high order and the E register becomes the low order. Further, similarly, when 2-byte data is stored in the HL register, the H register is in the high order and the L register is in the low order.

For example, as an example of storing 2 bytes of data in the BC register, in step S831 of FIG. 143 (the twenty-third embodiment), when performing the 2-byte waiting process of the production end waiting time, the production end waiting time (2 bytes An example of storing (data) in the BC register is given.
Even when storing 1-byte data, a pair register may be used. For example, in step S395 of FIG. 49 (the eleventh embodiment), in order to store the interrupt processing count "46", "00000000 (B)" is stored in the B register and "00101110 (B)" (46 (D (Corresponding to)) is an example of storing. Data is stored in the pair register consisting of 2 bytes even if it is 1-byte data, because the 2-byte wait processing program is diverted.

On the other hand, the BC register is not always used as a pair register but may be used alone. For example, as shown in step S497 of FIG. 55 (the eleventh embodiment), an example in which the error number display data is stored in the B register and the bet display data is stored in the C register can be given.
The same applies to the DE register and the HL register.

The F register is called a flag register. FIG. 166(B) is a diagram showing a structure of the F register.
In this embodiment, as shown in FIG. 166(B), the “D0” bit (least significant bit) of the F register is set in the carry flag (C). Here, the "carry flag (C)" is a flag that becomes "1" when a carry-down or a carry (also referred to as a carry-over) occurs due to the calculation.
In the present embodiment, the carry flag may be abbreviated as “C”. In the present embodiment, “C” means a carry flag and does not mean the C register. When referring to the C register, it is called "C register". However, the BC register may be referred to as “BC” in an instruction described later.
Further, in the instruction described later, “C” means “when the carry flag is “1” (when carry occurs)”. On the other hand, “NC” means “when the carry flag is not “1” (when no carry occurs).

For example, in step S434 of FIG. 51 (the eleventh embodiment), the carry flag changes according to the comparison operation between the HL register value (difference number counter value) and "2401(D)". In step S434 of FIG. 51, in the comparison operation of the HL register value and "2401(D)", a process of subtracting "2401(D)" from the HL register value is executed. Therefore, the carry flag is "1" when the HL register value is "2400 (D)" or less, and the carry flag is "0" when the HL register value is "2401 (D)" or more.
For example, when the HL register value is "2400(D)",
"2400 (D)"-"2401 (D)" = "-1 (D)", carry flag = "1"
Becomes
When the HL register value is "2402(D)",
"2402 (D)"-"2401 (D)" = "1 (D)", carry flag = "0"
Becomes

Therefore, since the operation result is "1", no carry occurs and the carry flag is "0" (the D0 bit of the F register is "0").
On the other hand, when the HL register value is “2402(D)”,
“2401(D)”−“2402(D)”=“−1(D)” (actually, “FFFF(H)”
The carry flag becomes "1" and the D0 bit of the F register becomes "1".

The carry flag may be "1" even if the carry result does not carry or carry.
For example, in the process of step S422 in FIG. 51 (the eleventh embodiment), even if “1” is subtracted from “0000(H)”, no carry is generated, and a special operation for maintaining “0000(H)” as it is. To execute. However, in the process of step S422, the carry flag becomes "1" when "1" is subtracted from "0000 (H)".
When the carry flag once becomes "1", another operation is executed next and is maintained until the carry flag becomes "0" (the process of clearing the carry flag is not executed).

Further, as shown in FIG. 166(B), the “D7” bit (most significant bit) of the F register is set to the zero flag (Z). Here, the “zero flag (Z)” is a flag that becomes “1” when the calculation result becomes “0”.
Further, in an instruction described later, “Z” means a condition “when the zero flag becomes “1” (when the operation result is “0”)”. On the other hand, “NZ” means the condition “when the zero flag is not “1” (when the operation result is not “0”)”.
For example, in the process of step S422 of FIG. 51 (the eleventh embodiment), when the value before calculation is “0001 (H)” and “1” is subtracted to become “0000 (H)”, the zero flag is set. It becomes "1".

Similar to the carry flag, when the zero flag once becomes "1", another operation is executed next and is maintained until the zero flag becomes "0" (the process of clearing the zero flag is not executed).
In this embodiment, the F register uses only the D0 bit (carry flag) and the D7 bit (zero flag), and the D1 to D6 bits are unused. However, not limited to this, it is also possible to use other bits of the F register for other flags.

As described above, the Q register is a register that stores “F0(H)” (upper address of the working area of the used area in the RWM 53), and in the 24th embodiment, among the storage areas of the RWM 53. , Used in an instruction when reading data whose upper address is “F0(H)”. In particular, in the twenty-fourth embodiment, most of the high-order addresses of the work area in the use area of the RWM 53 are set to “F0(H)”. For example, the first “F000(H)” is set in the set value data (_NB_RANK) as shown in FIG. 35 (the eleventh embodiment).

In the example shown in FIG. 35 and FIGS. 133 to 138 (23rd embodiment), the upper address of the storage area in which each data is stored is “F0##(H)” (“#” is “ Any value from 0" to "F"). When “F0(H)” is once stored in the Q register and the upper address “F0(H)” in the storage area of the RWM 53 is designated by an instruction, the Q register is designated.
In the use area of the RWM 53, when the main upper address of the work area is not “F0(H)”, for example, “E1(H)”, the Q register has “E1(H1)” accordingly. (H)” is stored.

Further, when "F0(H)" is stored in the Q register, for example, in the use area of the RWM 53, predetermined data relating to the progress of the game is stored in a storage area other than the upper address "F0(H)". If there is a need to access the data, the following methods are available.
For example, firstly, the address where the data to be read is stored is stored in, for example, the HL register, and in the instruction of the program, the value of the HL register can be specified (the content stored in the HL register can be read). Can be mentioned.

Secondly, when the data of the storage area other than the upper address “F0(H)” is accessed, the Q register value is temporarily changed from “F0(H)” to another value (the data to be accessed is stored). It is possible to access the data in the storage area of the upper address by changing the address to the upper address) and then specifying the Q register with an instruction. Then, after completion of this instruction, for example, the Q register value is returned to "F0(H)".

FIG. 167 is a diagram for explaining an instruction “LDQ A, (20(H))”.
This command is equivalent to a command for saving (storing) the contents (also called “contents” and “data”; the same applies hereinafter) stored (stored) at the address “F020(H)” to the A address. To do.
Here, the entire description "LDQ A, (20(H))" is referred to as "instruction".
When the instruction is actually stored in the ROM 54, it is encoded and stored (binary data of “0” or “1”). The binarized data in the form in which the instructions are stored in the ROM 54 is called "instruction code".

Further, the command includes command information and identification information. In this example, “LDQ A,” corresponds to command information, and “(20(H))” corresponds to identification information.
In the instruction "LDQ A, (20(H))", "LD" means transfer, "Q" refers to the upper address, and "(20(H))" refers to the lower address to be accessed. .. The operand of the instruction (variable to be operated) is specified in the parentheses of the identification information, and becomes the lower address accessed by the operand. Further, “A” indicates a save destination register (register A in this example).
Therefore, the data stored in the A register has the contents of the address “F020(H)”.

In the above case, it is assumed that the data “n” is stored in the address “F020(H)” as shown in FIG. 167(B). In this case, "n" is stored in the A register by the instruction "LDQ A, (20(H))". If some data is stored in the A register before saving "n", "n" is overwritten in the A register.

Subsequently, a specific example of the command in the twenty-fourth embodiment will be described.
168 to 171 are diagrams showing the types of instructions in the twenty-fourth embodiment, and show 37 types from No. 1 to No. 37. Note that these instructions are merely examples, and the number of instructions is not limited to the 37 types shown in FIGS. 168 to 171, and more instructions are provided.
First, the first and second instructions indicate "JTQ" instructions.
The first "JTQ NZ, (k), e" is the contents stored in the addresses with the contents of the Q register as the upper part and k as the lower part (hereinafter, the contents stored in the addresses to be operated are , "Target address value") is "0", and if it is not "0" (NZ), it is an instruction to shift the processing to e (address). is there.

The last "e" indicates the transfer destination address. For example, when the migration destination address is “0010(H)”, “e” is described as “0010(H)” (2 bytes).
Furthermore, "NZ" is a condition symbol in a branch instruction. The condition symbols of the branch instruction described below include the following.
NZ: When the operation result is not "0", in other words when the zero flag is not "1" Z: When the operation result is "0", in other words when the zero flag is "1" NC: The operation result is a digit If it does not fall, in other words if the carry flag is not "1" C: If the operation result is a digit carry down, in other words if the carry flag is "1"

In the above instruction, to determine whether the target address value is "0", "0" is subtracted from the target address value (target address value-"0"), and when the zero flag is not "1". , It is determined that the target address value is not “0”, and the process proceeds to e (address).
For example, it is determined whether or not the content stored in the address "F001(H)" is "0", and if the content is not "0", the process proceeds to the address "0010(H)". The instruction is “JTQ NZ, (01(H)), 0010(H)”.
In this case, it is determined whether or not the address stored in the address “F001(H)” with the Q register value “F0(H)” as the upper level and “01(H)” as the lower level is “0”. To judge.
And here,
"Contents of address "F001(H)""-"0"
Is calculated.

For example, when "1 (H)" is stored in "F001 (H)", "1-0 ≠ 0", and the zero flag is "0". Therefore, it is determined that the content stored in the address “F001(H)” is not “0”, and the processing is shifted to the address “0010(H)”.
On the other hand, when "0(H)" is stored in the address "F001(H)", for example, "0-0=0" and the zero flag becomes "1". Therefore, it is determined that the content stored in the address “F001(H)” is “0”, and the processing is ended (the processing is not shifted to the address “0010(H)”, and the next instruction (specifically, To execute the instructions stored at consecutive addresses).

As a method of determining whether or not the target address value is "0", "0" is subtracted from the contents stored in the target address, and when the zero flag is "1", it is stored in the target address. The method for determining that the content stored in the target address is not "0" (or the content stored in the target address is not "0" when the zero flag is not "1") can be determined by "NZ" or When it has a condition symbol of "Z", the same operation is performed.

The contents stored in the RWM 53 do not change before and after the execution of the above command. When the instruction of "JTQ NZ, (k), e" is executed, the contents stored in the addresses with the contents of the Q register as the upper and k as the lower do not change before and after the instruction.
Furthermore, even if an interrupt processing cycle arrives during execution of an instruction, the interrupt processing is not executed until the instruction is completed. When the interrupt processing cycle arrives during the execution of the instruction, the interrupt processing is waited until the instruction is completed, and the interrupt processing is executed after the instruction is completed.

Depending on the operation executed by the instruction, the zero flag and carry flag will have the value corresponding to the operation result of the instruction, but the value of the zero flag and carry flag corresponding to the operation result of the instruction will not change until the instruction is completed. Need to In other words, after the zero flag and the carry flag are changed by the execution of the instruction, the interrupt process is executed before the instruction is finished, and the zero flag and the carry flag are changed by the interrupt process. Corresponding zero flag and carry flag will be broken by the operation based on interrupt processing). In order to prevent this, the interrupt processing is not executed during the execution of the instruction.

In the twenty-fourth embodiment, not only the first instruction described above but also all the instructions shown in FIGS. 168 to 171 do not execute the interrupt processing even when the cycle of the interrupt processing comes during the execution of the instructions. , Interrupt processing is executed after the end of the instruction.
For example, when the “N”-th instruction and the “N+1”-th instruction are not in the interrupt prohibition period and the “N”-th instruction and the “N+1”-th instruction are continuously executed, If the cycle of interrupt processing comes during the execution of the N'th instruction, the interrupt processing is not executed until the'N'th instruction is completed, and the interrupt processing is executed after the'N'th instruction is completed. To do. Furthermore, the "N+1"th instruction is not executed during execution of this interrupt processing. After the interrupt processing is completed, the “N+1”th instruction is executed.
On the other hand, when the interrupt prohibition period is set between at least the “N”th instruction and the “N+1”th instruction, and the “N”th instruction and the “N+1”th instruction are continuously executed. When the cycle of interrupt processing comes during the execution of the “N”th instruction, the interrupt processing is not executed after the “N”th instruction is completed, and the interrupt processing is performed after the interrupt disable period ends. To execute. Here, the above-mentioned interrupt prohibition period corresponds to, for example, the period from the DI instruction to the EI instruction.
The commands shown in FIGS. 168 to 171 may be executed not only in the main process but also in the interrupt process.

The second instruction “JTQ Z, (k), e” is the same as the first instruction except that the condition symbol “NZ” in the first instruction is “Z”. is there. Contrary to the first instruction, this instruction, when it is determined that the content stored in the address in which the contents of the Q register are higher and k is lower is "0", that is, the zero flag is "1". If there is, the process moves to e (address). On the other hand, when it is determined that the target address value is not "0", the process ends.

An example of the second instruction is, for example, step S803 in FIG. 147 (23rd embodiment). A step S803 determines whether or not the value (prize and replay condition device number) stored in the address “F0A9(H)” is “0”. If it is determined to be “0”, the process proceeds to step S804. Therefore, for example, when the instruction in step S804 is stored at the address “0011(H)”, the instruction in step S803 becomes “JTQ Z, (A9(H)), 0011(H)”.

The third and fourth instructions are "RTQ" instructions.
These instructions are the same as the first and second instructions in that they judge whether or not the contents stored in the addresses with the contents of the Q register as the upper part and k as the lower part are "0". Is different from the first and second instructions in that when the condition specified by the instruction is satisfied, the caller is transferred to.
First, the third “RTQ NZ, (k)” determines whether the content stored in the address with the content of the Q register as the higher order and k as the lower order is “0” and “0”. If not (NZ), the process is terminated, and the process proceeds to the caller.
Here, in the case of moving to the caller after the end of the instruction like this third instruction, at the start of the instruction, the address (caller; 2 bytes) returned after the end of the instruction is stored in the stack area. To do.

The method of determining whether or not it is "0" is the same as that of the above "JTQ" instruction, and "target address value-"0"" is calculated.
The third “RTQ NZ, (k)” is a paraphrase when it is determined that the target address value (contents stored in an address with the contents of the Q register as upper and k as lower) is not “0”. Then, when the zero flag is not "1", the processing is terminated and the process proceeds to the calling source, and when the zero flag is "1", the next instruction (specifically, it is stored in an address consecutive to the instruction). Execute the specified instruction).
Further, the fourth "RTQ Z, (k)" terminates the process and shifts to the calling source when the zero flag is "1", and when the zero flag is not "1", the next instruction (specifically, Is an instruction for executing an instruction stored at addresses consecutive to the instruction.

An example of the fourth instruction is, for example, step S808 in FIG. 147 (23rd embodiment). In step S808, it is determined whether or not the value of the address "F098(H)" (AT standby counter) is "0". When the value is "0", the process proceeds to step S289 of the calling source in FIG. 139. To do. Therefore, for example, if the instruction of step S289 is stored at the address “0021(H)”, the instruction of step S808 of FIG. 147 becomes “RTQ Z, (98(H))”, and the stack area has , "0021(H)" which is the address of the calling source is stored.

The fifth to eighth are "RCP" instructions.
The fifth instruction "RCP NZ,A,n" compares the A register value (indicating the contents stored in the A register. The same applies hereinafter) with "n", and when the zero flag is not "1". This is an instruction to end the processing and shift to the calling source. Note that the A register value and "n" are compared in the same way in the sixth to eighth instructions.
The "comparison" in this RCP instruction calculates "A register value-"n"".
Example 1)
A register value = 6
n=5
, The instruction is “RCP NZ,A,5”.
In this case, an operation of subtracting "5" from the A register value is executed.
Therefore,
6-5=1 (≠0)
And the zero flag is "0".
Since the zero flag is "0", the process moves to the caller, that is, the address (2 bytes) saved in the stack area.
Example 2)
A register value = 4
n=5
, The instruction is “RCP NZ,A,5”.
In this case, an operation of subtracting "5" from the A register value is executed.
Therefore,
4-5=-1 (FF(H)) (≠0)
And the zero flag is "0".
Since the zero flag is "0", the process moves to the caller, that is, the address (2 bytes) saved in the stack area.
Example 3)
A register value = 5
n=5
, The instruction is “RCP NZ,A,5”.
In this case, an operation of subtracting "5" from the A register value is executed.
Therefore,
5-5=0
And the zero flag is "1".
Since the zero flag is "1", it does not move to the caller, that is, the address (2 bytes) saved in the stack area, and the next instruction (specifically, the instruction stored in the address consecutive to the instruction is stored. ) Is executed.

Furthermore, in the above instruction (the same applies to the following sixth to eighth instructions), an operation of subtracting "n" from the A register value is executed, but the A register value does not change even after the operation. .. For example, in the above-mentioned example 1, even if the operation of subtracting n "5" from the A register value "4" is executed, the A register value remains "4".
Thus, the A register value is not changed by the RCP instruction, so that the A register value can be continuously used after the RCP instruction.

The sixth instruction "RCP Z, A, n" differs from the fifth instruction in that the instruction moves to the calling source when the zero flag is "1". The comparison between the A register value and "n" is the same as that of the fifth instruction.
The seventh instruction "RCP NC, A, n" is an instruction that compares the A register value with "n" and shifts to the calling source when the carry flag is not "1".

As an example of this instruction, for example, step S805 of FIG. 147 (third embodiment) can be cited. In step S805, the accessory condition device number is stored in the A register value, and "n" is "2". Therefore, step S805 becomes an instruction "RCP NC, A, 2".
here,
Example 1)
When the A register value (role item condition device number) is, for example, "2" (at the time of winning the RBA or when carrying the winning information of the RBA),
2-2=0
And the carry flag is "0".
Therefore, since the carry flag is "0", the process proceeds to the calling source. The calling source in this case is the address after the reel stop acceptance check (M_STOP_CHK) (FIG. 146), that is, the address at which the instruction of step S289 in FIG. 139 is stored.
Example 2)
When the A register value (role item condition device number) is "0", for example,
0-2=-2 (FE(H))
And the carry flag is "1".
Therefore, since the carry flag is "1", the next instruction (instruction of step S806) is executed without shifting to the calling source.
Example 3)
When the A register value (role item condition device number) is "3", for example,
3-2=1
And the carry flag is "0".
Therefore, since the carry flag is "0", the process proceeds to the calling source. The calling source in this case is the address after the reel stop acceptance check (M_STOP_CHK) (FIG. 146), that is, the address at which the instruction of step S289 in FIG. 139 is stored.
Furthermore, the 8th "RCP C, A, n" is the instruction in which the "NC" in the 7th instruction has become "C", and when the carry flag is "1", shifts to the calling source. However, when the carry flag is “0”, it is an instruction to execute the next instruction (specifically, an instruction stored at an address consecutive to the instruction).

The ninth and tenth "LDWQ" commands are commands for storing a predetermined value in two consecutive addresses. In this instruction, “LD” means transfer as described above, and “W” indicates that the target address is 2 addresses.
This instruction can be executed even when there is no free space in the register (a situation where a value is stored in the register). It can also be used, for example, when actually using the temporarily stored data and storing the data.
The ninth instruction "LDWQ (k), (k')" is an address in which the contents of the Q register are upper and "k'" is lower, and an address obtained by adding "1" to the address. For example, the contents stored in the addresses with the contents of the Q register as the upper and “k′+1” as the lower, the contents with the contents of the Q register as the upper and “k” as the lower, and “1” in the address. Is added to the address, that is, the contents of the Q register are stored in the upper address and the lower address of “k+1”.

For example,
Contents saved in the upper address "Q" and lower address "k'": x
Contents saved in high-order address "Q" and low-order address "k'+1": y
If
Save "x" in the storage area of higher address "Q" and lower address "k",
It is an instruction to save “y” in the storage area of the upper address “Q” and the lower address “k+1”.

The tenth instruction, "LDWQ (k),mn", is an address in which the contents of the Q register are upper and "k" is lower, and an address obtained by adding "1" to the address, in other words, the Q register. Is an instruction to store "mn" (2-byte value) at an address in which the contents of is higher and "k+1" is lower.
This instruction is used, for example, when storing a 2-byte timer value in a 2-byte storage area.

As an example of this instruction, for example, in step S767 of FIG. 140 (the twenty-third embodiment), at the addresses “F0AB(H)” and “F0AC(H)”, the initial value “3672(D)” of the minimum game time is given. There is a process of storing.
Here, since "3672 (D)" = "0E58 (H)", the instruction in the above example becomes "LDWQ (AB (H)), 0E58 (H)" and becomes the address "F0AB (H)". “0E(H)” is saved, and “58(H)” is saved in “F0AC(H)”.

This command is also used, for example, when setting the initial value of the number of sheets to be acquired during 1BB operation. For example, in FIG. 133 (the twenty-third embodiment), since the number of 1BB that can be acquired in the twenty-third embodiment is 170, the storage area for storing the number of acquired 1BB is 1-byte storage at address “F00E(H)”. It has become an area. However, the present invention is not limited to this, and when the obtainable number of 1BB is 256 or more, the storage area for storing the obtainable number of 1BB is 2 bytes. Then, at the start of the 1BB game, the initial value of the obtainable number (2 byte value) at the time of 1BB operation is stored in the storage area.

The 11th and 12th shows "JTWQ" instructions. This instruction is an instruction that determines whether or not the content stored in two consecutive addresses is "0" and shifts the processing to the "e" address according to the determination result. This instruction can be used, for example, to determine whether or not the 2-byte timer has elapsed.
First, the eleventh instruction, "JTWQ NZ, (k), e", stores the contents stored in an address with the contents of the Q register as the upper part and "k" as the lower part, and "1" at the address. It is determined whether or not the content of the added address, in other words, the content stored in the address in which the content of the Q register is upper and the value of "k+1" is lower (that is, 2-byte data) is "0", If it is not "0", the processing is shifted to e (address), and if it is "0", the processing is not shifted to e (address) and the next instruction (specifically, the instruction Command stored in consecutive addresses) is executed.

Here, to determine whether or not it is "0", "2 byte data value"-"0" is calculated, and when the zero flag is "1", 2 byte data value is "0". Judge that there is. The same applies to the 12th to 14th instructions below.
The twelfth instruction, "JTWQ Z, (k), e," differs from the eleventh instruction in that the processing shifts to e (address) when the 2-byte data is "0". ..
As an example of this instruction, for example, step S766 in FIG. 140 (the twenty-third embodiment) can be cited. Step S766 is a process of determining whether or not the 2-byte data stored in the addresses “F0AB(H)” and “F0AC(H)” is “0”. When it is determined to be "0", the process proceeds to e (address), which is the address in which the instruction of the next step S767 is stored in this example. On the other hand, when it is determined that it is not "0", the process is not shifted to e (address), and in this example, the process proceeds to the address where the instruction of the next step S766 is stored.

The 13th and 14th are "RTWQ" instructions. This instruction is an instruction to determine whether or not the content (2-byte data) stored in two consecutive addresses is "0" and to shift to the calling source according to the determination result. That is, the eleventh and twelfth instructions described above move to e (address) when the condition defined in the instructions is satisfied, but the thirteenth and fourteenth instructions are defined as the instructions. When the above condition is satisfied, it is different from the eleventh and twelfth instructions in that a transition is made to the calling source. Like the 11th and 12th instructions, this instruction can be used for waiting for a 2-byte timer, for example.

The thirteenth instruction, "RTWQ NZ, (k)", is the contents stored in the address with the contents of the Q register as the upper part and "k" as the lower part, and the address obtained by adding "1" to the address. It is determined whether or not the stored contents, in other words, the contents stored in the address with the contents of the Q register as the upper part and the lower part of "k+1" (that is, 2-byte data) is "0", If it is not “0”, it shifts to the calling source, and if it is “0”, it is an instruction to execute the next instruction (specifically, the instruction stored in the address consecutive to the instruction). is there.
As an example of this instruction, for example, step S791 of FIG. 146 (third embodiment) can be cited. In step S791, it is determined whether the contents (waiting time) of the addresses "F041(H)" and "F042(H)" is "0" (whether the zero flag is "1"), and "0" is determined. If not, the process according to the flowchart of FIG. 146 is terminated and the caller, in this example, moves to the address where the instruction of step S289 in FIG. 139 is stored. On the other hand, whether or not the contents (waiting time) of the addresses “F041(H)” and “F042(H)” is “0” (whether the zero flag is “1”) is determined to be “0”. In this case, the instruction of step S792 of FIG. 146 (the instruction following step S791) is executed.
The 14th instruction "RTWQ Z, (k)" moves to the calling source when the 2-byte data value is "0", and when it is not "0", the next instruction ( Specifically, it is different from the 11th instruction in that it executes an instruction stored at addresses consecutive to the instruction. Otherwise, it is the same as the 13th instruction.

In FIG. 169, the fifteenth and sixteenth “ICPLDS” instructions are instructions that compare the target register value with “n” (1 byte value) and execute a predetermined process according to the operation result.
First, the fifteenth instruction "ICPLDS A,n" compares the contents stored in the A register with "n". The 15th instruction includes the following patterns 1 to 3 (however, it is not limited to these 3 patterns).

<Pattern 1>
A value obtained by adding "1" to the content stored in the A register is compared with "n". When "A register value + 1" exceeds "n", the value of "n" is stored in the A register. Set the value.
Here, the value obtained by adding "1" to the A register value is subtracted from "n"("n"-"A register value + 1"), and when the carry flag becomes "1", the value is stored in the A register. When the value of "n" is set and the carry flag does not become "1", the value of "n" is not set in the A register.
This instruction adds, for example, "1" to some counter every time a predetermined condition is satisfied (for example, for each game), and when the value exceeds "n" (upper limit value), the state is maintained. There is a case where it continues. Specifically, when a parameter (for example, the number of games) reaches the ceiling, while maintaining the ceiling state, when in the ceiling state, it is possible to execute each game, a specific lottery, and the like.

<Pattern 2>
a) When the content stored in the A register is less than “1”, “1” is added to the content stored in the A register (A register value=A register value+1) and the process ends. To do.
b) If the content stored in the A register is "1" or more, "n" (1 byte value) is set in the A register (A register value="n") and the process is terminated.
Here, "1" is subtracted from the content stored in the A register (A register value-"1"), and when the carry flag is "1", the content stored in the A register is "1". It is judged to be less than. Alternatively, "0" is subtracted from the content stored in the A register (A register value-"0"), and when the zero flag is "1", the content stored in the A register is less than "1". It is determined that
Further, "1" is subtracted from the content stored in the A register (A register value-"1"), and when the carry flag is "0", the content stored in the A register is "1". It is determined that the above.

<Pattern 3>
a) When the content stored in the A register is less than "n" (1 byte value), "1" is added to the content stored in the A register, and the process ends.
b) If the content stored in the A register is "n", the process is terminated.
c) If the content stored in the A register exceeds "n", the register A is set to "n" (1 byte value) and the process is terminated.

Here, "n" is subtracted from the content stored in the A register (A register value-"n"), and when the carry flag is "1", the content stored in the A register is "n". It is judged to be less than.
Further, "n" is subtracted from the content stored in the A register (A register value-"n"), and when the zero flag is "1", the content stored in the A register is "n". Judge that there is.
Furthermore, "n" is subtracted from the contents stored in the A register (A register value-"n"), and when the carry flag is "0" and the zero flag is "0", the A register It can be judged that the content stored in the table exceeds "n".

In the 16th instruction “ICPLDS (HL), n”, “A” (A register value (1 byte data)) in the 15th instruction is “(HL)” (HL register value (2 byte data) ) Became the order. Otherwise, it is the same as the 15th instruction.
The HL register is often used when storing 2-byte data (for example, an address value), and as an example, it is “HL” in the above instruction. However, the instruction is not limited to this, and may be an instruction to specify another pair register (BC register, DE register). In this case, “ICPLDS (BC),n” and “ICPLDS (DE),n” respectively.
This also applies to the instructions (26th, 29th, 30th) for specifying the "HL" register described below.

Although the description partially overlaps with the 15th instruction, the 16th instruction will be described again.
“ICPLDS (HL),n” compares the content stored in the HL register with “n”. Examples of this instruction include patterns 1 to 3 shown below (though not limited to these three patterns).

<Pattern 1>
A value obtained by adding "1" to the content stored in the HL register is compared with "n" (1 byte value). If "HL register value + 1" exceeds "n", the HL register Set the value of "n" to. When "n" is set in the HL register, the H register value becomes "0" and the L register value becomes "n".
Here, the value obtained by adding "1" to the HL register value is subtracted from "n"("n"-"HL register value + 1"), and when the carry flag becomes "1", it is stored in the HL register. When the value of "n" is set and the carry flag is not "1", the value of "n" is not set in the HL register.

<Pattern 2>
a) When the content stored in the HL register is less than "1", "1" is added to the content stored in the HL register (HL register value = HL register value + 1), and the process ends. To do.
b) When the content stored in the HL register is "1" or more, "n" (1 byte value) is set in the HL register (HL register value="n") and the process is terminated.
Here, "1" is subtracted from the content stored in the HL register (HL register value-"1"), and when the carry flag is "1", the content stored in the HL register is "1". It is judged to be less than. Alternatively, "0" is subtracted from the content stored in the HL register (HL register value-"0"), and when the zero flag is "1", the content stored in the HL register is less than "1". It is determined that
Also, "1" is subtracted from the content stored in the HL register (HL register value-"1"), and when the carry flag is "0", the content stored in the HL register is "1". It is determined that the above.

<Pattern 3>
a) When the content stored in the HL register is less than "n" (1 byte value), "1" is added to the content stored in the HL register and the process ends.
b) If the content stored in the HL register is "n", the process is terminated.
c) If the content stored in the HL register exceeds "n", "n" (1 byte value) is set in the HL register and the process is terminated.

Here, "n" is subtracted from the content stored in the HL register (HL register value-"n"), and when the carry flag is "1", the content stored in the HL register is "n". It is judged to be less than.
Also, "n" is subtracted from the content stored in the HL register (HL register value-"n"), and when the zero flag is "1", the content stored in the HL register is "n". Judge that there is.
Furthermore, "n" is subtracted from the contents stored in the HL register (HL register value-"n"), and when the carry flag is "0" and the zero flag is "0", the HL register It can be judged that the content stored in the table exceeds "n".

The "JCPQR" instruction, which is the 17th to 20th instruction, subtracts "n" (1 byte value) from the content of the address having the contents of the Q register as the high order and k as the low order, and e This is an instruction to shift the processing to (address).
This "JCPQR" instruction can be executed even in a situation where there are not enough registers because a conditional branch can be performed without using the A register and the HL register.

First, the 17th instruction, "JCPQR NZ,(k),n,e", starts with "n" (1 byte value) from the contents stored in the addresses with the contents of the Q register as the upper and k as the lower. If it is not "0" as a result of subtracting, it is an instruction to shift the processing to e (address).
In this instruction, "target address value-"n"" is calculated. When the zero flag is not "1", the processing shifts to e (address), and when the zero flag is "1", the next instruction ( Specifically, the instructions stored in the addresses consecutive to the instruction) are executed.
The 18th instruction, "JCPQR Z,(k),n,e", is "n" (1 byte value) from the contents stored in the addresses with the contents of the Q register as the high order and k as the low order. When it is “0” as a result of subtracting, it is an instruction to shift the processing to e (address).
In this instruction, “target address value−“n”” is calculated. When the zero flag is “1”, the process moves to e (address), and when the zero flag is not “1”, the next instruction ( Specifically, the instructions stored in the addresses consecutive to the instruction) are executed.

Furthermore, the 19th instruction, "JCPQR NC, (k), n, e", starts from "n" (1 byte value When the carry does not occur as a result of subtraction of () (when the carry flag is “0”), the instruction shifts the processing to e (address).
In this instruction, "target address value-"n"" is calculated. When the carry flag is "0", the processing shifts to e (address), and when the carry flag is "1", Command (specifically, a command stored at an address consecutive to the command) is executed.
Furthermore, the 20th instruction "JCPQRC C, (k), n, e" is "n" (1 byte value) from the contents stored in the addresses with the contents of the Q register as upper and k as lower. When the carry is generated as a result of subtracting (when the carry flag is “1”), the instruction shifts the processing to e (address).
Here, "target address value-"n"" is calculated, and if the carry flag is "1", the process moves to e (address). If the carry flag is not "1", the next instruction is executed. (Specifically, the instruction stored in the address consecutive to the instruction) is executed.

In FIG. 170, the 21st to 24th instructions are “RCPQ” instructions.
The “RCPQ” instruction is an instruction that subtracts “n” from the target address value and ends the process according to the subtraction result.
Therefore, the "RCPQ" instruction terminates the process when the condition specified in the instruction is satisfied. Therefore, like the "JCPQR" instruction, which is the 17th to 20th instruction, the "RCPQ" instruction moves to e (address). Is different from.

Since the “RCPQ” instruction is an instruction for directly comparing the target address values, it can be executed even when there is no vacancy in the register, like the “JCPQR” instruction described above.
The 21st instruction, “RCP NZ, (k), n”, is the result of subtracting “n” (1 byte value) from the contents stored in the address with the contents of the Q register as the upper part and k as the lower part. If it is not "0", it is an instruction to end the process (the next instruction starts from the return address stored in the stack area).
Here, "target address value-"n"" is calculated, and if the zero flag is not "1", the process is terminated, and if the zero flag is "1", the next instruction (stored in the stack area The instruction which is not the instruction corresponding to the return address, specifically, the instruction stored in the address consecutive to the instruction) is executed.
The 22nd instruction, "RCPQ Z, (k), n", subtracts "n" (1 byte value) from the contents stored in the addresses with the contents of the Q register as the upper and k as the lower. As a result, if it is “0”, it is an instruction to end the process.
Here, "target address value-"n"" is calculated, and when the zero flag is "1", the processing is ended, and when the zero flag is not "1", the next instruction (stored in the stack area The instruction which is not the instruction corresponding to the return address, specifically, the instruction stored in the address consecutive to the instruction) is executed.

Furthermore, the 23rd instruction, “RCPQ NC, (k), n”, outputs “n” (1 byte value) from the content stored in the address with the contents of the Q register as the upper part and k as the lower part. If a carry has not occurred as a result of the subtraction (if the carry flag is “0”), the processing is terminated (the next instruction starts from the return address stored in the stack area). is there.
Here, "target address value-"n"" is calculated, and if the carry flag is not "1", the process is terminated, and if the carry flag is "1", the next instruction (stored in the stack area) The instruction that is not the instruction corresponding to the returned address, specifically, the instruction stored at the address consecutive to the instruction is executed.
In addition, the 24th instruction, "RCPQ C, (k), n", subtracts "n" (1 byte value) from the contents stored in the address with the contents of the Q register as the upper part and k as the lower part. As a result, if it is less than “n”, it is an instruction to end the process (the next instruction starts from the return address stored in the stack area).
Here, "target address value-"n"" is calculated, and if the carry flag is "1", the process is ended, and if the carry flag is not "1", the next instruction (stored in the stack area) The instruction that is not the instruction corresponding to the returned address, specifically, the instruction stored at the address consecutive to the instruction is executed.

The 25th instruction, “LDQ (k), (k′)”, indicates that the contents stored in the addresses with the contents of the Q register as the upper part and k′ as the lower part, the contents of the Q register as the upper part and k This is an instruction to save to a lower address.
For example,
Contents saved in the upper address "Q" and lower address "k'": x
If
This is an instruction to save “x” in the storage area of the upper address “Q” and the lower address “k”.
This instruction is used when it is desired to move the value of the predetermined address (copy source) of the RWM to another address (copy destination) when the register is not empty.

The 26th “CLRHL (HL),n” sets the content of each address to “0” (clears) from the address indicated by the HL register to the “n” address destination, in other words, to the “HL+n” address. It is an instruction. In this case, the contents before storing "0" are not viewed, and "0" is stored regardless of whether the contents of the address storing "0" is "0".

In such processing, for example, as in step S435 of FIG. 51 (the eleventh embodiment), the contents of a series of addresses of the RWM 53 (addresses for storing data regarding the advantageous period and the AT) are sequentially read. It is used when setting to "0".
Also, it can be used when executing RWM clear of a predetermined range of addresses at the start of the game.
Furthermore, "n" in this instruction is a 1-byte value, but if "n" is applicable to a 2-byte value, for example, RWM clear of an address in a predetermined range at the time of setting change (for example, It can also be used in step S224) of FIG. 39 (the eleventh embodiment).

FIG. 172 is a diagram showing addresses of the RWM 53 for storing data regarding the advantageous section and the AT in the twenty-fourth embodiment. As shown in FIG. 172, the addresses for storing the data regarding the advantageous period and the AT, in other words, the addresses to be initialized in the RWM initialization process in step S435 of FIG. To do. Then, in the process of step S435, a process of storing "0" in the storage area from the address "F070(H)" to "F07B(H)" is executed. For example, in the example of FIG. 172, it becomes “CLRHL (F070(H)), B(H)”.

Also, in the instruction “CLRHL (F070(H)), B(H)”, the HL register value at the start of the instruction is “F070(H)”, but the value of the HL register after the end of this instruction. Is also “F070(H)”. That is, this instruction does not change the HL register value. As a result, when the HL register value is used also in the next instruction, it can be used as it is.

On the other hand, in the conventional technique, the reference address is stored in the HL register, and when the data of the addresses from the reference address to the “n” address destination is sequentially cleared, the following processing is performed.
For example, when the HL register value is "F070(H)" and the data up to the address "B(H)", that is, the data up to "F07B(H)" is cleared as described above,
Save "0" at the address indicated by the HL register value (F070(H)) ↓
HL register value = HL register value + 1
Save "0" at the address indicated by the HL register value (F071(H)) ↓
HL register value = HL register value + 1
Save "0" at the address indicated by the HL register value (F072(H)) ↓
:
↓
HL register value = HL register value + 1 (F07B(H))
“0” is stored in the address indicated by the HL register value (F07B(H)).

Therefore, when "0" is stored in the storage area from address "F070(H)" to "F07B(H)", the HL register value at the end of the instruction is "F07B(H)".
Therefore, in the next instruction, when executing some instruction again with "F070(H)" as the reference address, it was necessary to save "F070(H)" in the HL register again.
On the other hand, in the “CLRHL (HL),n” instruction, the HL register value that was initially set is maintained even after the end of the instruction, so there is no need to perform processing for returning the HL register value to the reference address value. Therefore, it is possible to reduce the program capacity and the processing time.

In FIG. 170, the 27th instruction, “DCPLDQ (k), 0”, is “1” if the contents stored in the address with the contents of the Q register as the higher order and k as the lower order are not “0”. Is an instruction to subtract.
Here, whether or not the content stored in the address in which the content of the Q register is upper and k is lower is "0" is calculated by "object address value-"0", and the zero flag is "1". , It is determined that the content stored in the target address is “0”. If it is not "0", "1" is subtracted.

The following two patterns are possible for this command.
<Pattern 1>
If the content stored in the address in which the content of the Q register is higher and the value of k is lower is "0", "1" is not subtracted.
<Pattern 2>
When the carry flag becomes "1" as a result of subtracting "1", "0" is stored in the target address. In this case, it means that the content before subtraction is "0".
Any of these may be adopted.

The 28th instruction "DCPWLDQ (k), 0" is an address in which the contents of the Q register are upper and k is lower, and the address +1 (the contents of the Q register is upper and "k+1" is lower. If the content stored in () is not "0", it is an instruction to subtract "1".
The 28th instruction differs from the 27th instruction that subtracts "1" from 1-byte data in that "1" is subtracted from 2-byte data. Other points, such as pattern 1 and pattern 2 above, also apply to this instruction.

The 29th and 30th instructions are "LDWQ" instructions.
The 29th instruction, “LDWQ (k), (HL+d)”, saves the contents of the address “HL+d (1 byte value)” in an address with the Q register as the upper address and k as the lower address, and “HL+d( This is an instruction to save the contents of the address of (1 byte value)+1” in the address +1 where the Q register is upper and “k” is lower (the address where the Q register is upper and “k+1” is lower).
This instruction can be used, for example, when a value is fetched from the input port 51 and stored in the target address.

For example,
HL=51 (H)
d=1
Contents of F052(H)(HL+d)=1(H)
Contents of F053(H)(HL+d+1)=2(H)
k=60 (H)
If it is, the value “1(H)” stored in the address “F052(H)” is stored in the address “F060(H)” and is stored in the address “F053(H)”. The value “2(H)” is stored in the address “F061(H)”.

The 30th instruction “LDWQ (HL+d), (k)” is an instruction in which “k” and “HL+d” are opposite to the 29th instruction, and the Q register is higher than The contents of the address with k as the lower order are saved in the address of “HL+d (1 byte value)”, and the address with the Q register as the higher order and k as the lower order+1 (the address with the Q register as the upper order and “k+1” as the lower order) ) Is stored in the address of "HL+d (1 byte value)+1".
This instruction can be used, for example, when writing data directly from the target address when outputting to the output port 52.
For example,
k=60 (H)
Contents of F060 (H) = 1 (H)
Contents of F061 (H) = 2 (H)
HL=51 (H)
d=1
If it is, the value “1(H)” stored in the address “F060(H)” is stored in the address “F052(H)”, and the content “2( H)” is stored in the address “F053(H)”.

In FIG. 171, “cc” in the 31st to 36th instructions indicates either “NZ” or “Z”.
In the 31st instruction, “JT NZ, (DE), e” is an instruction that calculates the contents of the DE register and, if not “0”, shifts the processing to e (address). If it is, it is an instruction to execute the next instruction (specifically, the instruction stored at the address next to the instruction) without shifting the processing to e (address).
Here, “calculate the contents of the DE register” is a calculation for determining whether the DE register value is “0”. In this embodiment, "DE register value-"0"" is calculated, and when the zero flag is not "1", it is determined that the DE register content is not "0".

On the other hand, “JT Z,(DE),e” is an instruction which is the reverse of the above, calculates the contents of the DE register, and when it is “0”, in other words, when the zero flag is “1”. Is an instruction to shift the processing to e (address). If the zero flag is not "1", the processing is not shifted to e (address) and the next instruction (specifically, the next The instruction stored in the address) is executed.
Note that the 31st instruction specifies “DE” because it specifies a register that stores 2-byte data, but is not limited to this, and may specify a BC register or an HL register. In this case, they are “JT cc, (BC), e” and “JT cc, (HL), e”, respectively.
This also applies to the 32nd instruction below.

The 32nd instruction is different from the 31st instruction that shifts the processing to e (address) in that the processing is ended when the condition of the instruction is satisfied. Others are the same as the 31st instruction.
In the 32nd instruction, "RT NZ,(DE),e" calculates the contents of the DE register, and if not "0", the processing is terminated (the next instruction is stored in the stack area. If it is “0”, it is the instruction to execute the next instruction (specifically, the instruction stored at the address next to the instruction).
Here, "calculate the contents of the DE register" is the same as above.
Further, "RT Z, (DE), e" calculates the contents of the DE register, and when it is "0", the processing is terminated (the next instruction is the return address stored in the stack area. If it is not “0”, it is the instruction to execute the next instruction (specifically, the instruction stored at the address next to the instruction).

In the 33rd instruction, "JTQ NZ, (k), e" calculates the contents stored in the addresses having the Q register as the higher order and k as the lower order, and if not "0", e (address ), and if it is “0”, it is an instruction to execute the next instruction (specifically, an instruction stored at an address consecutive to the instruction).
Here, "calculate the contents stored in the addresses having the Q register as the upper part and k as the lower part" means "the contents of the address indicated by the target register-"0"", and the zero flag is "1". If not, it is determined that the contents stored in the addresses having the Q register as the higher order and k as the lower order are not "0".

On the other hand, in the 33rd instruction, "JTQ Z, (k), e" calculates the contents stored in the addresses having the Q register as the higher order and k as the lower order, and if "0", When the processing shifts to e (address) and the value is not "0", it is an instruction to execute the next instruction (specifically, an instruction stored at an address consecutive to the instruction). Here, in the same manner as above, "the content of the address indicated by the target register-"0"" is calculated, and when the zero flag is "1", the Q register is stored in the address with the higher order and k as the lower order. It is determined that the content is “0”.

The 34th instruction is different from the 33rd instruction that shifts the processing to e (address) in that the processing is terminated when the condition of the instruction is satisfied. Others are the same as the 33rd instruction.
In the 34th instruction, “RTQ NZ, (k)” calculates the contents stored in the addresses having the Q register as the higher order and k as the lower order, and if not “0”, ends the process ( The next instruction starts from the return address stored in the stack area), and if it is "0", the next instruction (specifically, the instruction stored at the address consecutive to the instruction) Is an instruction to execute.
Also, "RTQ Z, (k)" calculates the contents stored in the addresses having the Q register as the higher order and k as the lower order, and if "0", terminates the process (next instruction Starts from the return address stored in the stack area), and if it is not "0", the instruction to execute the next instruction (specifically, the instruction stored at the address consecutive to the instruction) Is.
In these instructions, "the content of the address indicated by the target register-"0"" is calculated, and the processing is ended according to the value of the zero flag.

The thirty-fifth "RTW" instruction is an instruction for determining whether or not the content stored in the target register is "0" and ending the processing according to the determination result.
This instruction may be used, for example, when a timer value is stored in a register and it is determined whether or not the timer value has elapsed.
In the 35th instruction, “ss” indicates either the BC register, the DE register, or the HL register.
For example, the instruction "RTW NZ, (BC)" calculates the contents of the BC register, and if it is not "0", the processing is terminated (the next instruction is the return address stored in the stack area. If it is “0”, it is an instruction to execute the next instruction (specifically, an instruction stored at an address consecutive to the instruction).

Here, "calculate the contents of the BC register" is a calculation for determining whether or not the BC register value is "0". In the present embodiment, "BC register value-"0"" is calculated, and when the zero flag is not "1", it is determined that the content of the BC register is not "0". The same applies to "RTW NZ, (DE)" for calculating the contents of the DE register and "RTW NZ, (HL)" for calculating the contents of the HL register.

Further, "RTW Z, (BC)" is an instruction for calculating the content of the BC register and ending the processing when it is "0". The content of the BC register is calculated as “BC register value−“0””. When the zero flag is “1”, the content of the BC register is determined to be “0”. The same applies to "RTW Z, (DE)" for calculating the contents of the DE register and "RTW Z, (HL)" for calculating the contents of the HL register.

The 36th “RBITQ” instruction is an instruction that determines whether or not a predetermined bit of the content stored in the target address is “0” and terminates the processing according to the determination result. Since this instruction does not directly judge (see) the register value, it is an instruction that can be used even when there is no register space.
In the 36th instruction, “RBITQ NZ,b,(k)” is “b” (any of 0 to 7 bits) among the contents stored in the addresses with the Q register as the upper and k as the lower. Is not "0", the process is terminated (the next instruction starts from the return address stored in the stack area), and "b" (one of 0 to 7 bits) is "0". In some cases, it is an instruction to execute the next instruction (specifically, an instruction stored at an address consecutive to the instruction).
For example, the instruction for determining whether the D1 bit is "0" is "PBITQ NZ,1,(k)". Here, "0" is subtracted from the target bit value, and when the zero flag is "0", it is determined that the target bit value is not "0".

On the contrary, “RBITQ Z,b,(k)” is “b” (any of 0 to 7 bits) among the contents stored in the addresses with the Q register as the upper and k as the lower. Is 0, it is an instruction to end the process. Also in this case, "0" is subtracted from the target bit value, and if the zero flag is "1", it is determined that the target bit value is "0".

The thirty-seventh "BITQ" instruction indicates which bit of the content stored in the target address is set ("1") or how many bits are set ("1" bit is It is an instruction to check how many).
“BITQ A, (k)” is an instruction for inspecting the position of the content of “A” among the contents stored in the addresses with the Q register as the upper and k as the lower.
In this command, the following two patterns are mainly considered.

<Pattern 1>
As the pattern 1, it is checked whether or not the designated bit is “1” in the contents stored in the target address.
For example, in the case of the instruction "BITQ 3, (k)", the instruction to check whether or not the D3 bit of the content stored in the address with the Q register as the upper and k as the lower is "1" Become.
<Pattern 2>
Further, as the pattern 2, the number of bits which is “1” is searched from the contents stored in the target address, and the number of bits which is “1” is stored in the A register.

The instructions 1 to 37 described above are binarized (coded) and stored in the ROM 54 as instruction codes. Then, as shown in FIG. 167(A), since the command is composed of command information and identification information, when the command is coded, it is composed of a command information code and an identification information code.
Here, in the twenty-fourth embodiment, when the instruction is coded, the code including the most significant bit of the instruction code is defined as the instruction information code.
If the code including the most significant bit of the instruction code is the instruction information code, the main CPU 55 can quickly determine which instruction should be executed when the instruction code is read from the most significant bit. Becomes
The arrangement of the instruction code may be, for example, “(instruction information code) (identification information code) (instruction information code)” or “(instruction information code) (identification information code)”.

However, not limited to the above, when the instruction is coded, the least significant bit of the instruction code may be determined to include the instruction information code.
The arrangement of the instruction code in this case may be, for example, “(identification information code) (instruction information code)” or “(instruction information code) (identification information code) (instruction information code)”. In this case, when the instruction code is read, by reading the code including the least significant bit first, the main CPU 55 can quickly determine which instruction should be executed by the instruction code. Become.

Although the twenty-fourth embodiment has been described above, the twenty-fourth embodiment is not limited to the above contents, and various modifications such as the following are possible.
(1) Although the initial value of the Q register is set to “F0(H)”, it is not limited to this, and it differs depending on the upper address value of the work area in the usage area of the RWM 53. For example, when the upper address of the work area in the usage area of the RWM 53 is set to "E1(H)", the initial value of the Q register is "E1(H)".
(2) The bits corresponding to the carry flag (C) and the zero flag (Z) in the F register shown in FIG. 166(B) are examples, and the present invention is not limited to these. For example, the D3 bit may be a carry flag (C) and the D4 bit may be a zero flag (Z).
(3) The twenty-fourth embodiment is not limited to the instructions illustrated in FIGS. 168 to 171, and more instructions are provided to execute the program of the slot machine 10.
The commands illustrated in FIGS. 168 to 171 are not limited to the illustrated description.
(4) In the twenty-fourth embodiment, the slot machine 10 (FIG. 1) is illustrated as an example of the gaming machine, but it is also possible to implement it with the pachinko gaming machine 500 (FIG. 99).

<Twenty-fifth embodiment>
Subsequently, a twenty-fifth embodiment of the present invention will be described.
The twenty-fifth embodiment is, firstly, an invention regarding a method of determining a winning combination (a symbol combination stopping on an activated line). Secondly, the invention relates to a method of determining the number of payouts when a small winning combination is won.
In the 25th embodiment, the basic configuration of the slot machine 10 is the same as that of the 23rd embodiment. Therefore, the twenty-fifth embodiment includes FIGS. 114 to 163.
In the present specification (including all embodiments) and claims, the term "at the time of stop" of the reel 31 or the symbol means that the stop switch 42 corresponding to the reel is stopped when the stop switch 42 is operated. When the stop operation of is detected (when the level data or the rising data is turned on), when the stop position of the symbol is determined based on the stop operation of the stop switch 42, after the stop position of the symbol is determined When the symbol (reel 31) is not yet stopped (when it is about to stop, for example, during deceleration), the output state to the motor 32 is the excitation state for stopping the reel 31 (for example, the four-phase excitation state (fourth phase). (Refer to the embodiment). The same applies in this paragraph hereinafter), when the excitation state for stopping the reel 31 is finished, when the reel 31 is actually stopped, or when the symbol is stopped and displayed ( The meaning (any meaning) is included after the end of the excitation state for stopping the reel 31 (when the excitation output to the motor 32 is not performed).
Therefore, when the reel 31 or the symbol is called “at the time of stop”, the reel 31 or the symbol is not always stopped.

Further, although it partially overlaps with the matters explained at the beginning of the first embodiment, it will be explained anew that, in all of the present specification and claims, "payout (payout)" means that a medal is actually a hopper. Not only paying out from 35, but also adding credits is included. Further, if the gaming machine is a management gaming machine that does not use medals (sometimes referred to as an enclosed gaming machine, a medalless gaming machine, an ECO gaming machine, the same applies hereinafter), an electronic gaming medium is added. Is also included.
Therefore, in the present specification (including all the embodiments) and the claims, “payout” can also be referred to as “grant”. Therefore, for example, the “payout number table” can be referred to as a “granting number table”.

173 to 175 are diagrams showing the contents of the RWM 53 in the twenty-fifth embodiment. 173 to 175 partially include the contents already described in the other embodiments.
In FIGS. 173 to 175, the numerical value written in parentheses below the address indicates the number of bytes in the storage area of the address (same as in FIGS. 133 to 138).
In FIG. 173, the operation state flag (_FL_ACTION) of the address “F00C(H)” is a storage area of a flag for determining the presence or absence of the operation of the accessory, and the operation shown in FIG. 35 (the eleventh embodiment). It corresponds to the status flag.
In the twenty-fifth embodiment, the D3 bit corresponds to 1BB and the D4 bit corresponds to RB (RBA to RBP). Similar to the eleventh embodiment, the operating state flag is updated in the game start set processing (step S272 in FIG. 139). Also, it is cleared in the game end check processing (not shown in FIG. 148).

The number of games when the RB of the address "F00F(H)" is operating (_CT_BONUS_PLAY) and the number of winnings when the RB of the address "F010(H)" is operating (_CT_BONUS_WIN) are shown in FIG. 133 (the twenty-fifth embodiment). It is the same storage area as the one. In the twenty-fifth embodiment, as shown in FIG. 202 described later, the method of updating the number of winnings during RB operation is different from that of the other embodiments.

The stop acceptance information data (_PT_STOP_STS) at the address “F01E(H)” is a storage area for storing whether or not the stop switch 42 can accept.
First (left) to third (right) stop switches 42 are assigned to the D0 to D2 bits of the stop acceptance information data, respectively. Before the start of the rotation of the reel 31, and from the start of the rotation of the reel 31 until the constant speed is reached and the operation of the stop switch 42 can be accepted, the value is "0". It becomes.
In addition, "until the operation of the stop switch 42 can be accepted" means that the index sensor corresponding to the reel 31 is detected and the symbol number is stored (any reel 31 that has not detected an index). However, if there is another reel 31 that has detected the index, the other reel 31 may be stopped), or the index sensor corresponding to all reels 31 is detected and the symbol number is stored. Until it is done.
In particular, in the present embodiment, in FIG. 140 (the twenty-third embodiment), the minimum game time is stored in the RWM 53 in step S767, and then "0000111 (B)" is set as the initial value in the stop acceptance information data. Then, for example, when the first (left) stop switch 42 is operated, in the stop acceptance information data, the bit corresponding to the first stop switch 42 becomes "0" and is updated to "00000110 (B)".
This stop acceptance information data may be used when masking bits other than the D0 to D2 bits of the input port rising data A (FIG. 133).

The payout amount data (_NB_PAY_MEDAL) of the address "F023(H)" and the payout amount data buffer (_BF_PAY_MEDAL) of the address "F024(H)" are respectively the payout amount data (_BF_PAY_MEDAL) shown in FIG. 35 (the eleventh embodiment). _NB_PAY_MEDAL) and payout amount data buffer (_BF_PAY_MEDAL).
Explaining again, when one of the small prizes is won and the payout number is determined, the payout number data and the payout number data buffer respectively store the payout number (the same value). The payout number data is decremented by "1" each time one medal is paid out (including addition of credit), and becomes "0" when the payout process is completed. On the other hand, the payout amount data buffer is not subtracted even if the payout process is executed, and the initial value is maintained even after the payout process. The payout amount data buffer is updated (overwritten) at the end of the next game. In addition, the payout number is updated using the value of the payout number data buffer, and the above-mentioned instructed winning character ratio (cumulative), continuous winning character ratio (6000 games), winning character ratio (6000 games), continuous winning character ratio. It is possible to calculate (cumulative) and accessory ratio (cumulative).

The reel stop flag (_FL_STOP_LP) at the address “F0AD(H)” is a flag storage area for determining whether or not the stop of the reel 31 is accepted. It is "1" when the reel stop acceptance is not completed, and "0" when the reel stop acceptance is completed. Therefore, when none of the reels 31 is stopped and received while the reels 31 are rotating, "00000011 (B)" is displayed. For example, when the first (left) reel 31 is stopped and received, "00000110 (B)". Becomes

The stop/control reel number data (_NB_STOP_REEL) at the address “F0AF(H)” is a storage area for storing the reel number during control or stop acceptance. When the reel 31 is being controlled and the stop acceptance is not in progress, the value is "0". For example, when the third stop switch 42 is operated to accept the stop of the third reel 31, or when the stop control of the third reel 31 is being performed. Is "00000011 (B)" (3 (D)).

The control symbol number (_BF_PICTURE) of the address "F0B4(H)" is a storage area for storing the symbol number stopped at the reference position. Here, the reference position in the twenty-fifth embodiment is the “lower stage”. Further, the line "lower left"-"middle lower"-"lower right" is referred to as a "reference line" in the twenty-fifth embodiment.
On the other hand, in FIGS. 135 to 137, the # reel symbol number (for stop position) (_NB_RL#_STPPIC) shows the symbol number of the symbol stopped in the middle stage.
Therefore,
"Control symbol number (_BF_PICTURE) = "# reel symbol number (for stop position) (_NB_RL#_STPPIC)"-"1"
It becomes a relationship.
Specifically, when the first (left) reel 31 is stopped at the position shown in FIG. 115(A), the first reel symbol number (for stop position) (_NB_RL1_STPPIC) is “13(D)( Red 7)”, and the control symbol number (_BF_PICTURE) becomes “12 (D) (bell B)”.

In FIG. 174 and FIG. 175, the stop symbol data (first group to ninth group) (_WK_STOP_PIC1 to 9) of the addresses “F0B7(H)” to “F0BF(H)” determine the symbol combination to be stopped on the activated line. This is a storage area for storing data for stopping (stop symbol data).
In the twenty-fifth embodiment, as shown in FIGS.
1 BB
RB (RBA-RBP)
Replay (Replay 01 ~ Replay 10)
Small role (small role 01-small role 34)
Is provided.
Then, the symbol group related to the symbol combination of the winning combination is determined as follows.
Design 1 group: RBA ~ RBH operation design Design 2 group: RBI ~ RBP operation design Design 3 group: 1BB operation design, and Replay 01 ~ Replay 07 act design Design 4 group: Replay 08 ~ Replay 10 act design Design 5 group: small Role 01 ~ small role 08 operation pattern 6 group: Small role 09 ~ small role 16 operation pattern 7 group: Small role 17 ~ small role 24 operation pattern 8 group: Small role 25 ~ small role 32 operation pattern 9 group ：Small winning combination 33 and small winning combination 34 Operational symbol In addition, in FIGS. 174 and 175, although it is described as “operating symbol”, “operating symbol” has the same meaning as “symbol combination”. Hereinafter, as necessary, it will be referred to as a "symbol combination" or an "operating symbol". Further, the symbol combination decided to be stopped, or the symbol combination which is actually stopped may be referred to as a "stop symbol combination".

The stop symbol data (first group) and the stop symbol data (second group) correspond to RBA to RBP.
For example, when all the reels 31 are stopped, when the stop symbol data (first group) is “00000000(B)”, it means that the symbol combination of RBA to RBH is not stopped on the activated line. On the other hand, when all the reels 31 are stopped, when the stop symbol data (first group) is “00000010(B)”, it means that the symbol combination of RBB is stopped on the activated line.
In the stop symbol data (third group), the D0 bit corresponds to 1BB, and the D1 to D7 bits are bits corresponding to Replay 01 to Replay 07, respectively.

Furthermore, in the stop symbol data (fourth group), D0 to D2 bits are bits corresponding to Replay 08 to Replay 10, respectively. Bits D4 to D7 are unused.
Furthermore, the bits corresponding to the small winning combinations 01 to 34 are assigned to the respective bits of the stopping symbol data (fifth group) to the stopping symbol data (9th group). The D2 to D7 bits of the stop symbol data (9th group) are unused.
Then, to the stop symbol data (first group) to the stop symbol data (fourth group), a combination (1BB, RB, and replay) without payout is assigned, and the stop symbol data (fifth group) to the stop symbol data (the fifth group). Small groups with payouts are assigned to (9 groups).
In this way, by dividing the storage area of the stopped symbol data, it is possible to simplify the determination of the number of coins to be paid out, when any symbol combination of the winning combination is stopped on the activated line, and the special character It is possible to simplify the counting of the number of winnings of the small winning combination when the object (RB) is operating (details will be described later).
Further, in the stop symbol data (fifth group) to the stop symbol data (the ninth group) having payout, D0 to D7 bits (small win 01 to small win 08) of the stop symbol data (fifth group), and the stop symbols Bits D0 to D3 (small win 09 to small win 12) of the data (sixth group) correspond to the payout of 15 sheets.
Furthermore, the D4 to D7 bits (small win 13 to small win 16) of the stop symbol data (sixth group) and the D0 to D7 bits (small win 17 to small win 24) of the stop symbol data (seventh group) are It corresponds to the payout of three sheets.
Furthermore, the D0 to D7 bits (small win 25 to small win 32) of the stop symbol data (8th group), and the D0 to D1 bits (small win 33 to small win 34) of the stop symbol data (9th group), It is equivalent to one payout.

In the twenty-fifth embodiment, when the start switch 41 is operated, the winning combination lottery process is performed (step S761 in FIG. 140), and the winning condition and the replay condition playing device number are stored based on the winning number. After saving, set the initial value to the stop symbol data (_WK_STOP_PIC). Here, the bit corresponding to all the working symbols of the stop symbol data (first group) to the stop symbol data (9th group) is set to "1".
In particular,
Stop symbol data (first group): 11111111 (B)
Stop symbol data (second group): 11111111 (B)
Stop symbol data (third group): 11111111 (B)
Stop symbol data (4th group): 00000111 (B)
Stop symbol data (5th group): 11111111 (B)
Stop symbol data (6th group): 11111111 (B)
Stop symbol data (7th group): 11111111 (B)
Stop symbol data (8th group): 11111111 (B)
Stop symbol data (9th group):00000011 (B)
Set to.

Then, after the stop position of the reel 31 is determined (may be after the reel 31 is actually stopped), the bit corresponding to the winning combination that is not likely to be stopped on the activated line is updated to "0". .. For example, when the symbol to be stopped on the activated line is “Replay” when the left reel 31 is stopped, as shown in FIG. 116, the symbol combinations of all RBs (RBA to RBP) may be stopped on the activated line. Disappear. In this case, when the left reel 31 is stopped and the symbol stopped on the activated line is “replay”,
Stop symbol data (first group): 00000000 (B)
Stop symbol data (second group): 00000000 (B)
Will be updated.

Further, for example, when the symbol to be stopped on the activated line is “Red 7” when the middle reel 31 is stopped, as shown in FIG. 116, the symbol combination of RBA to RBH and RBM to RBP among RBs is effective. Eliminates the possibility of stopping on the line. On the other hand, among RBs, the symbol combination of RBI to RBL has a possibility of stopping on the activated line. Therefore, when the middle reel 31 is stopped in this case,
Stop symbol data (first group): 00000000 (B)
Stop symbol data (second group): 000011111 (B)
Will be updated.

In this way, after the stop position of each reel 31 is determined, the stop symbol data (first group) to the stop symbol data (9th group) are updated, and after the stop positions of all reels 31 are determined, stop When all of the symbol data (first group) to the stopped symbol data (9th group) are "00000000(B)", the symbol combination corresponding to the winning combination in the game is not stopped on the activated line (the winning combination is It has been determined that no prize).
On the other hand, when any bit of the stop symbol data (first group) to the stop symbol data (9th group) is "1", the symbol combination of the winning combination corresponding to the bit is stopped on the activated line. It is determined that
Furthermore, when any one of the bits of the stop symbol data (first group) to the stop symbol data (fourth group) is "1", it is determined that there is no medal payout in the game.
On the other hand, when any of the bits of the stop symbol data (fifth group) to the stop symbol data (9th group) is "1", it is determined that there is a medal payout in the game. ..

Here, in the present embodiment,
Small role 01 to small role 12:15 payout Small role 13 to small role 24:3 payout Small role 25 to small role 34:1 payout.
Therefore, when any bit of the stop symbol data (fifth group) or any of the D0 to D3 bits of the stop symbol data (sixth group) is "1", it is determined that the payout of 15 sheets is made. ..
Further, when any of the D4 to D7 bits of the stop symbol data (sixth group) or the D0 to D7 bits of the stop symbol data (seventh group) is "1", it is determined that three pieces are paid out. ..
Furthermore, when any of the D0 to D7 bits of the stop symbol data (8th group) or the D0 to D1 bits of the stop symbol data (9th group) is "1", it is determined that one sheet is paid out. It

176 to 179 are diagrams showing definition data in the twenty-fifth embodiment. In the definition data, “EQU” is an assembler instruction that defines a symbol as having an integer value, and means “equal”.
FIG. 176 shows a reel symbol definition and a symbol definition.
The reel symbol definition shows the relationship between symbols for ten types of symbols in the twenty-fifth embodiment and numerical values. For example, the "blue BAR" symbol is "@ZGR_01" when indicated by a symbol and "0" when indicated by a numerical value.
Further, the symbol definition shows the relationship between each symbol of the symbol group 1 to symbol group 9 and the numerical value. For example, “@_PIC1” is a symbol indicating a group of symbols. As described above, for example, the group of symbols 1 is composed of RBA to RBH, and each bit (D0 to D7) corresponds to RBA to RBH, respectively. And, for example, the D0 bit of the numerical value of the symbol 1 group is a bit corresponding to RBA.

177 to 179 show definition data of each operation symbol in the symbol group 1 to symbol group 9. Each bit of each symbol group coincides with a bit corresponding to each operation symbol of stop symbol data (first group) to stop symbol data (9th group).
As described above, for example, the D0 bit of the stop symbol data (first group) is a bit corresponding to the RBA operation symbol, but in the symbol group 1, the numerical value of the symbol "@SRB_A" indicating the RBA operation symbol is, It is defined in "00000001(B)" in which the D0 bit is "1". Similarly, the numerical value corresponding to the RBB operation symbol "@SRB_B" is set to "00000010(B)" in which the D1 bit is "1",..., The numerical value corresponding to the RBH operation symbol "@SRB_H" is , D7 bit is “1” and is defined as “10000000(B)”.

In the definition data, "@SRB" is a symbol indicating a shift RB (SRB) operation symbol, and substantially indicates the RBA operation symbol to the RBP operation symbol.
Further, for example, “@SRB_A_H” indicates the RBA operation symbol to the RBH operation symbol. The numerical value is "11111111(B)", which is equal to the case where all the bits of the stop symbol data (first group) are "1".
Furthermore, "@1BB" is a symbol indicating a 1BB operation pattern.
Furthermore, "@REP" is a symbol that indicates a replay operation pattern. Then, for example, “@REP_01” is a symbol indicating the Replay 01 operation pattern.
Further, in FIG. 178, “@WIN” is a symbol indicating a small win operation pattern. Then, for example, "@WIN_01" is a symbol indicating the small win 01 working pattern.
As described above, the symbols and numerical values of each operation symbol of each symbol group are defined.

FIG. 180 is a diagram showing an outline of various tables used in the twenty-fifth embodiment.
It should be noted that all the tables described below are stored at predetermined addresses in the ROM 54.
The reel symbol search table address offset table (TBL_PIC_SRCH) shown in FIG. 180(A) specifies the start address (offset value) of the target table for each reel 31 when searching the stop symbol of each reel 31. It is a table for.
For example, when searching for a stop symbol on the first reel 31, the value (offset value) stored at the address “1200 (H)” is referred to. Since the offset value is “3 (H)”, the offset value “3 (H)” is added to the address “1200 (H)” indicating the first reel 31 of the reel symbol search table address offset table (TBL_PIC_SRCH). The address "1203(H)" indicated by the value is specified as the start address of the first reel symbol array table (TBL_PICARG_1). As shown in FIG. 180(B), the first reel symbol array table (TBL_PICARG_1) is stored at addresses “1203(H)” to “120C(H)” (details will be described later), and the start address is The address is “1203(H)”.

Further, when searching for the stop symbol of the second reel 31, the value (offset value) stored in the address “1201(H)” is referred to. Since the offset value is "39(H)", the offset value "39(H)" is added to the address "1201(H)" indicating the second reel 31 of the reel symbol search table address offset table (TBL_PIC_SRCH). The address “123A(H)” indicated by the value is specified as the start address of the second reel symbol array table (TBL_PICARG_2) (FIG. 180(B)).
Similarly, when searching for a stop symbol on the third reel 31, the value (offset value) stored in the address “1203(H)” is referred to. Since the offset value is "8D(H)", the offset value "8D(H)" is added to the address "1202(H)" indicating the third reel 31 of the reel symbol search table address offset table (TBL_PIC_SRCH). The address “128F(H)” indicated by the value is specified as the start address of the third reel symbol array table (TBL_PICARG_3) (FIG. 180(B)).

As described above, offset values for identifying the head addresses of the symbol arrangement tables of the first to third reels 31 are stored at the three addresses of the reel symbol search table address offset table (TBL_PIC_SRCH).
Then, the first reel symbol array table (TBL_PICARG_1) corresponding to the first reel 31, the second reel symbol array table (TBL_PICARG_2) corresponding to the second reel 31, and the third reel symbol array table corresponding to the third reel 31. (TBL_PICARG_3) is provided.
These # reel symbol arrangement table (TBL_PICARG_#) is a table used to specify a symbol to be stopped on the activated line from the symbol number to be stopped at the reference position (details will be described later).

Further, as shown in FIG. 180(B), the # reel symbol combination table (TBL_PICCMB_#) is provided at an address continuous with the # reel symbol arrangement table (TBL_PICARG_#).
Each data of the # reel design combination table (TBL_PICCMB_#) is composed of reel design data information, reel design data information+table offset, and design data. Details of these data will be described later.

FIG. 181 is a diagram showing a first reel symbol array table (TBL_PICARG_1). In FIG. 181, the reel symbol definition shown in FIG. 176 is also shown.
Here, the data stored in each address of the # reel symbol arrangement table (TBL_PICARG_#) is referred to as "symbol data". This "symbol data" is data that can identify the type of symbol.
The first reel symbol arrangement table (TBL_PICARG_1), and the second reel symbol arrangement table (TBL_PICARG_2) and the third reel symbol arrangement table (TBL_PICARG_3), which will be described later, are tables each consisting of "10" addresses, and "10". The 0th to 19th symbols (20 symbols) are specified by the address. In other words, one address specifies two symbol data.

In FIG. 181, “*16” in the figure indicates the upper 4 bits. For example, in the address "1203 (H)", the upper 4 bits are "@ZGR_08" (2nd symbol, "cherry"), and the lower 4 bits are "@ZGR_02" (3rd symbol, "black BAR"). Indicates that there is.
As shown in FIG. 114, in the left reel 31, the second symbol is "cherry" and the third symbol is "black BAR".
Then, from the definition data, "@ZGR_08" is "7(H)", that is, "0111(B)". Further, "@ZGR_02" is "1(H)", that is, "0001(B)".
Therefore, in the address “1203(H)”, the upper 4 bits are “0111(B)” and the lower 4 bits are “0001(B)”, so that “0111/0001(B)” is actually It is stored (“/” indicates a boundary between upper 4 bits and lower 4 bits).

Here, for example, when the left (first) reel 31 is stopped, when the symbol stopped at the reference position (lower stage) is the first "watermelon", the symbol stopped at the activated line is the third "black BAR". (See FIGS. 114 and 115).
In this case, when the first "watermelon" is stopped at the reference position (lower stage), the value corresponding to the symbol stopped on the activated line is determined by the address "1203(H)" by the program (flow chart) described later. It is configured to be specified as the value of the lower 4 bits (“@ZGR — 02 ”, that is, “black BAR”).
Further, for example, when the second "cherry" stops at the reference position (lower row), the value corresponding to the symbol stopped on the activated line is the value of the upper 4 bits of the address "1204(H)", that is, "@ ZGR_05" (Bell A).

As shown in FIG. 181, in this embodiment, 20 symbol data are stored at 10 addresses. That is, in one address, the upper 4 bits specify 1 symbol data, and the lower 4 bits specify 1 symbol data. With this configuration, it is possible to reduce the capacity of the ROM 54 that stores the symbol data. Further, in the present embodiment, as shown in FIG. 181, since the types of symbols are less than 16 types (10 types (@ZGR_01 to @ZGR_10)), "0000 (B)" to "1010 (B)" It can be expressed as a range. Therefore, the upper 4 bits and the lower 4 bits can be stored, and the capacity of the ROM 54 can be reduced.
However, not limited to this, 20 symbol data may be stored at 20 addresses. In this case, one symbol will store one symbol data. This example is shown in FIG. 228 (Example 1 of the 27th embodiment) described later.

182 to 184 are diagrams showing the first reel symbol combination table (TBL_PICCMB_1). 182 to 184, and FIGS. 186 to 188 and 190 to 192 described later, “; //” means that there is no address storing the value. For example, the address “120F(H)” is an address that stores a value corresponding to “blue BAR” of the symbol 1 group, but corresponds to “black BAR” to “special figure bottom” of the symbol 1 group. There is no address storing the value, and the next address "1210(H)" is the address storing the value of the reel symbol data information of the symbol 2 group. In other words, since the drawings are drawings for facilitating the description, not all the data described in the drawings are stored in the ROM 54 (data and definitions described in “;//”). The data is not stored in ROM 54).

An address is provided for the content of ";//", and "0" is stored when data is stored. In that case, the reel symbol data information and table offset data (for example, “120D(H)” and “120E(H)”) described later are not necessary. Specifically, the symbol combination data (for specifying what the symbol combination having each symbol is) corresponding to each symbol in a predetermined order is stored. For example, in the symbol group 1, if the symbol combination data including “blue BAR” on the left reel 31 is the address “XXX0(H)”, the symbol combination data including “black BAR” on the left reel 31 is the address “XXX1”. (H)”,..., If the symbol combination data includes “special drawing” on the left reel 31, it may be the address “XXX8(H)” and symbol combination data including “special drawing lower” on the left reel 31. For example, like the address "XXX9(H)", the symbol combination data can be stored for each symbol group at intervals (10 addresses in this example) corresponding to the number of symbols. However, in this example, even when the data is “0”, it is stored in the ROM 54, so that the capacity of the ROM 54 increases, but the verification is easy when re-verifying from the data stored in the ROM 54. become.

Here, at each address of the # reel symbol combination table (TBL_PICCMB_#), for example, in the first reel symbol combination table (TBL_PICCMB_1) of FIG. 182, taking the group of symbols as an example, the first address “120D(H)” And the data stored in the D7 and D6 bits of "120E(H)" are referred to as "reel symbol data information".
The data stored in bits D5 to D0 of the address "120E(H)" is called "table offset".
Furthermore, the data stored at the address "120F(H)" is referred to as "symbol combination data".

First, the D0 to D7 bits of the address "120D(H)" and the D6 and D7 bits of the next address "120E(H)" correspond to reel symbol data information and correspond to 10 types of symbols.
In particular,
(1) Reel symbol data information of address "120D(H)" D7: Blue BAR
D6: Black BAR
D5: Red 7
D4: Replay D3: Bell A
D2: Bell B
D1: Watermelon D0: Cherry (2) Reel pattern data information of address "120E(H)" D7: On special drawing D6: Under special drawing.

And among the reel symbol data information, it means that the symbol data corresponding to the bit "1" is stored in the addresses following the addresses "120D(H)" and "120E(H)". For example, among the reel symbol data information stored at the addresses "120D(H)" and "120E(H)", only the D7 bit of the reel symbol data information stored at the address "120D(H)" is "1". It has become. Therefore, at the next address “120F(H)”, the symbol combination data (“blue BAR” data) for the D7 bit of the reel symbol data information at the address “120D(H)” is stored.

Further, the lower 6 bits (D0 to D5) of the data of the address "120E(H)" are the table offset value.
For example, the table offset value stored at the address “120E(H)” is “3(H)”. In the present embodiment, in order to facilitate understanding of the reel symbol data information and the table offset value, the reel symbol data information and the table offset value are described separately. For example, in the data of the address "120E(H)", the reel symbol data information is "00000000(B)" and the table offset value is "03(H)". Then, in the address "120E(H)", actually, data obtained by logically adding the reel symbol data information and the table offset value, that is, "00000011(H)" is stored.

The above reel symbol data information and reel symbol data information+table offset are the same for symbol groups 2 to symbol group 9. Furthermore, the same applies to each symbol 1 group to symbol 9 group of the second reel symbol combination table (TBL_PICCMB_2) (FIGS. 186 to 188) and the third reel symbol combination table (TBL_PICCMB_3) (FIGS. 190 to 192). ..

Here, the symbol 1 group of the first reel symbol combination table (TBL_PICCMB_1) shown in FIG. 182 will be described in more detail.
At the first address "120D(H)" D0 to D7 bits and at the next address (120E(H)) D6 and D7 bits, which symbol of the first (left) reel 31 is the symbol combination of the symbol 1 group It is shown whether it is a pattern that constitutes.
The symbol combination of symbol group 1,
RBA: "Blue BAR"-"Blue BAR"-"Black BAR"
RBB: "Blue BAR"-"Blue BAR"-"Red 7"
RBC: "Blue BAR"-"Blue BAR"-"Watermelon"
RBD: "Blue BAR"-"Blue BAR"-"Special drawing"
RBE: "Blue BAR"-"Blue BAR"-"Black BAR"
RBF: "Blue BAR"-"Black BAR"-"Red 7"
RBG: "Blue BAR"-"Black BAR"-"Watermelon"
RBH: "Blue BAR"-"Black BAR"-"Special drawing top"
(See FIG. 116).

Therefore, in the symbol combination of the symbol group 1, the symbols on the first (left) reel 31 are all “blue BAR”.
From this, the D7 bit of the address "120D(H)" corresponding to "blue BAR" is "1", and the other D6 to D0 bits are "0".
Similarly, the D7 and D6 bits of the address "120E(H)" are "0".
Further, the table offset value shown by the lower 6 bits of the address "120E(H)" indicates the numerical value up to the address of the next symbol group (in this example, the symbol group 2). The table offset value stored in the address "120E(H)" is "3(H)", but the address "1211(H)" obtained by adding "3(H)" to the address "120E(H)" is , The address storing the table offset of the second group of symbols.
Similarly, the address “1211(H)” stores the offset value “3(H)” up to the address storing the table offset of the symbol 3 group. That is, the address becomes “1211(H)”+“3(H)”=“1214(H)” (address storing table offset of symbol group 3).
Further, similarly, the address "1214 (H)" stores the offset value "8 (H)" up to the address where the table offset of the symbol 4 group is stored. That is, the address becomes “1214(H)”+“8(H)”=“121C(H)” (address storing the table offset of the group of symbols 4) (hereinafter, description will be omitted).

In this way, the first two addresses
First address: "blue BAR" to "cherry" reel symbol data information Next address: "special symbol upper" and "special symbol lower" reel symbol data information, and the table offset of the next symbol group is stored The offset value to the address is stored.
In this way, the "next address" stores two completely different data, that is, the reel symbol data information and the offset value up to the address at which the table offset of the next symbol group is stored. Since the corresponding bits of the data are different, the control processing is not hindered. If such a storage method is adopted, the capacity of the ROM 54 can be reduced.
When the number of symbols is 8 or less, the reel symbol data information is stored at "first address", and the offset value up to the address at which the table offset of the next symbol group is stored at "next address" is stored. You may. Further, when the number of symbols is 9 or more, the reel symbol data information is stored at the "first address", the reel symbol data information is also stored at the "next address", and further at the "next address". It is possible to employ various patterns such as storing the offset value up to the address where the table offset of the symbol group is stored (in this case, the total is 3 addresses).

Further, at the next address "120F(H)", symbol combination data for specifying what is the symbol combination having the symbol "blue BAR" on the first (left) reel 31 is stored. There is.
As described above, in the eight symbol combinations of the symbol group 1, the symbols on the first (left) reel 31 are all “blue BAR”. Therefore, "@SRB_A_H" (RBA to RBH) indicating the type of the combination in which the first (left) reel 31 is "blue BAR" is stored at the address "120F(H)".
As shown in FIG. 177, “@SRB_A_H” means an operating symbol related to all of the symbol group 1, and the value corresponding to this symbol is “11111111(B)”. Therefore, “11111111(B)” is actually stored in the address “120F(H)”.

Of the first reel symbol combination table, the symbol group 2 is also defined in the same manner as the symbol group 1.
Next, in the first reel symbol combination table, the symbol group 3 will be described.
First, the D7 to D0 bits of the address “1213(H)” and the D7 and D6 bits of the address “1214(H)” are
(1) Reel symbol data information at address "1213(H)" D7: "1" (blue BAR)
D6: "1" (black BAR)
D5: "0" (red 7)
D4: "1" (replay)
D3: "1" (Bell A)
D2: "0" (Bell B)
D1: "1" (watermelon)
D0: "0" (cherry)
(2) Reel symbol data information at address "1214(H)" D7: "1" (on special map)
D6: "0" (below special figure)
Has become.
Therefore, the symbols of the first (left) reel 31 among the symbols 3 groups (1BB or the symbol combinations of Replay 01 to Replay 07) are “blue BAR”, “black BAR”, “replay”, and “bell A”. , "Watermelon", or "on special map".

actually,
1BB: "Blue BAR"-"Blue BAR"-"Blue BAR"
Replay 01: "Replay"-"Blue BAR/Black BAR/Red 7/Special drawing"-"Bell A"
Replay 02: "Replay"-"Replay"-"Replay"
Replay 03: "Bell A"-"Red 7/Cherry"-"Replay/Bell B"
Replay 04: "Black BAR"-"Red 7/Cherry"-"Replay/Bell B"
Replay 05: "Special drawing"-"Replay"-"Bell A"
Replay 06: "Watermelon"-"Replay/Watermelon"-"Red 7/Watermelon/Special drawing/Black BAR"
Replay 07: "Replay"-"Replay"-"Bell A"
(See FIG. 116 and FIG. 117).

Then, in the reel symbol data information, symbol combination data corresponding to the bit (symbol) which is "1" is stored in the addresses after the address "1215(H)".
In particular,
(1) Reel symbol data information of address "1213 (H)" D7: "1" (blue BAR) → address "1215 (H)"
D6: “1” (black BAR) → address “1216 (H)”
D5: "0" (red 7) → no address (no pattern combination data)
D4: “1” (replay) → address “1217 (H)”
D3: “1” (bell A) → address “1218 (H)”
D2: "0" (Bell B) → no address (no pattern combination data)
D1: "1" (watermelon) → address "1219 (H)"
D0: "0" (cherry) → no address (no pattern combination data)
(2) Reel symbol data information of address "1214 (H)" D7: "1" (on special map) → address "121A (H)"
D6: "0" (below special drawing) → no address (no pattern combination data)
Has become.

First, in the address “1215 (H)”, symbol combination data for specifying a symbol combination in which the symbol of the first (left) reel 31 is “blue BAR” is stored. In the group of symbols 3, the symbol combination in which the symbol of the first (left) reel 31 is "blue BAR" is 1BB as described above, so "@1BB" is stored in the address "1215(H)". Has been done. As shown in FIG. 177, “@1BB” is “00000001(B)”, and the value is stored in the address “1215(H)”.
Next, at the address “1216 (H)”, symbol combination data for specifying a symbol combination in which the symbol of the first (left) reel 31 is “black BAR” is stored. In the symbol group 3, the symbol combination of the first (left) reel 31 is "black BAR" is Replay 04 as described above, so "@REP_04" is assigned to the address "1216(H)". Remembered As shown in FIG. 177, “@REP_04” is “00010000(B)”, and the value is stored in the address “1216(H)”.

Further, in the symbol group 3, since there is no symbol combination in which the symbol of the first (left) reel 31 is "red 7", the symbol combination in which the symbol of the first (left) reel 31 is "red 7" is No address is provided in which the symbol combination data for specifying is stored.
At the next address "1217 (H)", symbol combination data for specifying a symbol combination in which the symbol of the first (left) reel 31 is "replay" is stored. In the symbol group 3, the symbol combination in which the symbol of the first (left) reel 31 is “Replay” is Replay 01, Replay 02, and Replay 07 as described above, so the address “1217(H)” is , "@REP_01 OR @REP_02 OR @REP_07" is stored. As shown in FIG. 177, "@REP_01 OR @REP_02 OR @REP_07" is "00000010 (B)" OR "0000100 (B)" OR "10000000 (B)", so the address "1217 (H)" In the field, "1000110(B)" is stored.

At the next address "1218 (H)", symbol combination data for specifying the symbol combination in which the symbol of the first (left) reel 31 is "bell A" is stored. In the group of symbols 3, the symbol combination in which the symbol of the first (left) reel 31 is "bell A" is Replay 03 as described above, so "@REP_03" is assigned to the address "1218(H)". Remembered As shown in FIG. 177, “@REP_03” is “00001000(B)”, and the value is stored in the address “1218(H)”.
Further, in the symbol group 3, since there is no symbol combination in which the symbol of the first (left) reel 31 is "bell B", the symbol combination in which the symbol of the first (left) reel 31 is "bell B" is No address is provided in which the symbol combination data for specifying is stored.

At the next address "1219 (H)", symbol combination data for specifying a symbol combination in which the symbol of the first (left) reel 31 is "watermelon" is stored. In the group of symbols 3, the symbol combination in which the symbol of the first (left) reel 31 is "watermelon" is Replay 06 as described above, so "@REP_06" is stored in the address "1219(H)". Has been done. As shown in FIG. 177, "@REP_06" is "01000000(B)", so that value is stored in the address "1219(H)".

Further, since there is no symbol combination in which the symbol of the first (left) reel 31 is "cherry" in the symbol group 3, the symbol combination in which the symbol of the first (left) reel 31 is "cherry" is specified. The address where the symbol combination data for is stored is not provided.
At the next address "121A(H)", symbol combination data for specifying a symbol combination in which the symbol of the first (left) reel 31 is "on special symbol" is stored. In the symbol group 3, the symbol combination of the symbol of the first (left) reel 31 is "on special symbol" is the replay 05 as described above, so that the address "121A(H)" is "@REP_05". Is remembered. As shown in FIG. 177, “@REP_05” is “00100000 (B)”, and the value is stored in the address “121A (H)”.

Further, in the symbol group 3, since there is no symbol combination in which the symbol of the first (left) reel 31 is “special symbol lower”, the symbol combination in which the symbol of the first (left) reel 31 is “cherry” is selected. No address is provided in which the symbol combination data for specifying is stored.
As described above, reel symbol data information, reel symbol data information+table offset, and symbol combination data are also stored for other symbol groups.
Then, the first reel symbol combination table (TBL_PICCMB_1) is provided from addresses "120D(H)" to "1239(H)" (FIGS. 180 and 182 to 184).

FIG. 185 is a diagram showing a second reel symbol array table (TBL_PICARG_2), and is a diagram corresponding to FIG. 181 of the first reel 31. In FIG. 185, the reel symbol definition shown in FIG. 176 is also shown.
For example, when the second (middle) reel 31 is stopped, when the symbol stopped at the reference position (lower stage) is the first "cherry", the symbol stopped at the activated line is the second "watermelon" (Fig. 114 and FIG. 115).
In this case, when the first "cherry" stops at the reference position (lower row), the value corresponding to the symbol stopped on the activated line is determined by the address "123A(H)" by the program (flow chart) described later. It is configured to be specified as the value of the lower 4 bits. The lower 4 bits of the address "123A(H)" correspond to "@ZGR_07", that is, "watermelon" (see FIG. 114).
Further, when the second "watermelon" stops at the reference position (lower stage), the value corresponding to the symbol stopped on the activated line is specified to be the value of the upper 4 bits of the address "123B(H)". Is configured to. The upper 4 bits of the address "123B(H)" correspond to "@ZGR_02", that is, "black BAR".

186 to 188 are diagrams showing the second reel symbol combination table (TBL_PICCMB_2) and are diagrams corresponding to FIGS. 182 to 184 of the first reel 31.
In the second reel symbol combination table (TBL_PICCMB_2), the symbol group 4 of FIG. 187 will be described as an example.
D0 to D7 bits of the first address "1255 (H)" and D6 and D7 bits of the next address "1256 (H)", which symbol of the second (middle) reel 31 is a symbol combination of 4 groups of symbols It is shown whether it is a pattern that constitutes.
The symbol combination of the symbol 4 group,
Replay 08: "Special drawing"-"Replay"-"Replay"
Replay 09: "Bell A"-"Red 7/Cherry"-"Blue BAR/Special Figure"
Replay 10: "Replay"-"Red 7/Cherry"-"Bell B"
(See FIG. 117).

Therefore, in the symbol combination of the symbol group 4, the symbol of the second (middle) reel 31 is “replay”, “red 7”, or “cherry”.
From this, in the reel symbol data information of the address "1255 (H)", the D5 bit corresponding to "red 7", the D4 bit corresponding to "replay", and the D0 bit corresponding to "cherry" are "1". The other bits of the reel symbol data information are "0".
Further, from the address “1256(H)” in which the table offset of the symbol 4 group is stored, the address “125B(H)” in which the table offset of the symbol 5 group is stored is five, so that the address “1256”. The table offset value stored in “(H)” is “5(H)”.

In the group of symbols 4 there is no symbol combination in which the symbol of the second (middle) reel 31 is "blue BAR" or "black BAR", so the symbol of the second (middle) reel 31 is "blue BAR" or " There is no address where the symbol combination data for specifying the symbol combination of "black BAR" is stored.
At the first address "1257 (H)" following the address "1255 (H)" and the address "1256 (H)", the symbol combination in which the symbol of the second (middle) reel 31 is "red 7" is specified. The symbol combination data for is stored. In the group of symbols 4, the symbol combination of the symbol of the second (middle) reel 31 is "red 7" is Replay 09 and Replay 10, so the address "1257 (H)" is "@REP_09 OR @REP_10." Is remembered. As shown in FIG. 178, since "@REP_09" is "00000010(B)" and "@REP_10" is "00000100(B)", the address "1257(H)" is "00000110(B)". Is remembered.

At the next address "1258 (H)", symbol combination data for specifying the symbol combination in which the symbol of the second (middle) reel 31 is "replay" is stored. In the group of symbols 4, the symbol combination for which the symbol of the second (middle) reel 31 is "replay" is Replay 08, so "@REP_08" is stored in the address "1258 (H)". As shown in FIG. 178, since “@REP_08” is “00000001(B)”, the value is stored in the address “1258(H)”.
Next, in the group of symbols 4, since there is no symbol combination in which the symbol of the second (middle) reel 31 is "bell A", "bell B" or "watermelon", the symbol of the second (middle) reel 31 No address is provided in which the symbol combination data for specifying the symbol combination in which “Bell A”, “Bell B” or “Watermelon” is stored.

At the next address "1259 (H)", symbol combination data for specifying a symbol combination in which the symbol of the second (middle) reel 31 is "cherry" is stored. In the group of symbols 4, since the symbol combination in which the symbol of the second (middle) reel 31 is "cherry" is Replay 09 and Replay 10, the address "1259 (H)" is "@REP_09 OR @REP_10". Is remembered. As shown in FIG. 178, since "@REP_09" is "00000010(B)" and "@REP_10" is "00000100(B)", "000000110(B)" is assigned to the address "1259(H)". Is remembered.

Next, in the group of symbols 4, there is no symbol combination in which the symbol of the second (middle) reel 31 is "on special symbol", so the symbol of the second (middle) reel 31 is "on special symbol". There is no address where the symbol combination data for specifying the symbol combination is stored.
Further, since the "special drawing lower" does not exist on the second (middle) reel 31 (see FIG. 114), the symbol combination in which the symbol of the second (middle) reel 31 is "special drawing lower" is specified. The address where the symbol combination data for is stored is not provided.
As described above, the second reel symbol combination table (TBL_PICCMB_2) is composed of addresses “1244(H)” to “128E(H)” (FIGS. 180 and 186 to 188).

FIG. 189 is a diagram showing the third reel symbol array table (TBL_PICARG_3), and is a diagram corresponding to FIG. 181 of the first reel 31. In FIG. 189, the definition data of the reel symbol shown in FIG. 176 is also shown.
Then, for example, when the right (third) reel 31 is stopped, when the symbol stopped at the reference position (lower stage) is the first "replay", the symbol stopped at the activated line is also the first "replay" ( 114 and 115).
In this case, when the first "replay" is stopped at the reference position (lower stage), the value corresponding to the symbol stopped on the activated line by the program (flow chart) described later is the address "128F(H)". It is configured to be specified as the value of the lower 4 bits. The lower 4 bits of the address "128F(H)" correspond to "@ZGR_04", that is, "replay" (see FIG. 114).
Further, when the second "blue BAR" stops at the reference position (lower stage), the value corresponding to the symbol stopped on the activated line is specified to be the value of the upper 4 bits of the address "1290(H)". Is configured to be. The upper 4 bits of the address "1290(H)" correspond to "@ZGR_01", that is, "blue BAR".

In addition, as shown in FIGS. 181, 185, and 189, in the # reel symbol arrangement table, the symbol numbers specified by the head addresses are different.
Specifically, in the first address “1203(H)” of the first reel symbol array table, symbol data is stored starting from the second symbol. This is because when the control symbol number (BF_PICTURE) is "0", the symbol number of the symbol on the activated line on the left reel 31 becomes 2.
Further, at the head address “123A(H)” of the second reel symbol array table, symbol data is stored starting with the first symbol. This is because when the control symbol number (BF_PICTURE) is "0", the symbol number of the symbol on the activated line of the middle reel 31 becomes 1.
Furthermore, at the head address “128F(H)” of the third reel symbol array table, symbol data is stored starting from the 0th symbol. This is because when the control symbol number (BF_PICTURE) is “0”, the symbol number of the symbol on the activated line on the right reel 31 becomes 0.

In this way, the symbol data stored in the symbol array table is shifted as necessary (in consideration of the difference) and stored, so that the correction is performed for each acquired control symbol number (BF_PICTURE) ( It is not necessary to add or subtract the difference). Therefore, it becomes possible to obtain the symbol data on the activated line by a simple calculation based on the symbol number of the symbol stopped at the reference position (lower stage), simplifying the program processing and reducing the capacity of the ROM 54. You can
The order of the symbol data stored in the symbol array table of each reel 31 is determined according to the reference line and the activated line. The reference line (reference position) and the effective line can be freely determined. However, the reference line is preferably a horizontal line.
Here, the effective line of this embodiment is "upper left tier"-"middle middle tier"-"lower right tier" as shown in FIG. The reference line is "lower left"-"middle lower"-"lower right". Therefore, the difference is “+2” in the first reel symbol arrangement table, the difference is “+1” in the second reel symbol arrangement table, and the difference is “0” in the third reel symbol arrangement table. In other words, the difference indicates the amount of deviation (number of steps) between the position of the effective line and the reference position.
Therefore, for example, if the activated line is "left middle"-"middle middle"-"right middle", the difference in the symbol arrangement table of each reel 31 is "+1". In this case, the symbol array table of each reel 31 is sequentially stored from the symbol data of the first symbol. Further, for example, when the reference line is the middle line ("left middle stage"-"middle middle stage"-"right middle stage") and the valid line is "left middle stage"-"middle middle stage"-"right middle stage" The difference in the symbol arrangement table of each reel 31 is “0” (no difference). In this case, the symbol array table of each reel 31 is sequentially stored from the symbol data of the 0th symbol.
The above also applies to FIG. 228 (Example 1 of the 27th embodiment) described later.

On the other hand, as shown in FIG. 229 (Example 2 of 27th embodiment) described later, in each of the symbol array tables of the left reel 31, the middle reel 31, and the right reel 31, the symbol data of the symbol number “0” There is also a method of sequentially storing the difference data corresponding to each reel 31 from the beginning. Then, when acquiring the symbol data, the symbol data of the symbol on the activated line is acquired by adding or subtracting the difference data of the reel 31 to the symbol number of the symbol stopped at the reference position. In this case, even if there is a change in the effective line, only the difference data needs to be changed, so that the development man-hours can be reduced.

In FIG. 229 (Example 2 of 27th embodiment), the difference data corresponds to the value of the “difference” described above. That is, in the symbol array table of each reel 31, the difference data of the left reel 31 is “+2”, the difference data of the middle reel 31 is “+1”, and the difference data of the right reel 31 is “0”.
Therefore, similar to the above, when the reference line is "lower left"-"middle lower"-"lower right" and the valid line is "left middle"-"middle middle"-"right middle", The difference data of the symbol arrangement table of each reel 31 is "+1". Further, when the reference line is, for example, the middle line ("left middle stage"-"middle middle stage"-"right middle stage") and the valid line is "left middle stage"-"middle middle stage"-"right middle stage", for example. The difference data of the symbol arrangement table of each reel 31 is "0". In this case, it is not necessary to provide difference data, and the process of adding or subtracting difference data is also unnecessary.

FIGS. 190 to 192 are diagrams showing a third reel symbol combination table (TBL_PICCMB_3) and are diagrams corresponding to FIGS. 182 to 184 of the first reel 31.
In the third reel symbol combination table (TBL_PICCMB_3), the symbol group of FIG. 191 will be described as an example.
D0 to D7 bits of the first address "12B5 (H)" and D6 and D7 bits of the next address "12B6 (H)", which symbol on the third (right) reel 31 is a symbol combination of symbol group 5 It is shown whether it is a pattern that constitutes.
The symbol combination of the symbol group 5 is
Small Role 01: "Watermelon"-"Cherry"-"Bell A"
Small role 02: "Watermelon"-"Bell A"-"Blue BAR/Special drawing below"
Small role 03: "Bell A"-"Bell A"-"Bell A"
Small role 04: "Watermelon"-"Bell A"-"Bell A"
Small role 05: "Bell A"-"Replay"-"Blue BAR/Special drawing below"
Small role 06: "Bell A"-"Bell A"-"Blue BAR/Special drawing below"
Small role 07: "Watermelon"-"Cherry"-"Bell B"
Small role 08: "Watermelon"-"Bell A"-"Black BAR/Red 7/Watermelon/Special drawing"
(See FIG. 118).

Therefore, the symbols of the third (right) reel 31 in the symbol combination of the symbol group 5 are “bell A”, “blue BAR”, “special drawing lower”, “bell B”, “black BAR”, “red 7”. , "Watermelon" or "on special view".
From this, in the reel symbol data information of the address "12B5(H)", the D7 bit corresponding to "blue BAR", the D6 bit corresponding to "black BAR", the D5 bit corresponding to "red 7", " The D3 bit corresponding to "bell A", the D2 bit corresponding to "bell B", and the D1 bit corresponding to "watermelon" are "1".
Further, in the reel symbol data information of the address "12B6(H)", the D7 bit corresponding to "on special drawing" and the D6 bit corresponding to "below special drawing" are "1".
Furthermore, the address “12C0(H)” in which the table offset of the symbol 6 group is stored is 10 addresses ahead of the address “12B6(H)” in which the table offset of the symbol 5 group is stored, so the address “12B6 The table offset value stored in “(H)” is “0A(H)”.

Since there is no symbol combination in which the symbol of the third (right) reel 31 is "Replay" in the symbol group 5, the symbol combination in which the symbol of the third (right) reel 31 is "Replay" is specified. The address where the symbol combination data is stored is not provided.
Further, since the right reel 31 is not provided with "cherry" (see FIG. 114), the symbol combination data for specifying the symbol combination in which the symbol of the third (right) reel 31 is "cherry" is stored. Address is not provided.
First, in the first address "12B7(H)" following the addresses "12B5(H)" and "12B6(H)", a symbol combination in which the symbol of the third (right) reel 31 is "blue BAR" is specified. The symbol combination data for doing is stored. In the symbol group 5, the symbol combination in which the symbol of the third (right) reel 31 is "blue BAR" is small win 02, small win 05, and small win 06, so the address "12B7(H)" is , "@WIN_02 OR @WIN_05 OR @WIN_06" is stored. As shown in FIG. 178, "@WIN_02" is "00000010(B)", "@WIN_05" is "00010000(B)", and "@WIN_06" is "0010000(B)". "00110010(B)" is stored in the address "12B7(H)".

At the next address "12B8 (H)", symbol combination data for specifying a symbol combination in which the symbol of the third (right) reel 31 is "black BAR" is stored. In the symbol group 5, the symbol combination in which the symbol of the third (right) reel 31 is "black BAR" is the small role 08, so "@WIN_08" is stored in the address "12B8(H)". There is. As shown in FIG. 178, since “@WIN_08” is “10000000(B)”, the value is stored in the address “12B8(H)”.
At the next address "12B9 (H)", symbol combination data for specifying a symbol combination in which the symbol of the third (right) reel 31 is "red 7" is stored. In the symbol group 5, the symbol combination in which the symbol of the third (right) reel 31 is "red 7" is the small winning combination 08, so that the address "12B9(H)" is "10000000( B)” is stored.

At the next address "12BA(H)", symbol combination data for specifying a symbol combination in which the symbol of the third (right) reel 31 is "bell A" is stored. In the group of symbols 5, the symbol combination in which the symbol of the third (right) reel 31 is "bell A" is small win 01, small win 03, and small win 04, so the address "12BA(H)" is , "@WIN_01 OR @WIN_03 OR @WIN_04" is stored. As shown in FIG. 178, "@WIN_01" is "00000001(B)", "@WIN_03" is "00000100(B)", and "@WIN_04" is "00001000(B)". “00001011(B)” is stored in the address “12BA(H)”.

At the next address "12BB (H)", symbol combination data for specifying a symbol combination in which the symbol of the third (right) reel 31 is "bell B" is stored. In the group of symbols 5, the symbol combination in which the symbol of the third (right) reel 31 is "bell B" is the small role 07, so "@WIN_07" is stored in the address "12BB(H)". There is. As shown in FIG. 178, since “@WIN_07” is “01000000(B)”, the value is stored in the address “12BB(H)”.
At the next address "12BC(H)", symbol combination data for specifying a symbol combination in which the symbol of the third (right) reel 31 is "watermelon" is stored. In the symbol group 5, the symbol combination of the symbol of the third (right) reel 31 is "watermelon" is the small role 08, so "@WIN_08" is stored in the address "12BC(H)". .. As shown in FIG. 178, since “@WIN_08” is “10000000(B)”, the value is stored in the address “12BC(H)”.

At the next address "12BD(H)", symbol combination data for specifying the symbol combination in which the symbol of the third (right) reel 31 is "on special drawing" is stored. In the symbol group 5, the symbol combination in which the symbol of the third (right) reel 31 is “on special drawing” is the small winning combination 08, so that the address “12BD(H)” is the same as the address “12BC(H)”. “10000000(B)” is stored in “”.
At the next address "12BE(H)", the symbol combination data for specifying the symbol combination in which the symbol of the third (right) reel 31 is "under special drawing" is stored. In the symbol group 5, the symbol combination in which the symbol of the third (right) reel 31 is "special drawing lower" is small win 02, small win 05, and small win 06, so at the address "12BE(H)". "@WIN_02 OR @WIN_05 OR @WIN_06" is stored. As shown in FIG. 178, "@WIN_02" is "00000010(B)", "@WIN_05" is "00010000(B)", and "@WIN_06" is "0010000(B)". "00110010(B)" is stored in the address "12BE(H)".
As described above, the third reel symbol combination table (TBL_PICCMB_3) is composed of the addresses "1299(H)" to "12DE(H)" (FIGS. 180 and 190 to 192).

FIG. 193 is a diagram showing a payout amount table (TBL_WIN_CTL ). In the twenty-fifth embodiment, after the symbol combination to be stopped on the activated line is determined, in other words, the stop positions of all reels 31 are determined, and after the stop symbol data (_WK_STOP_PIC1 to 9) is updated, the symbol combination concerned It is determined using the payout number table whether or not to have the payout corresponding to.
First, “6” stored in the address “1400(H)” means the number of inspections. This means that whether or not to have a payout is inspected at most 6 times.
What are these 6 times?
1st time: Small Win 01 to Small Win 08 (15 pieces) (D0 to D7 of stop symbol data (fifth group))
Second time: Small winning combination 09 to Small winning combination 12 (15 pieces) (D0 to D3 of stop symbol data (6th group))
Third time: Small Win 13 to Small Win 16 (3) (D4 to D7 of stop symbol data (6th group))
4th time: Small winning combination 17 to small winning combination 24 (3 pieces) (D0 to D7 of stop symbol data (7th group))
Fifth time: Small combination 25 to small combination 32 (1 sheet) (D0 to D7 of stop symbol data (8th group))
Sixth time: Small winning combination 33 to small winning combination 34 (1 sheet) (D0 to D1 of stop symbol data (9th group))
Equivalent to.
In particular, in the stop symbol data (sixth group), the D0 to D3 bits (small win 09 to small win 12) and the D4 to D7 bits (small win 13 to small win 16) have different payout numbers, Inspect separately.

In the next address “1401 (H)”, the upper 3 bits (*32) indicate the number of transition bytes, and the lower 5 bits indicate the number of payouts. Here, since the upper 3 bits are "0*32", it is "000(B)", and the lower 5 bits are "01111(B)" because the payout number is "15(D)". Therefore, actually, "00001111(B)" is stored in the address "1401(H)".

The configurations of the number of transfer bytes and the number of payouts are the same for the addresses “1403(H)”, “1405(H)”, “1407(H)”, “1409(H)”, and “140B(H)”. .. For example, in "1407 (H)", the upper 3 bits (number of transition bytes) is "1*32", so it is "001 (B)", and the lower 5 bits (payout number) is "3 (D)". Since there is, it becomes “00011(B)”. Therefore, "00100011(B)" is stored in the address "1407(H)".

Here, the "number of transition bytes" means the number of transition bytes from the address of the stop symbol data. In this example, the initial value of the address of the stop symbol data is the address "F0BB(H)" of the stop symbol data (fifth group) (_WK_STOP_PIC5). Stop symbol data (1st group) (_WK_STOP_PIC1) to stop symbol data (4th group) (_WK_STOP_PIC4) is a payout combination (RB, 1BB, or replay), so whether or not to have a payout It does not become. Therefore, the initial value of the stop symbol data to be inspected is the address of the stop symbol data (fifth group). In the present embodiment, the payout process can be simplified by grouping the symbol groups of the winning combinations (small winning combinations) having the payout into the fifth group to the ninth group.
Therefore, for example, the number of transition bytes specified by the address “1401(H)” is “0”, but this is transition from the address “F0BB(H)” of the stop symbol data (fifth group) (_WK_STOP_PIC5 ). It means not to let.
Also, since the number of transition bytes designated by the address "1403(H)" is "1", "1" is added to the address "F0BB(H)" of the stop symbol data (fifth group) (_WK_STOP_PIC5). Then, the address to be inspected is "F0BC(H)" (stop symbol data (6th group) (_WK_STOP_PIC6)).

Furthermore, the "designated data" means bits (inspection data) corresponding to the symbol combination to be inspected. For example, since the address “1402(H)” is “@_PIC5”, it is “11111111(B)” as shown in FIG. 176.
In this case, the stop symbol data (fifth group) (_WK_STOP_PIC5) when all reels 31 are stopped, and the data stored in the address "1402(H)", that is, the inspection data "5" of the stop symbol data 11111111(B)”. Then, when the calculation result is "0", it is determined that there is no payout corresponding to the symbol combination of the fifth group. On the other hand, when the operation result is not "0", it is determined that there is a value stored in the lower 5 bits of the address "1401(H)", that is, "15" sheets are paid out.

At the next address “1403(H)”, the number of transfer bytes is “1” and the number of payouts is “15”. The designated data (address “1404(H)”) is “@WIN_09_12”. Therefore, as a result of the AND operation of the stop symbol data (sixth group) of the address “F0BC(H)” and “@WIN_09_12”, that is, “000011111(B)” (FIG. 178), when it is not “0”, 15 It means paying out the sheets.
As described above, the stop symbol data (sixth group) is the small winning combinations 09 to 16, but among these small winning combinations, the number of payouts of the small winning combinations 09 to 12 is 15 at the time of winning the prize. Since the number of payouts of the small prizes 13 to 16 at the time of winning is three, the small prizes 09 to 12 are the small prizes to be paid out of 15 at the address “1404(H)”. Is specified.

At the next address “1405 (H)”, the number of transfer bytes is “0” and the number of payouts is “3”. The designated data (address “1406(H)”) is “@WIN_13_16”. Therefore, as a result of the AND operation of the stop symbol data (sixth group) of the address “F0BC(H)” and “@WIN_13_16”, that is, “1110000(B)” (FIG. 178), it is 3 if not “0”. It means paying out the sheets.
As described above, at the addresses “1407(H)” to “140C(H)”, the number of bytes to be transferred, the acquired data, and the designated data are determined for the remaining small winning combination and the number of payouts.

Next, the control process (program) in the twenty-fifth embodiment will be described using a flowchart.
FIG. 194 is a flowchart showing the reel stop acceptance check (M_STOP_PIC). In the 25th embodiment, when the process proceeds to step S752 in FIG. 139 (the 23rd embodiment), the process proceeds to the flowchart in FIG. 194.
194, step S1013 is the same as step S792 of FIG. 146. Also, step S1014 is the same as step S793 of FIG. 146. Furthermore, step S1017 is the same as step S794 of FIG. 146.
Further, although not shown in FIG. 194, after step S1012, the process of step S791 of FIG. 146 (determination as to whether or not the waiting time has elapsed) is executed.

Here, the waiting process shown in step S791 of FIG. 146 is to set the waiting time when 1BB is tempted when the condition for permitting winning of 1BB is not established (steps S809 and S810 of FIG. 147). The judgment is whether or not the waiting time has elapsed.
On the other hand, the waiting time shown in step S1012 of FIG. 194 is a judgment as to whether or not the interrupt waiting process in step S1011 has been completed.
Further, in FIG. 194, when the process proceeds to the stop symbol set (M_STOPPIC_SET) in step S1024, the process of FIG. 195 is executed. However, the stop symbol set (M_STOPPIC_SET) of the twenty-fifth embodiment, in addition to the process of FIG. It is assumed that the processing of 195 is executed.

Although part of the description overlaps with the description of FIG. 146, the process of FIG. 194 will be described below.
The reel stop acceptance check (M_STOP_PIC) of FIG. 194 is a process of determining whether or not the stop switch 42 can accept a stop, and detecting an operation of the stop switch 42, shifts to a stop symbol setting process.
In step S1011 of FIG. 194, an interrupt waiting process is executed. The interrupt waiting process is the same as the process of step S239 in FIG. 39 (the eleventh embodiment). However, in the 25th embodiment, the interrupt cycle is “1.1175” ms, as in the 23rd embodiment. Then, in the next step S1012, it is determined whether or not the next interrupt has arrived (whether or not the waiting time for waiting for an interrupt has become “0”). When it is determined that the next interrupt has not arrived, this flowchart ends. On the other hand, after the interrupt waiting process is started in step S1011 and the next interrupt arrives, the process proceeds to step S1013.

By the interrupt waiting process, it is possible to prevent the plurality of reels 31 from stopping at the same time even when the plurality of stop switches 42 are simultaneously pressed. This is because the stop control is executed for one reel 31 by the processing of step S1015 and thereafter, and when the process returns to step S794, the rising data A is cleared by the interrupt waiting processing of step S1011.
Further, since the processing after step S1012 is executed all at once, it is possible to prevent the interrupt processing from being executed (hard to be executed) until the next interrupt waiting processing (step S1011). As a result, after the rising data A is first acquired in step S1016, an interrupt process is performed until the rising data A is acquired in step S1016, and the data acquired in the first step S1016 and the next step S1016 are processed. It is possible to prevent it from being different from the acquired data.

In step S1013, all motor index passage check is performed. Here, the following processing is executed.
(1) The first reel symbol number (for passing position) (_NB_RL1_PASPIC) (FIG. 135) is stored in the A register.
(2) An OR (logical sum) operation of the A register value and the second reel symbol number (for passing position) (_NB_RL2_PASPIC) (FIG. 136) is performed. Then, the calculation result is stored in the A register.
(3) An OR (logical sum) operation is performed between the A register value and the third reel symbol number (for passage position) (_NB_RL3_PASPIC) (FIG. 137). Then, the calculation result is stored in the A register.
(4) Add "1" to the A register value.

Here, the first reel symbol number (for passing position) (_NB_RL1_PASPIC), the second reel symbol number (for passing position) (_NB_RL2_PASPIC), and the third reel symbol number (for passing position) (_NB_RL3_PASPIC) is the # reel. Before the motor index is changed, it is "FF(H)", that is, "11111111(B)".
Therefore, if at least one data is "111111111(B)", the calculation result up to (3) above is "11111111(B)", and if "1" is added as shown in (4), it becomes "0". become. Therefore, before at least one reel 31 the # reel motor index is changed, the above calculation result is “0”, and after all the reels 31 are changed to the # reel motor index. The calculation result is a value other than "0".

When there is a change in the # reel motor index, the # reel symbol number (for the passing position) is set to “10 (D)” (at the time of rising) or “as shown in step S897 of FIG. 155. "0" (at the time of falling) is stored. Then, every time it is determined that one symbol has been moved, the #1 reel symbol number (for the passing position) is decremented. In this way, after the # reel motor index changes, the # reel symbol number (for passing position) is “0” (00000000(B)) to “19(D)” (00010011(B)). It will circulate. Therefore, after the # reel motor index is changed, the OR operation of (1) to (3) does not result in "11111111(B)".

Next, proceeding to step S1014, it is determined whether the stop acceptance of the stop switch 42 is possible. This determination is whether or not it is "0" (whether the zero flag is "1") in the calculation of (4) in step S1013. When it is "0" (the zero flag is "1"), it is determined that the stop acceptance of the stop switch 42 is not possible. In other words, the stop acceptance of the stop switch 42 is permitted when the # reel motor index changes for all reels 31.
When it is determined in step S1014 that the stop acceptance of the stop switch 42 is possible, the process proceeds to step S1015, and when it is determined that the stop acceptance of the stop switch 42 is not possible, the process proceeds to step S1021.

In step S1015, the first reel number and the first reel bit are set. Here, the following processing is executed.
(1) The address “F0AD(H)” of the reel stop flag (_FL_STOP_LP) is stored in the HL register.
(2) Store "00000001(B)" in the B register.
Here, the B register value is a value corresponding to the value of stop/control reel number data (_NB_STOP_REEL) (one of "1" (first reel 31) to "3" (third reel 31)).
(3) “00000001(B)” is stored in the C register.
Here, the C register value is a value corresponding to the stop switch 42. When the C register value is "00000001 (B)", it corresponds to the first (left) reel 31, when it is "00000010 (B)", it corresponds to the second (middle) reel 31, and "00000100 (B)". Corresponds to the third (right) reel 31.

Next, proceeding to step S1016, the input port rising data A (_PT_IN_A_UP) of the address “F017(H)” in FIG. 133 is acquired. Here, the value of the input port rising data A is stored in the A register.
In the next step S1017, it is determined whether or not the stop switch 42 has risen (whether or not the rise data of the stop switch 42 is ON).
Here, the following processing is executed.
(1) The data (reel stop flag (_FL_STOP_LP)) stored at the address (F0AD(H)) indicated by the HL register value is ANDed with the A register value (input port rising data A). .. The calculation result is stored in the A register value.
(2) An AND (logical product) operation is performed on the A register value and the C register value. The calculation result is stored in the A register value.

Here, for example, when the loop processing of steps S1016 to S1019 is the first time, the C register value is "00000001 (B)", so the rising data of the stop switch 42 corresponding to the first (left) reel 31 is A. Stored in register value.
When the loop processing is the second time, the C register value is updated to "00000010 (B)", and the rising data of the stop switch 42 corresponding to the second (middle) reel 31 is stored in the A register value. To be done.
Furthermore, when the loop processing is the third time, the C register value is updated to "00000100 (B)", and the rising data of the stop switch 42 corresponding to the third (right) reel is stored in the A register value. To be done.
Furthermore, in step S1019 of the third loop processing, the C register value is updated to "00001000 (B)", and it is determined that the processing of all reels 31 has been completed ("Yes" in step S1019).
(3) As a result of the calculation of (2) above, when it is determined that it is not “0” (zero flag≠“1”), it is determined that the stop switch 42 has risen, and the process proceeds to step S1022. On the other hand, when it is determined that the operation result is “0” (zero flag=“1”), it is determined that the stop switch 42 has not risen, and the process proceeds to step S1018.

In step S1018, the next reel number and reel bit are set. This process is a process of adding "1" to the B register value. Therefore, "00000001(B)" is updated to "00000010(B)" in the first loop of steps S1016 to S1019, and "00000010(B)" is changed to "00000011(B)" in the second loop. Will be updated.

Next, proceeding to step S1019, it is determined whether the processing has been completed for all reels 31.
Here, the following processing is executed.
(1) Perform a shift operation that shifts the C register value to the left by "1". Therefore, "00000001(B)" is updated to "00000010(B)" during the first loop, "00000010(B)" is updated to "00000100(B)" during the second loop, and the third loop is performed. Time is updated from "00000100(B)" to "00001000(B)".
(2) When the D3 bit of the C register value is "1", it is determined to be "Yes" (processing of all reels 31 is completed).
If "No" is determined in step S1019, the process returns to step S1016, and if "Yes" is determined, the process proceeds to step S1020.

In step S1020, the reel stop flag (_FL_STOP_LP) is acquired. At this point, since the address value of the reel stop flag is stored in the HL register (step S1015), the value stored at the address indicated by the HL register value is stored in the A register.
Next, proceeding to step S1021, the stop acceptance information data (_PT_STOP_STS) is stored. This process is a process of storing the A register value in the address “F01E(H)” (stop acceptance information data (_PT_STOP_STS)). By this processing, the value of the reel stop flag (_FL_STOP_LP) and the value of the stop acceptance information data (_PT_STOP_STS) become the same.
Then, the processing according to this flowchart is ended.

On the other hand, if it is determined in step S1017 that the stop switch 42 has risen and the process proceeds to step S1022, the stop switch 42 is accepted. Here, the following processing is executed.
(1) Update the reel stop flag (_FL_STOP_LP) with the latest information.
Here, the A register value (in step S1017, the reel stop flag (_FL_STOP_LP) and the input port rising data A are ANDed, and the operation result and the C register value are ANDed), and the reel stop flag ( _FL_STOP_LP) and XOR (exclusive OR) operation, store the result in the A register, and store the A register value in the reel stop flag (_FL_STOP_LP ).

For example, in step S1017,
Reel stop flag: 00000111 (B)
Input port rising data A:00000001(B)
When both are ANDed, the AND operation results in “00000001(B)”.
Furthermore, when the C register value is “00000001(B)”, the AND operation of the both results in “00000001(B)”.
Further, when this value and the reel stop flag "00000111 (B)" are XORed, it becomes "00000110 (B)". This value becomes the reel stop flag after updating.
(2) The stop/control reel number data (_NB_STOP_REEL) is updated to the latest information. This process is a process of storing the B register value in the stop/control reel number data.

Next, proceeding to step S1023, symbol combination control is executed. Here, the following processing is executed.
(1) Set the reel drive state (_WK_RL#_STS) (FIGS. 135 to 137) to “deceleration start”, that is, “4(D)”.
(2) The symbol number at the stop position is stored in the # reel symbol number (for stop position) (_NB_RL#_STPPIC) (FIGS. 135 to 137).
(3) The value obtained by subtracting “1” from the # reel symbol number (for stop position) (_NB_RL#_STPPIC) is stored in the A register value. When subtracting “1” from the symbol number “0”, the subtraction (special subtraction) is executed so as to be “19(D)” (maximum value of symbol number).
This process is an operation for obtaining the control symbol number (_BF_PICTURE) (lower stage) by subtracting "1" from the # reel symbol number (for stop position) (middle stage). At this point, the control symbol number is stored in the A register. For example, when the # reel symbol number (for stop position) is "4", "3" is stored as the control symbol number. Further, when the # reel symbol number (for stop position) is "0", "19" is stored as the control symbol number.
Then, the process proceeds to the stop symbol set (M_STOPPIC_SET) (FIG. 195) in step S1024.

In the example of FIG. 194, the reel stop control can be executed for one reel 31 even when the plurality of stop switches 42 are simultaneously pressed.
Here, “simultaneous pressing” refers to a case where the rising data of a plurality of (two in this example) stop switches 42 are turned on in the same interrupt process.
less than,
1. When the left and center stop switches 42 are simultaneously pressed while all reels 31 are rotating 1. 2. When the left reel 31 is stopped and the middle and right reels 31 are rotating, the middle and right stop switches 42 are simultaneously pressed. An example in which the left and middle stop switches 42 are simultaneously pressed when the left reel 31 is stopped and the middle and right reels 31 are rotating will be described.

1. When the left and middle stop switches 42 are simultaneously pressed while all the reels 31 are rotating, in FIG. 194, if “Yes” is determined in step S1014 and the process proceeds to step S1015, as described above,
(1) The address “F0AD(H)” of the reel stop flag (_FL_STOP_LP) is stored in the HL register.
(2) Store "00000001(B)" in the B register.
(3) “00000001(B)” is stored in the C register.

In the next step S1016, the value of the input port rising data A is stored in the A register. Here, when the left and center stop switches 42 are simultaneously pressed, the input port rising data A (A register value) is "00000011 (B)".
In the next step S1017, the following processing is executed.
(1) The data (reel stop flag (_FL_STOP_LP)) stored at the address (F0AD(H)) indicated by the HL register value is ANDed with the A register value (input port rising data A). .. The calculation result is stored in the A register value.
The reel stop flag (_FL_STOP_LP) at this time point is “00000111(B)”. Therefore, an AND operation of this value and the A register value "00000011 (B)" yields "00000011 (B)". The value after this calculation becomes the A register value.
(2) The A register value and the C register value are ANDed (logical product) and the operation result is stored in the A register value. Therefore, the AND operation result “00000001(B)” of the A register value “00000011(B)” and the C register value “00000001(B)” is set as the A register value.

Then, in step S1017, since it is not "0" as a result of the above calculation (zero flag ≠ "1"), it is determined that the stop switch 42 has risen, and the process proceeds to step S1022.
In step S1022, the reel stop flag (_FL_STOP_LP) is updated to the latest information.
Here, the A register value (00000001 (B)) and the reel stop flag (_FL_STOP_LP) (00000111 (B)) are XORed (exclusive OR), and the operation result “00000110 (B)” is registered in the A register. In the reel stop flag (_FL_STOP_LP).
Next, the B register value (00000001(B)) is stored in the stop/control reel number data.

As described above, when the left and middle stop switches 42 are simultaneously pressed during the rotation of all reels 31, the stop control of the left reel 31 corresponding to the operation of the left stop switch 42 is executed. In other words, the stop control of the middle reel 31 corresponding to the operation of the middle stop switch 42 is not executed at this timing.
Further, by the processing of step S1022, the reel stop flag (_FL_STOP_LP) is updated to data “00000110(B)” indicating that the left stop switch 42 has received “0”.
Furthermore, after the stop control of the left reel 31 is executed, when returning to step S752 again, generally, since one interrupt time has elapsed, the rising data A is cleared. However, even before one interrupt time has elapsed, when the process proceeds to step S752, the rising data A is cleared by steps S1011 and S1012. Therefore, unless the middle stop switch 42 is operated again, the middle reel The stop control of 31 is not executed.

2. When the left and right reels 31 are stopped and the middle and right reels 31 are rotating, the middle and right stop switches 42 are simultaneously pressed. In FIG. 194, it is determined as “Yes” in step S1014, and the process proceeds to step S1015. Going forward, as mentioned above,
(1) The address “F0AD(H)” of the reel stop flag (_FL_STOP_LP) is stored in the HL register.
(2) Store "00000001(B)" in the B register.
(3) “00000001(B)” is stored in the C register.

In the next step S1016, the value of the input port rising data A is stored in the A register. Here, since the middle and right stop switches 42 are simultaneously pressed, the input port rising data A (A register value) is "00000110 (B)".
In the next step S1017, the following processing is executed.
(1) The data (reel stop flag (_FL_STOP_LP)) stored at the address (F0AD(H)) indicated by the HL register value is ANDed with the A register value (input port rising data A). .. The calculation result is stored in the A register value.
The reel stop flag (_FL_STOP_LP) at this time point is “00000110 (B)”. Therefore, an AND operation of this value and the A register value “00000110 (B)” results in “00000110 (B)”. The value after this calculation becomes the A register value.
(2) The A register value and the C register value are ANDed (logical product) and the operation result is stored in the A register value. Therefore, the AND operation result “00000000(B)” of the A register value “000000110(B)” and the C register value “00000001(B)” is set as the A register value.

Then, in step S1017, since the result of the above calculation is "0" (zero flag="1"), it is determined that the stop switch 42 has not risen, and the process proceeds to step S1018.
In step S1018, "1" is added to the B register value. Therefore, the B register value is updated to "00000010(B)".
Next, proceeding to step S1019, it is determined whether the processing has been completed for all reels 31.
Here, first, a shift operation for shifting the C register value to the left by "1" is performed. Therefore, the C register value is updated to "00000010(B)".
Next, it is determined whether or not the D3 bit of the C register value is "1". Since it is not "1" here, it is determined as "No", and the process proceeds to step S1016.

In step S1016 of the second time, the value of the input port rising data A is stored in the A register. Therefore, the A register value becomes "00000110 (B)".
In the next step S1017, the following processing is executed.
(1) The data (reel stop flag (_FL_STOP_LP)) stored at the address (F0AD(H)) indicated by the HL register value is ANDed with the A register value (input port rising data A). .. The calculation result is stored in the A register value.
The reel stop flag (_FL_STOP_LP) at this time point is “00000110 (B)”. Therefore, an AND operation of this value and the A register value “00000110 (B)” results in “00000110 (B)”. This value becomes the A register value.
(2) The A register value “000000110 (B)” and the C register value “00000010 (B)” are ANDed (logical product) and the operation result is stored in the A register value. Therefore, the A register value is "00000010 (B)".

Then, in step S1017, since it is not "0" as a result of the above calculation (zero flag ≠ "1"), it is determined that the stop switch 42 has risen, and the process proceeds to step S1022.
In step S1022, the reel stop flag (_FL_STOP_LP) is updated to the latest information. In this processing, the A register value "00000010 (B)" and the reel stop flag (_FL_STOP_LP) value "00000110 (B)" are XORed (exclusive OR) and the operation result "0000100 (B)" is calculated. Is stored in the A register, and the A register value is stored in the reel stop flag (_FL_STOP_LP).
Next, the B register value (00000010 (B)) is stored in the stop/control reel number data.

As described above, when the left reel 31 is stopped and the middle and right stop switches 42 are simultaneously pressed while the middle and right reels 31 are rotating, the middle reel corresponding to the operation of the middle stop switch 42 The stop control of 31 is executed. In other words, the stop control of the right reel 31 corresponding to the operation of the right stop switch 42 is not executed at this timing.
By the processing of step S1022, the reel stop flag (_FL_STOP_LP) is updated to the data “00000100(B)” indicating that the left and middle stop switches 42 have received “0”.
Furthermore, after the stop control of the middle reel 31 is performed, when the process returns to step S752 again, the rising data A is cleared as described above, so unless the right stop switch 42 is operated again, the right reel 31 Stop control is not executed.

3. When the left reel 31 is stopped and the middle and right reels 31 are rotating, the left and middle stop switches 42 are simultaneously pressed. In FIG. 194, it is determined as “Yes” in step S1014, and the process proceeds to step S1015. When you proceed,
(1) The address “F0AD(H)” of the reel stop flag (_FL_STOP_LP) is stored in the HL register.
(2) Store "00000001(B)" in the B register.
(3) “00000001(B)” is stored in the C register.

In the next step S1016, the value of the input port rising data A is stored in the A register. Here, since the left and middle stop switches 42 are simultaneously pressed, the input port rising data A (A register value) is "00000011 (B)".
In the next step S1017, the following processing is executed.
(1) The data (reel stop flag (_FL_STOP_LP)) stored at the address (F0AD(H)) indicated by the HL register value is ANDed with the A register value (input port rising data A). .. The calculation result is stored in the A register value.
The reel stop flag (_FL_STOP_LP) at this time point is “00000110 (B)”. Therefore, an AND operation of this value and the A register value "00000011 (B)" yields "00000010 (B)". The value after this calculation becomes the A register value.
(2) The A register value and the C register value are ANDed (logical product) and the operation result is stored in the A register value. Therefore, the AND operation result “00000000(B)” of the A register value “00000010(B)” and the C register value “00000001(B)” is set as the A register value.

Then, in step S1017, since the result of the above calculation is "0" (zero flag="1"), it is determined that the stop switch 42 has not risen, and the process proceeds to step S1018.
In step S1018, "1" is added to the B register value. Therefore, the B register value is updated to "00000010(B)".
Next, proceeding to step S1019, it is determined whether the processing has been completed for all reels 31.
Here, first, a shift operation for shifting the C register value to the left by "1" is performed. Therefore, the C register value is updated to "00000010(B)".
Next, it is determined whether or not the D3 bit of the C register value is "1". Since it is not "1" here, it is determined as "No", and the process proceeds to step S1016.

In step S1016 of the second time, the value of the input port rising data A is stored in the A register. Therefore, the A register value becomes "00000011 (B)".
In the next step S1017, the following processing is executed.
(1) The data (reel stop flag (_FL_STOP_LP)) stored at the address (F0AD(H)) indicated by the HL register value is ANDed with the A register value (input port rising data A). .. The calculation result is stored in the A register value.
The reel stop flag (_FL_STOP_LP) at this time point is “00000110 (B)”. Therefore, an AND operation of this value and the A register value "00000011 (B)" yields "00000010 (B)". This value becomes the A register value.
(2) The A register value "00000010 (B)" and the C register value "00000010 (B)" are ANDed (logical product) and the operation result is stored in the A register value. Therefore, the A register value is "00000010 (B)".

Then, in step S1017, since it is not "0" as a result of the above calculation (zero flag ≠ "1"), it is determined that the stop switch 42 has risen, and the process proceeds to step S1022.
In step S1022, the reel stop flag (_FL_STOP_LP) is updated to the latest information. In this processing, the A register value "00000010 (B)" and the reel stop flag (_FL_STOP_LP) value "00000110 (B)" are XORed (exclusive OR) and the operation result "0000100 (B)" is calculated. Is stored in the A register, and the A register value is stored in the reel stop flag (_FL_STOP_LP).
Next, the B register value (00000010 (B)) is stored in the stop/control reel number data.

As described above, when the left reel 31 is stopped and the left and middle stop switches 42 are simultaneously pressed while the middle and right reels 31 are rotating, the middle reel corresponding to the operation of the middle stop switch 42 is operated. The stop control of 31 is executed. In other words, even if the left stop switch 42 corresponding to the left reel 31 that has already stopped is operated, the stop control of the left reel 1 is not executed.
By the processing of step S1022, the reel stop flag (_FL_STOP_LP) is updated to the data “00000100(B)” indicating that the left and middle stop switches 42 have received “0”.
As described above, even when the stop switches 42 are simultaneously pressed, only one reel 31 can be stop-controlled.

FIG. 195 is a flowchart showing a stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194.
This process is a process of updating the stop symbol data (_WK_STOP_PIC1 to 9) based on the reel 31 stopped this time.
In step S1031, the control symbol number (_BF_PICTURE) is saved. This process is a process of storing the A register value in the control symbol number (_BF_PICTURE). Here, the control register number (_BF_PICTURE) is stored in the A register value in step S1023 of FIG. 194.

In the next step S1032, the number of symbol groups is set. Since the symbol group of this embodiment includes the first group to the ninth group, this process is a process of storing “9” in the B register. Next, proceeding to step S1033, a reel symbol data set (M_PICDAT_SET) is executed. This process is a process shown in FIG. 196 which will be described later, and is a process of identifying any one address of the # reel symbol combination table (TBL_PICCMB_#) and acquiring the symbol combination data stored at the address. .. The symbol combination data obtained by this processing is stored in the A register.
After storing "9" in the B register in step S1032, the B register value is saved in the stack area before executing the next step S1033. Then, after executing the reel symbol data set (M_PICDAT_SET) in step S1033, the B register value saved in the stack area is restored. This is because in step S1033, the B register is newly used and the value stored in the B register is used again.

Next, proceeding to step S1034, the RWM address of the stop symbol data corresponding to the update target symbol group is set. Here, the following processing is executed.
(1) The address “F0B6(H)” before the “1” address of the stop symbol data (first group) (_WK_STOP_PIC1) is stored in the HL register.
(2) The B register value is added to the HL register value. Then, the addition result is set as the HL register value.

Here, since “9” is stored in the B register in step S1032, in the first step S1034,
HL register value=HL register value “F0B6(H)”+“9(H)”=“F0BF(H)”
And becomes the address of the stop symbol data (9th group) (_WK_STOP_PIC9). Further, in step S1036 described later, “1” is subtracted from the B register value, and steps S1033 to S1036 are repeated until the B register value becomes “0”. Thereby, from the stop symbol data (the ninth group) (_WK_STOP_PIC9) to the stop symbol data (the first group) (_WK_STOP_PIC1), the reel symbol data set (M_PICDAT_SET) is repeatedly executed.

In step S1035, the stop symbol data is saved. Here, the following processing is executed.
(1) An AND (logical product) operation of the A register value (the symbol combination data acquired in step S1033) and the data (stop symbol data (_WK_STOP_PIC)) stored at the address indicated by the HL register value is performed. Then, the calculation result is stored in the A register.
(2) The A register value is stored in the address indicated by the HL register value (stop symbol data (_WK_STOP_PIC). As a result, the stop symbol data (_WK_STOP_PIC) is updated.

Next, proceeding to step S1036, it is determined whether or not the processing for the number of symbol groups has been completed. Here, the following processing is executed.
(1) Subtract "1" from the B register value and set the subtraction result as the B register value.
(2) When the B register value is "0", it is determined to be "Yes" (the processing for the number of symbol groups has been completed), and this flowchart is ended. On the other hand, if it is determined to be "No" (the processing for the number of symbol groups has not been completed), the process returns to step S1033 to execute the reel symbol data set (M_PICDAT_SET) corresponding to the next symbol group.

FIG. 196 is a flowchart showing the reel symbol data set (M_PICDAT_SET) in step S1033 of FIG. 195.
As described above, the B register value is saved in the stack area before executing this flowchart.
The reel symbol data set is a process of acquiring symbol combination data corresponding to the symbol group of this time. For example, this process is
Stop/control reel number data (_NB_STOP_REEL) = "1" (first (left) reel)
Control symbol number (_BF_PICTURE) = "3" (symbol number that stops at the bottom)
Third group (B register value = "3")
Shall be
The following example describes the case where the process is performed under the above conditions,
Stop/control reel number data (_NB_STOP_REEL) = any one of "1", "2", "3" Control symbol number (_BF_PICTURE) = any of "0" to "19" B register value = "0" to " Also in the case of any of "9", the symbol combination data can be acquired by the same method.

As described above, when the control symbol number (_BF_PICTURE) is "3", the symbol number stopped on the activated line is "5", and the symbol is "replay".
In this case, the data "@REP_01 OR @REP_02 OR @REP_07" of the address "1217(H)" in FIG. 182, that is, "10000110(B)" is stored in the A register by the processing of the reel symbol data set. Becomes

196, in step S1041, stop/control reel number data is acquired. This process is a process of storing stop/control reel number data (_NB_STOP_REEL) in the A register.
In the next step S1042, the reel symbol search table address offset table (FIG. 180(A)) is set. This process is a process of storing the address "11FF(H)" obtained by subtracting "1" from the start address of the reel symbol search table address offset table (TBL_PIC_SRCH) in the HL register.
Next, proceeding to step S1043, table selection (R_TBL_SET) is executed. This process is a process shown in FIG. 197 described later. By this processing, in the HL register, the start address of the # reel symbol arrangement table (TBL_PICARG_#), specifically,
1203 (H): First address of first reel symbol array table (TBL_PICARG_1) 123A (H): First address of second reel symbol array table (TBL_PICARG_2) 128F (H): First address of third reel symbol array table (TBL_PICARG_3) Either value of address is stored.

Next, proceeding to step S1044, the control symbol number is acquired. This process is a process of storing the value stored in the control symbol number (_BF_PICTURE) in the A register.
In the next step S1045, 4-bit data acquisition (M_4BITDAT_GET) is executed. This process is a process shown in FIG. 198 described later. When this process is executed, the A register stores the symbol data corresponding to the symbols on the activated line.
In the next step S1046, the number of reel symbol data searches is set. This process is a process of storing the A register value (symbol data) in the C register value. The C register value storing the symbol data is used in the bit number count (M_BIT_COUNT) described later.

Next, proceeding to step S1047, the offset of the symbol combination table is set. This process is a process of storing "11(D)" in the A register value. For example, the start address of the first reel symbol array table (TBL_PICARG_1) is "1203(H)", but from this position, the address "120E(H)" at which the first table offset is stored is "11". Since there is an address, it is set to "11".

In the next step S1048, designated address data is set. Here, the following processing is executed.
(1) The A register value is added to the HL register value. Then, the addition result is set as the HL register value.
(2) The data stored at the address indicated by the HL register value is stored in the A register.
Here, if "1203 (H)" (start address of the first reel symbol array table (TBL_PICARG_1)) is stored in the HL register in step S1043,
HL register value=1203(H)+11(D)=120E(H)
Becomes
Therefore, the A register value is "00000011 (B)". As described above, in the data of the address “1203(H)”, the upper 2 bits are reel symbol data information and the lower 6 bits indicate the table offset value.

Next, proceeding to step S1049, the offset of the next symbol combination table is generated. In this processing, the AND (logical product) operation of the A register value and "00000011 (B)" is performed. Then, the calculation result is stored in the A register. As a result, for example, in the above example, the A register value becomes "00000011 (B)".
In the next step S1050, it is determined whether or not a symbol combination table of the number of symbol groups is acquired. In this process, "1" is subtracted from the B register value, and when the subtraction result is not "0", it is determined to be "No" (a symbol combination table of the number of symbol groups has not been acquired).
Here, the loop processing of steps S1048 to S1050 will be described by taking as an example the case where the HL register value is “120E(H)” and the B register value is “3” as in the above example.
(1) First time In step S1048,
HL register value=1203(H)+11(D)=120E(H)
Becomes
In step S1049,
A register value = 3 (H)
Becomes
In step S1050,
B register value = 3-1 = 2
Becomes
Therefore, it is determined as "No", and the process returns to step S1048.

(2) Second time In step S1048,
HL register value=120E(H)+3(D)=1211(H)
Becomes
In step S1049,
A register value =00000011 (B)
Becomes
In step S1050,
B register value=2-1=1
Becomes
Therefore, it is determined as "No", and the process returns to step S1048.

(3) Third time In step S1048,
HL register value=1121(H)+3(D)=1214(H)
Becomes
In step S1049,
A register value = 8 (H) (00001000 (B))
Becomes
In step S1050,
B register value = 1-1 = 0
Becomes
Therefore, it is determined to be “Yes”, and the process proceeds to step S step S1051.
As a result, the table offset “8 (H)” of the symbol 3 group is stored in the A register.
When the result is "Yes" in step S1050, the HL register value is saved in the stack area. The HL register value at this point is an address value that stores “reel symbol data information+table offset”.

In step S1051, the reel symbol combination table is corrected. This process is a process of subtracting "1" from the HL register value. So, for example, in the above example,
HL register value=1214(H)-1(H)=1213(H)
Becomes
Next, proceeding to step S1052, a bit number count (M_BIT_COUNT) is executed. This process is a process shown in FIG. 199, which will be described later, and is a process of counting how many bits are “1” in the reel symbol data information. For example, when the bit number is counted for the data "11011010(B)" at the address "1213(H)", it is counted as "5". After the execution of the bit number counting, the bit number is stored in the A register.
After the number of bits is counted in step S1052, the HL register value and the BC register value are restored from the stack area.

In the next step S1053, it is determined whether or not the inspection final bit is on. In this process, it is determined whether or not the carry flag is "1", and when the carry flag is "1", "Yes" is determined.
As will be described later in detail, in the bit number count (M_BIT_COUNT), the reel symbol data information is shifted to the left by "1" by the number corresponding to the symbol to be stopped this time, and "1" is set at the last left "1" shift. The carry flag is set to "1" when it comes out. For example, in the reel symbol data information “11011010 (B)” of the address “1213 (H)”, when the symbol to be stopped this time is “Replay”, four times corresponding to “Replay”, shift to the left by “1” To do. Therefore, in this case, the carry flag becomes "1" at the fourth left "1" shift.
If it is determined in step S1053 that the carry flag is not "1", the flow proceeds to step S1054, and if it is determined that the carry flag is "1", the flow proceeds to step S1055. In other words, in step S1053, it is determined whether or not there is a symbol combination including "replay" on the left reel 31 and belonging to the third group. In this case, when the carry flag is not "1", it is determined that the symbol combination is not present, and when the carry flag is "1", it is determined that the symbol combination is present.
In step S1054, reel symbol data is set. In this processing, an XOR (exclusive OR) operation between the A register value and the A register value is executed to set the A register value to "0". Then, the processing according to this flowchart is ended.

On the other hand, in step S1055, designated address data is set. Here, the following processing is executed.
(1) The A register value is added to the HL register value. The added result is set as the HL register value.
(2) The data stored at the address indicated by the HL register value is stored in the A register.
Here, the HL register value is a value saved when “Yes” in step S1050, and is an address storing reel symbol data information and table offset. As the A register value, the number of bits turned on in the bit number count of step S1052 is stored. For example, when the HL register value is "1214 (H)" and the A register value is "3 (H)", the HL register value is "1217 (H)".
Therefore, the data of the address "1217(H)" is "@REP_01 OR @REP_02 OR @REP_07", that is, "1000110(B)", and the value is stored in the A register.

FIG. 197 is a flowchart showing table selection (R_TBL_SEL) in step S1043 of FIG. 196.
In FIG. 197, in step S1061, designated address data is set. Here, the following processing is executed.
(1) The A register value is added to the HL register value. The added result is set as the HL register value.
(2) The data stored at the address indicated by the HL register value is stored in the A register.
In step S1042 of FIG. 196, “11FF(H)” is stored in the HL register. Further, the A register value is the value of the stop/control reel number data (_NB_STOP_REEL), and is any of "1", "2" or "3".
Therefore, the HL register value becomes either “1200 (H)”, “1201 (H)”, or “1202 (H)” by the processing of step S1061.
Further, by the processing of (2) above, any of the offset values shown in FIG. 180(A) is stored in the A register.

Next, proceeding to step S1062, the designated address is set. This process is a process in which the A register value is added to the HL register value and the addition result is used as the HL register value. For example, when the HL register value is "1200 (H)" and the A register value (offset value) is "3 (H)", the HL register value becomes "1203 (H)", and the first reel symbol array It is the start address of the table (TBL_PICARG_1). Further, when the HL register value is "1201 (H)" and the A register value (offset value) is "39 (H)", the HL register value becomes "123A (H)", and the second reel symbol It is the start address of the array table (TBL_PICARG_2). Furthermore, when the HL register value is “1202(H)” and the A register value (offset value) is “8D(H)”, the HL register value becomes “128F(H)”, and the third reel It becomes the top address of the symbol arrangement table (TBL_PICARG_3).
Then, the processing according to this flowchart is ended.

FIG. 198 is a flowchart showing the 4-bit data acquisition (M_4BITDAT_GET) in step S1045 of FIG. 196.
This process is a process of acquiring the symbol data of the symbols to be stopped on the activated line, using the # reel symbol arrangement table (TBL_PICARG_#) based on the control symbol number (_BF_PICTURE) corresponding to the symbols to be stopped.
For example, in the game in which it is determined that the symbol to be stopped on the activated line is “black BAR” on the basis of the stop operation reception of the left reel 31, the lower 4 of the address “1203 (H)” in FIG. The symbol data “@ZGR_02” corresponding to the bit data is acquired. As shown in the reel symbol definition in FIG. 181, "@ZGR_02" is symbol data corresponding to "black BAR". Also, "@ZGR_02" is, as shown in the reel symbol definition, the actual numerical value is "1 (H)".

In FIG. 198, the table offset is generated in step S1071. This process is a process for issuing an instruction to shift the A register value to the right by "1".
Here, before this processing, in step S1044 of FIG. 196, the control symbol number (_BF_PICTURE) is stored in the A register.
Therefore, if the A register value is, for example, "00000001(B)" (odd number), shift to the right by "1" changes the carry flag to "1". If the A register value is, for example, "00000010 (B)" (even number), shift to the right by "1" causes the carry flag to be "0". Furthermore, when the A register value is, for example, "00000011 (B)" (odd number), shift to the right by "1" changes the carry flag to "1".
Then, the value after “1” shift to the right is stored in the A register.

In the next step S1072, designated data is acquired. This process is a process of storing in the A register the data stored at the address obtained by adding the A register value to the HL register value.
Here, the start address of the # reel symbol arrangement table (TBL_PICARG_#) is stored in the HL register in step S1043 (FIG. 197) of FIG. 196. The A register value is a value obtained by shifting the control symbol number (_BF_PICTURE) to the right by "1". Therefore, when the HL register value is, for example, “1203(H)” (see FIG. 181) and the A register value is, for example, “1” (control symbol number (_BF_PICTURE) is “3”), A after calculation is calculated. The register value becomes the data of the address of “1204 (H)”, that is, “@ZGR_05*16+@ZGR_04”.
Here, as shown in FIG. 181, "@ZGR_05" (upper 4 bits) is "0100 (B)" (4 (H)), and "@ZGR_04" (lower 4 bits) is "0011 (B)". (3(H)), the A register value is “0100/0011(B)”.

In the next step S1073, it is determined whether the table data search number is an odd number. This process determines whether the carry flag is "1" by the process of step S1071, and when the carry flag is "1", it is determined to be an odd number. If it is determined that the table data search number is an odd number, the process proceeds to step S1075, and if it is determined that the table data search number is not an odd number, the process proceeds to step S1074.
In step S1074, even-numbered data is acquired. This process is a process for exchanging the upper 4 bits and the lower 4 bits of the data (A register value) acquired in step S1072.
For example, when the A register value is "0100/0011(B)" as in the above example, when the process of step S1074 is executed, it becomes "0011/0100(B)".

In step S1075, designated data is generated. This process is a process of executing an AND (logical product) operation of the A register value and "00001111(B)" and storing the operation result in the A register value. By this processing, the upper 4 bits are masked.
For example, when the A register value is "01000011 (B)" as described above, an AND (logical product) operation of this value and "000011111 (B)" is executed, and the A register value is "00000011 (B)". )”
Then, the processing according to this flowchart is ended.

FIG. 199 is a flowchart showing the bit number count (M_BIT_COUNT) in step S1052 of FIG. 196.
Here, immediately before the processing of counting the number of bits, the HL register value is the data updated in step S1051 of FIG. 196, and the start address value of the reel symbol data information (for example, in the case of the first group of the left reel 31). 182, "120D(H)").
Further, the C register value is the 4-bit data acquired by the 4-bit data acquisition of step S1045 by the process of step S1046 of FIG. 196.

In FIG. 199, in step S1081, the number of inspections is set. This process is a process of adding "1" to the C register value and setting the addition result as the C register value.
In the next step S1082, "0" is set as the initial value of the number of ON bits. This process is a process of setting the A register value to “0” by performing an XOR (exclusive OR) operation of the A register value and the A register value.
Next, proceeding to step S1083, the number of times of processing is set. This process is a process of storing "8" in the B register. Here, “8” is a value corresponding to the number of bits.

In the next step S1084, inspection data is acquired. This process is a process of storing the data stored in the address indicated by the HL register value in the D register. Therefore, the D register value becomes reel symbol data information.
Next, in step S1085, it is determined whether the bit is on. Here, the following processing is executed.
(1) An operation for shifting the D register value to the left by "1" is performed.
(2) As a result of the above calculation, when the carry flag is "1", it is determined to be "Yes".

If it is determined in step S1085 that the bit is on, the process proceeds to step S1086, and if it is determined that the bit is not on, the process proceeds to step S1087.
In step S1086, "1" is added to the number of ON bits. This process is a process of adding "1" to the A register value.
In the next step S1087, "1" is subtracted from the number of inspections. This process is a process of subtracting "1" from the C register value and setting the subtraction result as the C register value.
Next, in step S1088, it is determined whether or not the inspection is to be ended. This processing determines whether the C register value is "0" (whether the zero flag is "1"). When it is determined that the C register value is “0” (zero flag is “1”), it is determined that the inspection is ended, and the processing according to this flowchart is ended.
On the other hand, when it is determined that the inspection is not finished, the process proceeds to step S1089.

In step S1089, it is determined whether the number of processing times has been completed. In this processing, "1" is subtracted from the B register value, it is determined whether the result of the subtraction is "0", and when it is determined that it is "0", it is determined that the number of times of processing has been performed. If it is determined that the number of processes has not been completed, the process advances to step S1085. On the other hand, if it is determined that the processing count has been completed, then the flow proceeds to step S1090.
In step S1090, "1" is added to the HL register value, and the added value is set as the HL register value. Then, the process proceeds to step S1083.

The above bit number counting process will be described using a specific example.
Note that, although an example will be described below, the process can be executed in the same manner as described below regardless of the number of groups of symbols on any reel 31.
In this example,
HL register value = 1213 (H) (3 groups of symbols on the first reel 31)
C register value=3 (replay) (“4” in step S1081)
Shall be
in this case,
(1) First time step S1083: B register value=8 (initial value)
Step S1084: D register value "11011010 (B)" (symbol data stored at address "1213 (H)")
Step S1085: shift the D register value to the left by "1", carry flag=1, so "Yes"
Step S1086: A register value=0+1=1
Step S1087: C register value=4-1=3
Step S1088: Zero flag≠1, therefore “No”
Step S1089: B register value=8-1=7, so “No”
(2) Second time Step S1085: Shift the D register value to the left by "1", carry flag=1, so "Yes"
Step S1086: A register value=1+1=2
Step S1087: C register value=3-1=2
Step S1088: Zero flag≠1, therefore “No”
Step S1089: B register value=7-1=6, so “No”
(3) Third time Step S1085: shift the D register value to the left by "1", carry flag≠1, and thus "No"
Step S1087: C register value=2-1=1
Step S1088: Zero flag≠1, therefore “No”
Step S1089: B register value=6-1=5, so “No”
(4) Fourth time Step S1085: shift the D register value to the left by "1", carry flag=1, and thus "Yes"
Step S1086: A register value=2+1=3
Step S1087: C register value=1-1=0
Step S1088: Zero flag=1, so “Yes” (end of processing)
Becomes

In this case, when the counting of the number of bits is completed and the process proceeds to step S1053 in FIG. 196, since the carry flag is "1", the process proceeds to step S1055.
In step S1055,
HL register value=HL register value “1214(H)”+A register value “3(H)”=1217(H)
A register value=data of address “1217(H)” indicated by HL register value=@REP_01 OR @REP_02 OR @REP_07 (10000110(B))
Becomes
As described above, in the bit number counting, when the stop symbol is determined, the symbol combination data of the Nth group of the # reel 31 corresponding to the stop symbol is specified.

Subsequently, when each stop switch 42 is operated, how the stop symbol data (_WK_STOP_PIC) is updated by the stop symbol set (M_STOPPIC_SET) shown in FIG. 195 will be described with a specific example.
In the explanation below,
1. Example of non-winning role 1-1. When the left stop switch 42 is stopped 1-2. During stop operation of the middle stop switch 42 1-3. When the right stop switch 42 is stopped. Example of winning a special role (RBA) 2-1. When the left stop switch 42 is stopped 2-2. When the middle stop switch 42 is stopped 2-3. When the right stop switch 42 is stopped. Example of winning replay (Replay 01) 3-1. At the time of stop operation of the left stop switch 42 3-2. During stop operation of the middle stop switch 42 3-3. When the right stop switch 42 is stopped 4. Example of winning a small role (when pressing the correct answer in the pressing order bell) 4-1. During stop operation of the left stop switch 42 4-2. At the time of stopping operation of the middle stop switch 42 4-3. 4. When the right stop switch 42 is stopped. Example of winning a small role (incorrect answer in push order when push order bell is won) 5-1. At the time of stop operation of the right stop switch 42 5-2. During stop operation of the middle stop switch 42 5-3. A description will be given in order of the stop operation of the left stop switch 42.

1. At the time of non-winning of the winning combination In this example, as a result of the winning combination lottery, the winning number "26" is determined, and when the symbol of the symbol number "18" is passing through the middle of the left reel 31, a left stop is made. The switch 42 is operated, and then the middle stop switch 42 is operated when the symbol of the symbol number “17” is passing through the middle stage of the middle reel 31, and then the middle stage of the right reel 41 is changed to the symbol number “19”. By operating the stop switch 42 while the symbol is passing,
Symbol control number (_BF_PICTURE ): 1 (watermelon) when the left reel 31 is stopped
Symbol control number (_BF_PICTURE ): 0 (bell A) when the middle reel 31 is stopped
Symbol control number (_BF_PICTURE ): 2 (blue BAR) when the right reel 31 is stopped
Shall stop respectively.
In this case, the symbol combination on the activated line is “black BAR (3rd)”-“cherry (1st)”-“blue BAR (2nd)”, and the winning combination is not won.
Also, the initial value of the stop symbol data (_WK_STOP_PIC) is
Stop symbol data (first group) (_WK_STOP_PIC1 ): "11111111(B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): “11111111(B)”
Stop symbol data (third group) (_WK_STOP_PIC3 ): "11111111(B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00001111 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "11111111(B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): “11111111(B)”
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "11111111(B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "11111111(B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000011 (B)"
Is.

1-1. At the time of stop operation of the left stop switch 42 In the stop symbol set of FIG. 195, in step S1031, "1" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
(First time)
By the processing of step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that there is no "black BAR" in the symbol group 9 of the left reel 31 (see address "1236(H)").
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) at the address indicated by the HL register value (initial value is “00000011(B)”). As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

(Second time)
By the processing of step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "black BAR" does not exist in the symbol group 8 of the left reel 31 (see address "1230(H)").
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed on the A register value “00000000(B)” and the data (_WK_STOP_PIC8) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

(3rd time)
By the processing of step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "black BAR" does not exist in the symbol group 7 of the left reel 31 (see address "122B(H)").
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed on the A register value “00000000(B)” and the data (_WK_STOP_PIC7) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

(4th time)
By the process of step S1033, the symbol combination data “01000000(B)” (@WIN_15) of the address “1226(H)” is stored in the A register. This means that the small winning combination 15 exists as "black BAR" in the symbol group 6 of the left reel 31.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01000000(B)” and the data (_WK_STOP_PIC6) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "01000000 (B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

(5th time)
By the process of step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "black BAR" does not exist in the symbol group 5 of the left reel 31 (see address "1220(H)").
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

(6th time)
By the process of step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that there is no "black BAR" in the symbol group 4 of the left reel 31 (see the address "121B(H)").
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed on the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (initial value is “00001111(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

(7th time)
By the processing in step S1033, the symbol combination data “00010000(B)” (@REP_04) of the address “1216(H)” is stored in the A register. This means that the replay 04 exists as "black BAR" in the symbol group 3 of the left reel 31.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00010000(B)” and the data (_WK_STOP_PIC3) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00010000 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

(8th time)
In step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "black BAR" does not exist in the symbol group 2 of the left reel 31 (see address "1210(H)").
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

(9th time)
In step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "black BAR" does not exist in the symbol 1 group of the left reel 31 (see address "120D(H)").
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the left stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00010,000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "01000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, when the "black BAR" is stopped on the activated line when the left stop switch 42 is stopped, there is a possibility of stopping the symbol combination of the symbol 3 group or the symbol 6 group, but of the other symbol groups. It can be seen that there is no possibility of stopping the symbol combination.

Next, during the stop symbol set in FIG. 195, the reel symbol data set (FIG. 196) in step S1033 will be described with an example.
Of the above, the fourth step S1033 (group of symbols 6) will be taken as an example. The B register value in this case is "6".
196, in step S1041, stop/control reel number data (_NB_STOP_REEL), that is, "1" is stored in the A register.
In the next step S1042, “11FF(H)” is stored in the HL register.
Next, proceeding to step S1043, table selection (R_TBL_SET) is executed. By this processing, the head address "1203 (H)" of the first reel symbol array table (TBL_PICARG_1) is stored in the HL register.

Next, proceeding to step S1044, the control symbol number (_BF_PICTURE), that is, "1" is stored in the A register.
In the next step S1045, 4-bit data acquisition (M_4BITDAT_GET) is executed. By this processing, the symbol data “00000001(B)” corresponding to “black BAR” is stored in the A register.
In the next step S1046, the A register value (symbol data) is stored in the C register value. Therefore, the C register value is “00000001(B)”.

Next, proceeding to step S1047, "11(D)" (offset value) is stored in the A register value.
In the next step S1048, HL register value=“1203(H)” (first reel symbol array table (TBL_PICARG_1) start address)+“11(D)” (offset value)=“120E(H)” ..
Further, the A register value becomes the table offset value of the lower 6 bits of the data of the address “120E(H)” and becomes “00000011(B)”.

In the next step S1049, an AND (logical product) operation of the A register value and "00000011(B)" is performed, and the operation result is stored in the A register. As a result, the A register value becomes "00000011 (B)".
In the next step S1050, "1" is subtracted from the B register value, and when the subtraction result is not "0", it is determined to be "No" (the symbol combination table of the number of symbol groups has not been acquired).
Here, at the first point,
HL register value=120E(H)
B register value = 6
Is.
Therefore, the loop processing of steps S1048 to S1050 is as follows.
(First time)
HL register value=120E(H)
A register value = 3 (H)
B register value = 6-1 = 5 (determined as "No" and returns to step S1048)
(Second time)
HL register value=120E(H)+3(D)=1211(H)
A register value = 3 (H)
B register value=5-1=4 (determined as “No”, and returns to step S1048)
(3rd time)
HL register value=1121(H)+3(D)=1214(H)
A register value = 8 (H) (00001000 (B))
B register value = 4-1 = 3 (determined as "No" and returns to step S1048)

(4th time)
HL register value=1214(H)+8(D)=121C(H)
A register value = 5 (H) (00001000 (B))
B register value = 3-1 = 2 (determined as "No" and returns to step S1048)
(5th time)
HL register value=121C(H)+5(D)=1221(H)
A register value = 4 (H)
B register value=2-1=1 (determined as “No” and returns to step S1048)
(6th time)
HL register value = 1221 (H) + 4 (D) = 1225 (H)
A register value = 7 (H)
B register value=1−1=0 (determined as “Yes”, and proceeds to step S1051)

Here, the HL register value “1225(H)” is saved in the stack area.
In step S1051, the HL register value=“1225(H)”−“1(H)”=“1224(H)”.
In step S1052, a bit number count (M_BIT_COUNT) is executed. Here, the number of bits is counted for the data "01111010(B)" at the address "1224(H)". In this example, since it is counted as "1", the A register value becomes "1".
Then, the HL register value and the BC register value are restored from the stack area.

In the next step S1053, since the carry flag is "1", it is determined to be "Yes".
In step S1055, the data stored in the address indicated by the value "1226 (H)" obtained by adding the A register value "1" to the HL register value "1225 (H)" is stored in the A register.
Therefore, the data "@WIN_15" of the address "1226 (H)", that is, "01000000 (B)" is stored in the A register.
The A register value "01000000(B)" is then ANDed with the initial value "11111111(B)" stored in the stop symbol data (sixth group) (_WK_STOP_PIC6) in the stop symbol set (_M_STOPPIC_SET). (Logical product) is calculated. Thereby, the data of the stop symbol data (sixth group) (_WK_STOP_PIC6) is updated from "11111111(B)" to "01000000(B)".

Next, in the above example, a specific example of 4-bit data acquisition (M_4BITDAT_GET) (FIG. 198) in step S1045 will be described.
Before this process,
A register = 1 (control symbol number (_BF_PICTURE))
HL register = 1203 (H) (start address of first reel symbol array table (TBL_PICARG_1))
Has become.
In FIG. 198, in step S1071, the A register value is shifted to the right by "1". As a result, the carry flag becomes "1". Further, the A register value becomes "00000000(B)".

In step S1072, the data stored in the address obtained by adding the A register value to the HL register value is stored in the A register. Since the HL register value is “1203(H)” and the A register value is “0”, the A register value after calculation is the data “@ZGR_08*16 + @ZGR_02” of the address “1203(H)”, that is, It becomes "0111/0001 (B)".
In step S1073, since the carry flag is "1" by the above calculation, the process proceeds to step S1075.
In step S1075, an AND (logical product) operation of the A register value and "00001111(B)" is executed. As a result, the A register value becomes "0000/0001 (B)", and the symbol data "00000001 (B)" corresponding to "black BAR" is stored.

Next, in the above example, a specific example of the bit number count (M_BIT_COUNT) (FIG. 199) in step S1052 of FIG. 196 will be described.
Immediately before counting the number of bits,
HL register=1224 (H) (data updated in step S1051 in FIG. 196)
C register =00000001 (B) (symbol data acquired in 4-bit data acquisition (step S1045) in FIG. 196)
Has become.
In FIG. 199, in step S1081, "1" is added to the C register value, and the addition result is set as the C register value. As a result, the C register value becomes "2".
In step S1082, the A register value is set to "0".
In step S1083, “8” is stored in the B register.

In step S1084, the data stored at the address indicated by the HL register value “1224(H)” is stored in the D register. Therefore, the D register value becomes "01111010(B)".
In step S1085, the D register value is shifted to the left by "1". As a result, the carry flag is "0", so "No" is determined and the process proceeds to step S1087.
In step S1087, "1" is subtracted from the C register value. As a result, the C register value becomes "1".
In step S1088, the C register value is not "0", so "No" is determined, and the flow advances to step S1089.
In step S1089, "1" is subtracted from the B register value. As a result, the B register value becomes "7" and is not "0", and therefore the process returns to step S1085.

In step S1085, the D register value is shifted to the left by "1". Since the carry flag is "1", it is determined to be "Yes".
Therefore, the process advances to step S1086 to add "1" to the A register value. As a result, the A register value becomes "1".
In step S1087, "1" is subtracted from the C register value. As a result, the C register value becomes "0".
The process proceeds to step S1088, and since the C register value is "0", it is determined to be "Yes", and the process according to this flowchart ends.
When proceeding to step S1053 in FIG. 196, it is determined that the inspection last bit is on, and the process proceeds to step S1055.
In step S1055, designated address data is set.
Here, the value "1226 (H)" obtained by adding the A register value "1" to the HL register value "1225 (H)" returned from the stack area is set as the HL register value and stored at the address indicated by the HL register value. The stored data is stored in the A register. Therefore, the A register value becomes the data of the address “1226(H)”, that is, “01000000(B)”.

1-2. During stop operation of the middle stop switch 42 During stop operation of the middle stop switch 42, as described above,
Design control number (_BF_PICTURE ): 0 (bell A)
Design that stops on the activated line: "Cherry (No. 1)"
Shall be
Also, the stop symbol data (_WK_STOP_PIC) at this point is as described above.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00010,000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "01000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
Is.

In this case, when the middle reel 31 is stopped, the processing proceeds as follows.
In FIG. 195, in step S1031, “0” is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, the A register stores the symbol combination data “00000001(B)” of the address “128E(H)”.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000001(B)" and the data (_WK_STOP_PIC9) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol register data “00110000(B)” of the address “1289(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, the AND operation is performed between the A register value “00110000(B)” and the data (_WK_STOP_PIC8) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “00000010(B)” of the address “127F(H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000010(B)” and the data (_WK_STOP_PIC7) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 for the fourth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "cherry" does not exist in the symbol group 6 of the middle reel 31 (see address "125F(H)").
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed with the A register value “00000000(B)” and the data (_WK_STOP_PIC6) (“01000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 of the fifth time, the symbol combination data “01000001(B)” of the address “125E(H)” is stored in the A register.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, the AND operation is performed between the A register value “01000001(B)” and the data (_WK_STOP_PIC5) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, the symbol combination data “0000110 (B)” of the address “1259 (H)” is stored in the A register.
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000110 (B)" and the data (_WK_STOP_PIC5) ("00000000 (B)") at the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “00011000(B)” of the address “1253(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed on the A register value “00011000(B)” and the data (_WK_STOP_PIC3) (00010000(B)” at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00010000 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "cherry" does not exist in the symbol group 2 of the middle reel 31 (see address "1248 (H)").
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 of the ninth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "cherry" does not exist in the symbol 1 group of the middle reel 31 (see address "1244(H)").
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the middle stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00010,000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, when "black BAR" is stopped on the activated line when the left reel 31 is stopped, and when "watermelon" is stopped on the activated line when the middle reel 31 is stopped, the symbol combination corresponding to Replay 04 It turns out that it has the possibility of stopping.

1-3. At the time of stop operation of the right stop switch 42 At the time of stop operation of the right stop switch 42, as described above,
Design control number (_BF_PICTURE ): 2 (blue BAR)
Design that stops on the effective line: "Blue BAR (No. 2)"
Shall be
In this case, when the right stop switch 42 is stopped, the process proceeds as follows.
In FIG. 195, in step S1031, “2” is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 for the first time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 9 of the right reel 31 (see address "12DA(H)").
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 for the second time, the symbol combination data “10001010(B)” of the address “12D3(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “10000110(B)” and the data (_WK_STOP_PIC8) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “00011010(B)” of the address “12CA(H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00011010(B)" and the data (_WK_STOP_PIC7) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 of the fourth time, the symbol combination data “10000000(B)” of the address “12C1(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "10000000(B)" and the data (_WK_STOP_PIC6) ("01000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 of the fifth time, the symbol combination data “00110010(B)” of the address “12B7(H)” is stored in the A register.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00110010(B)” and the data (_WK_STOP_PIC5) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, the symbol combination data “00000010(B)” of the address “12B1(H)” is stored in the A register.
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000010(B)” and the data (_WK_STOP_PIC5) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “00000001(B)” of the address “12A7(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000001(B)" and the data (_WK_STOP_PIC3) ("00010000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000000(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 2 of the right reel 31 (see address "129F(H)").
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 of the ninth time, “00000000(B)” is stored in the A register (symbol combination data). This means that “blue BAR” does not exist in the symbol group 1 of the right reel 31 (see address “1299(H)”).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the right stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, when the left reel 31 is stopped, "black BAR" is stopped on the effective line, when the middle reel 31 is stopped, "watermelon" is stopped on the effective line, and when the right reel 31 is stopped, "black BAR" is stopped on the effective line. When the "blue BAR" is stopped, it is understood that the symbol combination corresponding to the winning combination is not stopped on the activated line (that is, the winning combination is not winning).

2. At the time of winning the special part Next, the update of the stop symbol data (_WK_STOP_PIC) at the time of winning the special part will be described.
In this example, as a result of the lottery, the game is determined to have the winning number "26", and the left stop switch 42 is operated when the symbol of the symbol number "16" is passing through the middle stage of the left reel 31. , Then, the middle stop switch 42 is operated when the symbol number "5" is passing through the middle stage of the middle reel 31, and then the symbol number "7" is passing through the middle stage of the right reel 31. When the right stop switch 42 is operated while the player is in the
Symbol control number (_BF_PICTURE ): 16 (watermelon) when the left reel 31 is stopped
Symbol control number (_BF_PICTURE ): 7 (bell B) when the middle reel 31 is stopped
Symbol control number (_BF_PICTURE) when the right reel 31 is stopped: 8 (black BAR)
Shall stop respectively.
In this case, the symbol combination on the activated line is "blue BAR (18th)"-"blue BAR (8th)"-"black BAR (8th)".
Also, the initial value of the stop symbol data (_WK_STOP_PIC) is
Stop symbol data (first group) (_WK_STOP_PIC1 ): "11111111(B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): “11111111(B)”
Stop symbol data (third group) (_WK_STOP_PIC3 ): "11111111(B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00001111 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "11111111(B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): “11111111(B)”
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "11111111(B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "11111111(B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000011 (B)"
Is.

2-1. At the time of stop operation of the left stop switch 42 At the time of stop operation of the left stop switch 42, the processing proceeds as follows.
In FIG. 195, in step S1031, "16(D)" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, the symbol combination data “00000010 (B)” of the address “1238 (H)” is stored in the A register.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, the AND operation is performed between the A register value "00000010 (B)" and the data (_WK_STOP_PIC9) ("00000011 (B)") at the address indicated by the HL register value. Thereby, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000010 (B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 8 of the left reel 31 (see address "1230(H)").
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC8) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 7 of the left reel 31 (see address "122B(H)").
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC7) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 for the fourth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 6 of the left reel 31 (see address "1224(H)").
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC6) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 of the fifth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 5 of the left reel 31 (see address "1220(H)").
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000000(B)" and the data (_WK_STOP_PIC5) ("11111111(B)") at the address indicated by the HL register value. As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 4 of the left reel 31 (see address "121B(H)").
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) (“00001111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In the seventh step S1033, the symbol combination data “00000001(B)” of the address “1215(H)” is stored in the A register. This means that 1BB exists as "blue BAR" in the symbol 3 group of the left reel 31.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, the AND operation is performed between the A register value “00000001(B)” and the data (_WK_STOP_PIC3) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000001(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In step S1033 of the eighth time, the symbol combination data “11111111(B)” of the address “1212(H)” is stored in the A register. This means that RBI to RBP exist as "blue BAR" in the symbol 2 group of the left reel 31.
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, the AND operation is performed between the A register value “11111111(B)” and the data (_WK_STOP_PIC2) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes “11111111(B)”.
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 of the ninth time, the symbol combination data “11111111(B)” of the address “120F(H)” is stored in the A register. This means that RBA to RBH exist as "blue BAR" in the symbol group 1 of the left reel 31.
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “11111111(B)” and the data (_WK_STOP_PIC1) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "11111111(B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the left stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "11111111(B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): “11111111(B)”
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000001 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000010 (B)"
From the above, when "blue BAR" is stopped on the activated line when the left reel 31 is stopped, there is a possibility of stopping the symbol combination of the symbols 1 group to the symbols 3 group and the symbol 9 group, but the symbols 4 group ~ It is understood that there is no possibility of stopping the symbol combination of the eight symbols.

2-2. During stop operation of the middle stop switch 42 During stop operation of the middle stop switch 42, as described above,
Design control number (_BF_PICTURE ): 7 (Bell B)
Design that stops on the activated line: "Blue BAR (No. 8)"
Shall be
In this case, when the middle stop switch 42 is stopped, the processing proceeds as follows.
In FIG. 195, in step S1031, “7” is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 (first time), "00000000(B)" is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 9 of the middle reel 31 (see address "128B(H)").
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed with the A register value “00000000(B)” and the data (_WK_STOP_PIC9) (“00000010(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol register data “00000111(B)” of the address “1283(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000111(B)” and the data (_WK_STOP_PIC8) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “00010000 (B)” of the address “1279 (H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00010000(B)" and the data (_WK_STOP_PIC7) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

At step S1033 of the fourth time, the symbol combination data “10000000(B)” of the address “1271(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "10000000(B)" and the data (_WK_STOP_PIC6) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 for the fifth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 5 of the middle reel 31 (see address "125A(H)").
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 4 of the middle reel 31 (see address "1255 (H)").
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “00000011 (B)” of the address “124E (H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000011 (B)" and the data (_WK_STOP_PIC3) (00000001 (B)" at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000001(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 2 of the middle reel 31 (see address "1248 (H)").
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, the symbol combination data “00001111(B)” of the address “1246(H)” is stored in the A register. This means that in the first group of the middle reels 31, RBA to RBD exist as symbols of "blue BAR".
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001111(B)” and the data (_WK_STOP_PIC1) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00001111 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the middle stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00001111 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000001 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, when the "blue BAR" is stopped on the effective line when the left reel 31 is stopped and the "blue BAR" is stopped on the effective line when the middle reel 31 is stopped, the RBA to RBD and 1BB are It can be seen that there is a possibility of stopping the corresponding symbol combination.

2-3. At the time of stop operation of the right stop switch 42 At the time of stop operation of the right stop switch 42, as described above,
Design control number (_BF_PICTURE ): 8 (black BAR)
Design to stop on the effective line: "Black BAR (No. 8)"
Shall be
In this case, when the right stop switch 42 is stopped, the process proceeds as follows.
195, in step S1031, "8" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 (first time), the A register stores the symbol combination data “00000001(B)” of the address “12DC(H)”.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000001(B)" and the data (_WK_STOP_PIC9) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol combination data “00010001(B)” of the address “12D4(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00010001(B)" and the data (_WK_STOP_PIC8) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “01100000 (B)” of the address “12CB (H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01100000(B)” and the data (_WK_STOP_PIC7) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 for the fourth time, the symbol combination data “00001100(B)” of the address “12C2(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001100(B)” and the data (_WK_STOP_PIC6) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 for the fifth time, the symbol combination data “10000000(B)” of the address “12B8(H)” is stored in the A register.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “10000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 for the seventh time, the symbol combination data “01000000(B)” of the address “12A8(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01000000(B)” and the data (_WK_STOP_PIC3) (“00000001(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000000(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In step S1033 of the eighth time, the symbol combination data “00011111(B)” of the address “12A1(H)” is stored in the A register. This means that in the symbol 2 group of the right reel 31, there are RBI to RBM as symbols of "black BAR".
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00011111(B)” and the data (_WK_STOP_PIC2) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 of the ninth time, the symbol combination data “00010001(B)” of the address “129B(H)” is stored in the A register. This means that RBA or RBE exists as a symbol of "black BAR" in the symbol group 1 of the right reel 31.
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed with the A register value "00010001(B)" and the data (_WK_STOP_PIC1) ("00001111(B)" at the address indicated by the HL register value. As a result, the stop symbol data (first group) )(_WK_STOP_PIC1) becomes "00000001(B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the right stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000001 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, when the left reel 31 is stopped, "blue BAR" is stopped on the effective line, when the middle reel 31 is stopped, "blue BAR" is stopped on the effective line, and when the right reel 31 is stopped, it is changed to the effective line. When "black BAR" stops, it can be seen that the symbol combination corresponding to RBA stops on the activated line.

3. At the time of winning the replay Next, the update of the stop symbol data (_WK_STOP_PIC) at the time of winning the replay will be described.
In this example, as a result of the lottery, the game is determined to have the winning number "1", and the left stop switch 42 is operated when the symbol of the symbol number "11" is passing through the middle stage of the left reel 31. , Then, the middle stop switch 42 is operated when the symbol of the symbol number "5" is passing through the middle stage of the middle reel 31, and then the symbol of the symbol number "2" is passing through the middle stage of the right reel 31. When the right stop switch 42 is operated while the player is in the replay 01,
Symbol control number (_BF_PICTURE ): 13 (red 7) when the left reel 31 is stopped
Symbol control number (_BF_PICTURE ): 7 (bell B) when the middle reel 31 is stopped
Symbol control number (_BF_PICTURE ): 4 (bell A) when the right reel 31 is stopped
Shall stop respectively.
In this case, the symbol combination on the activated line is “replay (15th)”-“blue BAR (8th)”-“bell A (4th)”.
Also, the initial value of the stop symbol data (_WK_STOP_PIC) is
Stop symbol data (first group) (_WK_STOP_PIC1 ): "11111111(B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): “11111111(B)”
Stop symbol data (third group) (_WK_STOP_PIC3 ): "11111111(B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00001111 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "11111111(B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): “11111111(B)”
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "11111111(B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "11111111(B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000011 (B)"
Is.

3-1. At the time of stop operation of the left stop switch 42 At the time of stop operation of the left stop switch 42, the processing proceeds as follows.
In FIG. 195, in step S1031, "13(D)" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) (“00000011(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol register data “11000001(B)” of the address “1233(H)” is stored in the A register. This means that in the symbol 8 group of the left reel 31, there are a small winning combination 25, a small winning combination 31, and a small winning combination 32 as a winning combination having the "replay" symbol.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed on the A register value “11000001(B)” and the data (_WK_STOP_PIC8) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "11000001 (B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “11001100(B)” of the address “122E(H)” is stored in the A register. This means that in the symbol 7 group of the left reel 31, there are a small winning combination 19, a small winning combination 20, a small winning combination 23, and a small winning combination 24 as a combination having the "replay" symbol.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “11001100(B)” and the data (_WK_STOP_PIC7) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "11001100(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

At step S1033 of the fourth time, the symbol combination data “10100000 (B)” of the address “1228 (H)” is stored in the A register. This means that in the symbol 6 group of the left reel 31, there are the small winning combination 14 and the small winning combination 16 as a winning combination having the "replay" symbol.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "10100000 (B)" and the data (_WK_STOP_PIC6) at the address indicated by the HL register value (the initial value is "11111111 (B)"). As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "10100000 (B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 of the fifth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, the symbol combination data “00000100(B)” of the address “121D(H)” is stored in the A register.
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000100(B)” and the data (_WK_STOP_PIC4) (00001111(B)”) of the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000100(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 for the seventh time, the symbol combination data “10000110(B)” of the address “1217(H)” is stored in the A register. This means that in the symbol 3 group of the left reel 31, there are Replay 01, Replay 02, and Replay 07 as the combination having the “Replay” symbol.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “10000110(B)” and the data (_WK_STOP_PIC3) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "1000110 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the left stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (third group) (_WK_STOP_PIC3 ): “1000110 (B)”
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000100 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "10100000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "11001100(B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "11000001 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"

3-2. During stop operation of the middle stop switch 42 During stop operation of the middle stop switch 42, as described above,
Design control number (_BF_PICTURE ): 7 (Bell B)
Design that stops on the activated line: "Blue BAR (No. 8)"
Shall be
In this case, when the middle stop switch 42 is stopped, the processing proceeds as follows.
In FIG. 195, in step S1031, “7” is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 9 of the middle reel 31 (see address "128B(H)").
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol register data “00000111(B)” of the address “1283(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000111(B)” and the data (_WK_STOP_PIC8) (“11000001(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000001 (B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “00010000 (B)” of the address “1279 (H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00010000(B)” and the data (_WK_STOP_PIC7) (“11001100(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

At step S1033 of the fourth time, the symbol combination data “10000000(B)” of the address “1271(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "10000000(B)" and the data (_WK_STOP_PIC6) ("10100000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "10000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 for the fifth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 5 of the middle reel 31 (see address "125A(H)").
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 4 of the middle reel 31 (see address "1255 (H)").
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC4) at the address indicated by the HL register value (“00000100(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “00000011 (B)” of the address “124E (H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000011 (B)” and the data (_WK_STOP_PIC3) (“100010 (B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000010 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data). This means that "blue BAR" does not exist in the symbol group 2 of the middle reel 31 (see address "1248 (H)").
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, the symbol combination data “00001111(B)” of the address “1246(H)” is stored in the A register.
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001111(B)” and the data (_WK_STOP_PIC1) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00001111 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the middle stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (third group) (_WK_STOP_PIC3 ): "00000010 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "10000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000001 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
Therefore, at the time of the second stop, the winning combinations are the replay 01, the small winning combination 16, and the small winning combination 25.

3-3. At the time of stop operation of the right stop switch 42 At the time of stop operation of the right stop switch 42, as described above,
Design control number (_BF_PICTURE ): 4 (bell A)
Design that stops on the activated line: "Bell A (No. 4)"
Shall be
In this case, when the right stop switch 42 is stopped, the process proceeds as follows.
195, in step S1031, "4" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, the A register stores the symbol combination data “00000010(B)” of the address “12DE(H)”.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000010(B)" and the data (_WK_STOP_PIC9) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 for the second time, the symbol combination data “00001000(B)” of the address “12D7(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00001000(B)" and the data (_WK_STOP_PIC8) ("00000001(B)") at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC7) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 of the fourth time, the symbol combination data “00001100(B)” of the address “12C4(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001100(B)” and the data (_WK_STOP_PIC6) (“10000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 of the fifth time, the symbol combination data “00001011(B)” of the address “12BA(H)” is stored in the A register.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001011(B)” and the data (_WK_STOP_PIC5) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC4) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “101000010(B)” of the address “12AB(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “101000010(B)” and the data (_WK_STOP_PIC3) (“00000010(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000010 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data of the address indicated by the HL register value (_WK_STOP_PIC1) (“00000000(B)”. As a result, the stop symbol data (first group) )(_WK_STOP_PIC1) becomes "00000000(B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the right stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (third group) (_WK_STOP_PIC3 ): "00000010 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, "replay" is stopped on the activated line when the left reel 31 is stopped, "blue BAR" is stopped on the activated line when the middle reel 31 is stopped, and "replay" is stopped on the activated line when the right reel 31 is stopped. When "Bell A" stops, it can be seen that the symbol combination corresponding to Replay 01 stops on the activated line.

Next, in describing "4. Winning a small win (when the push order is correct when the push order bell is won)", the reel stop control when the push order bell is won will be described.
Here, the case where the winning number “10” is determined as a result of the winning combination lottery will be described as an example.
In the twenty-third embodiment cited in the twenty-fifth embodiment, when the push order bell (winning number “10” to “21”) is won, the small winning combination wins with “PB=1” and no dropout occurs. Is set.
Generally, the following method can be used as the stop control of the reel 31 when a plurality of small winning combinations with different payout numbers, such as a winning number “10”, are won in duplicate.
As a first priority, when all of the symbols (of the reel 31) constituting the winning symbol combination can be stopped on the activated line, the reel 31 is stopped at that position.

Next, when it is not possible to stop all of the symbols constituting the winning symbol combination on the activated line (when the first priority cannot be adopted), as the second priority, "number of sheets priority" or " The reel 31 is stopped and controlled by either "number priority".
Here, the "number priority" means that among the symbol combinations of the winning combinations that have been won, the symbols of the reels 31 constituting the symbol combination having the largest number of payouts are preferentially stopped (pulled in) to the activated line. Say. Therefore, when the winning number “10” is won, the small winning combination 01 corresponds to the symbol combination with the largest number of payouts (15).
On the other hand, “number priority” means stopping the symbols of the reel 31 on the effective line so that the number of symbol combinations that can be stopped on the effective line is the largest.
In the present embodiment, since the number of effective lines is one, it is not possible to stop the symbol combination corresponding to all winning combinations on the effective line (first priority). 31 is stopped and controlled.
When the push order bell is won, the reel 31 is stopped and controlled when the push order is correct and the reel 31 is stopped and controlled when the push order is incorrect and when the push order is incorrect.

In the game when the small role A1 condition device is operating (during 1BB game), when the left first stop, it is the correct push order at this point, so the "watermelon" is stopped on the effective line (upper row). As shown in FIG. 114, the “watermelon” of the left reel 31 is arranged in four pieces with five symbol intervals (hereinafter, referred to as “PB=1” arrangement), so the left stop switch 42 is operated at any timing. Even if it is done, the "watermelon" can be stopped in the upper stage by "PB=1".

Next, when it is the middle second stop, since the pressing order is correct at this point, “cherry” is stopped on the activated line (middle row). As shown in FIG. 114, since the "cherry" of the middle reel 31 is arranged in "PB=1", the "cherry" is displayed in the middle row with "PB=1" no matter which timing the middle stop switch 42 is operated. Can be stopped.
Further, when the third stop on the right is made, the push order is correct, so "bell A" is stopped on the activated line (lower stage). As shown in FIG. 114, the "bell A" of the right reel 31 is in the "PB=1" arrangement, so no matter which timing the right stop switch 42 is operated, the "bell A" is "BEL A" with "PB=1". Can be stopped at the bottom.

On the other hand, after the first stop on the left side and the second stop on the right side, the pushing order is incorrect at this point, so the symbol of the left reel 31 is “watermelon” and is included in the small role A1 condition device. Any of the winning combinations (except the small combination 01) is stopped on the activated line.
As shown in FIG. 124, the winning combinations (excluding small combination 01) included in the small combination A1 condition device are
Small role 13: "Red 7"-"Bell A"-"Bell A/Bell B"
Small role 14: "Replay"-"Bell A"-"Bell A/Bell B"
Small role 15: "Black BAR"-"Bell A"-"Bell B"
Small role 16: "Replay"-"Blue BAR/Black BAR/Red 7/Special drawing top"-"Blue BAR"
Small role 17: "Watermelon"-"Red 7/Replay"-"Replay"
Is.

Therefore, the small winning combination 17 in which the symbol of the left reel 31 is "watermelon" is stopped.
As shown in FIG. 114, the “replay” of the right reel 31 has the “PB=1” arrangement, so that no matter which timing the right stop switch 42 is operated, “PB=1” is followed by “replay”. Can be stopped.
Next, at the time of the third and third stop, the "red 7/replay" is stopped on the activated line (middle). As shown in FIG. 114, the "replay" of the middle reel 31 has the "PB=1" arrangement. Therefore, no matter which timing the middle stop switch 42 is operated, "PB=1" causes the "replay" to be in the middle stage. Since it can be stopped at any time, it can be mentioned that "replay" is stopped at the activated line. Therefore, the small winning combination 17 can be won. Incidentally, when the middle stop switch 42 is operated at a timing at which "Red 7" can be stopped on the active line, it goes without saying that "Red 7" may be stopped on the active line.

On the other hand, in the game when the small win A1 condition device is operating (during 1BB game), when the game is the first stop, the pushing order becomes incorrect at this point, so the effective line (middle) has a small win. Any of the symbols related to 13 to the small winning combination 17 is stopped. In this case, the "bell A" is stopped on the activated line by executing the number priority. Since the "bell A" of the middle reel 31 is arranged in "PB=1", the "bell A" can be stopped in the middle stage by "PB=1" no matter which timing the middle stop switch 42 is operated. it can.
Next, when the vehicle is in the second stop on the left side, since one each of "red 7", "replay" and "black BAR" is provided, there is no superiority or inferiority and it can be set to any one. Therefore, the "replay" having the "PB=1" arrangement is stopped on the effective line (upper row).
Next, in the third stop on the right side, “Bell A/Bell B” is stopped on the activated line (lower stage). As for the right reel 31, both “Bell A” and “Bell B” are in the “PB=1” arrangement, any of them may be stopped.

On the other hand, when it is the second stop to the right after the middle first stop, the "bell B" is stopped to the lower stage due to the priority of the number. As described above, the "bell B" of the right reel 31 has the "PB=1" arrangement.
Further, at the time of the third stop on the left side, any one of "red 7", "replay" and "black BAR" is stopped. For example, it may be set to stop the "replay" having the "PB=1" arrangement. When the left stop switch 42 is operated at a timing at which "red 7" or "black BAR" can be stopped on the activated line, "red 7" or "black BAR" may be stopped on the activated line, respectively. Of course.

In addition, in the game when the small win A1 condition device is operating (during the 1BB game), when the right first stop, the pushing order is incorrect at this point, so the effective line (lower) has a small win 13 to One of the symbols related to the small winning combination 17 is stopped. In this case, the "bell B" is stopped on the activated line by executing the number priority.
Next, when it is the second stop on the left side, any one of "red 7", "replay" or "black BAR" is stopped. In this case, similarly to the above, it can be mentioned that the "replay" having the "PB=1" arrangement is determined to be stopped at the effective line (upper stage).
Then, at the time of the third and third stop, the "bell A" is stopped on the activated line (middle stage).
On the other hand, after the first stop on the right side and the second stop on the middle side, the "bell A" is stopped on the activated line (middle stage).
Next, at the time of the third stop on the left side, either "red 7", "replay" or "black BAR" is stopped. In this case, similarly to the above, it can be mentioned that the "replay" having the "PB=1" arrangement is determined to be stopped at the effective line (upper stage).

As described above, when the small win A1 condition device is operating during the 1BB game,
Push order 123: Small win 01 prize (15 pieces)
Push order 132: Small prize 17 prize (3 pieces)
Push order 213: Small prize 14 prize (3 pieces)
Push order 231: Small prize 14 prize (3 pieces)
Push order 312: Small prize 14 prize (3 pieces)
Pushing order 321: Small prize 14 prize (3 pieces)
Becomes

Further, when the winning number "10" is won during the normal game (during non-special game), since there is no correct answer pushing order, the reel 31 is stop-controlled by the number priority.
For example, when the winning number "10" is won during the normal game and the stop switch 42 is operated with the pushing order "123", the "replay" is stopped on the effective line (upper row) by the number first priority when the left first stop is made. Let
Next, at the time of the second stop in the middle, either "bell A" or "blue BAR/black BAR/red 7/special view" is stopped. Here, if the "blue BAR/black BAR/red 7/special drawing top" related to the small winning combination 16 is stopped on the activated line, the "blue BAR" becomes "PB≠1" when the right reel 31 is stopped. Therefore, it may not be possible to stop at the effective line. Therefore, at the time of the second middle stop, the "bell A" is stopped on the effective line (middle stage).
Next, at the time of the third stop on the right side, "bell A/bell B" is stopped on the effective line (lower stage). As a result, the small prize 14 is won.

4. When winning a small role (when the push order bell is correct and the push order is correct)
Next, the update of the stop symbol data (_WK_STOP_PIC) at the time of the stop operation of each stop switch 42 when the small prize is won will be described.
In this example, in FIG. 124, in the game in which the winning number “10” is won during the 1BB game, and the small winning combination A1 condition device operates, the stop switch is operated in the correct answer pressing order “123”, and there are 15 winning combinations. Small role 01 shall be awarded.
The left stop switch 42 is operated while the symbol of the symbol number "8" is passing through the middle stage of the left reel 31, and then the symbol of the symbol number "8" is passing through the middle stage of the middle reel 31. When the middle stop switch 42 is operated, and then the right stop switch 42 is operated while the symbol of the symbol number "2" is passing through the middle of the right reel 31,
Symbol control number (_BF_PICTURE ): 9 (bell A) when the left reel 31 is stopped
Symbol control number (_BF_PICTURE ): 10 (bell A) when the middle reel 31 is stopped
Symbol control number (_BF_PICTURE ): 4 (bell A) when the right reel 31 is stopped
Shall stop respectively.
In this case, the symbol combination on the activated line is “watermelon (11th)”-“cherry (11th)”-“bell A (4th)”.
Also, the initial value of the stop symbol data (_WK_STOP_PIC) is
Stop symbol data (first group) (_WK_STOP_PIC1 ): "11111111(B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): “11111111(B)”
Stop symbol data (third group) (_WK_STOP_PIC3 ): "11111111(B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00001111 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "11111111(B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): “11111111(B)”
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "11111111(B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "11111111(B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000011 (B)"
Is.

4-1. At the time of stop operation of the left stop switch 42 At the time of stop operation of the left stop switch 42, the processing proceeds as follows.
195, in step S1031, "9(D)" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) (“00000011(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol combination data “00011010(B)” of the address “1234(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00011010(B)” and the data (_WK_STOP_PIC8) (“11111111(B)”) at the address indicated by the HL register value. Thereby, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00011010(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “00000011 (B)” of the address “122F (H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000011 (B)" and the data (_WK_STOP_PIC7) ("11111111 (B)") at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000011 (B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 of the fourth time, the symbol combination data “00000010(B)” of the address “122A(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000010 (B)" and the data (_WK_STOP_PIC6) at the address indicated by the HL register value (the initial value is "11111111 (B)"). As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000010 (B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 of the fifth time, the symbol combination data “11001011(B)” of the address 1223(H)” is stored in the A register.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “11001011(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (initial value is “11111111(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "11001011(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC4) (00001111(B)” at the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “01000000(B)” of the address “1219(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01000000(B)” and the data (_WK_STOP_PIC3) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "01000000 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the left stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "01000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5): "11001011(B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000010 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000011 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00011010 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"

4-2. During stop operation of the middle stop switch 42 During stop operation of the middle stop switch 42, as described above,
Design control number (_BF_PICTURE ): 10 (bell A)
Design to stop on the activated line: "Cherry (11)"
Shall be
In this case, when the middle stop switch 42 is stopped, the processing proceeds as follows.
In FIG. 195, in step S1031, “10(D)” is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, the A register stores the symbol combination data “00000001(B)” of the address “128E(H)”.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000001(B)" and the data (_WK_STOP_PIC9) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol register data “00110000(B)” of the address “1289(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00110000(B)" and the data (_WK_STOP_PIC8) ("00011010(B)") at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00010000 (B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “00000010(B)” of the address “127F(H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000010 (B)" and the data (_WK_STOP_PIC7) ("00000011 (B)") at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000010 (B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 for the fourth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC6) (“00000010(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

At step S1033 for the fifth time, the A register stores the symbol combination data “01000001(B)” of the address “125E(H)”.
In step S1035, the AND operation is performed between the A register value “01000001(B)” and the data (_WK_STOP_PIC5) (“11001011(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "01000001 (B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, the symbol combination data “00000110 (B)” of the address “1259 (H)” is stored in the A register.
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “000000110 (B)” and the data (_WK_STOP_PIC4) (“00000000 (B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “00011000(B)” of the address “1253(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00011000(B)” and the data (_WK_STOP_PIC3) at the address indicated by the HL register value (“01000000(B)”). As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000000(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the middle stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (fifth group) (_WK_STOP_PIC5 ): "01000001 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000010 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00010,000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
Therefore, during the second stop operation, the winning combinations are the winning combination 01, the winning combination 07, the winning combination 18, and the winning combination 29.

4-3. At the time of stop operation of the right stop switch 42 At the time of stop operation of the right stop switch 42, as described above,
Design control number (_BF_PICTURE ): 4 (bell A)
Design that stops on the activated line: "Bell A (No. 4)"
Shall be
In this case, when the right stop switch 42 is stopped, the process proceeds as follows.
195, in step S1031, "4" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, the A register stores the symbol combination data “00000010(B)” of the address “12DE(H)”.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000010(B)" and the data (_WK_STOP_PIC9) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 for the second time, the symbol combination data “00001000(B)” of the address “12D7(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001000(B)” and the data (_WK_STOP_PIC8) (“00010000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC7) (“00000010(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 of the fourth time, the symbol combination data “00001100(B)” of the address “12C4(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001100(B)” and the data (_WK_STOP_PIC6) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00000000(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

At step S1033 of the fifth time, the A register stores the symbol combination data “00001011(B)” of the address “12BA(H)”.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00001011(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“01000001(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000001(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC4) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In the seventh step S1033, the A register stores the symbol combination data “101000010(B)” of the address “12AB(H)”.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “101000010(B)” and the data (_WK_STOP_PIC3) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000000(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data of the address indicated by the HL register value (_WK_STOP_PIC1) (“00000000(B)”. As a result, the stop symbol data (first group) )(_WK_STOP_PIC1) becomes "00000000(B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the right stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000001 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00000000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
From the above, when the left reel 31 is stopped, the "watermelon" is stopped on the activated line, the "cherry" is stopped on the activated line when the middle reel 31 is stopped, and the "bell" is activated on the activated line when the right reel 31 is stopped. When "A" stops, it can be seen that the symbol combination corresponding to the small winning combination 01 stops on the activated line.

5. When a small role wins a prize (when the push order is incorrect when the push order bell is won)
In this example, in FIG. 124, the winning number "10" is determined during the general game of the 1BB game, and in the game in which the small role A1 condition device operates, the stop switch is operated in the incorrect pressing order "321", As in the example, it is assumed that the symbol combination “replay”-“bell A”-“bell B” of the small winning combination 14 which is a three-piece winning combination is won.
Further, when the symbol of the symbol number "1" is passing through the middle stage of the left reel 31, the left stop switch 42 is operated, and when the symbol of the symbol number "7" is passing through the middle stage of the middle reel 31. The middle stop switch 42 is operated, and the right stop switch 42 is operated while the symbol of the symbol number “19” is passing through the middle stage of the right reel 31 (the pushing order is right→middle→left).
Symbol control number (_BF_PICTURE ): 3 (black BAR) when the left reel 31 is stopped
Symbol control number (_BF_PICTURE) when the middle reel 31 is stopped: 9 (replay)
Symbol control number (_BF_PICTURE ): 0 (bell B) when the right reel 31 is stopped
Shall stop respectively.
In this case, the symbol combination on the activated line is "Replay (No. 5)"-"Bell A (No. 10)"-"Bell B (No. 0)".
Also, the initial value of the stop symbol data (_WK_STOP_PIC) is
Stop symbol data (first group) (_WK_STOP_PIC1 ): "11111111(B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): “11111111(B)”
Stop symbol data (third group) (_WK_STOP_PIC3 ): "11111111(B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00001111 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "11111111(B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): “11111111(B)”
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "11111111(B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "11111111(B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000011 (B)"
Is.

5-1. At the time of stop operation of the right stop switch 42 At the time of stop operation of the right stop switch 42, as described above,
Design control number (_BF_PICTURE ): 0 (Bell B)
Design to stop on the activated line: "Bell B (No. 0)"
Shall be
In this case, when the right stop switch 42 is stopped, the process proceeds as follows.
In FIG. 195, in step S1031, “0” is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) (“00000011(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC8) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC7) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 of the fourth time, the symbol combination data “01110011(B)” of the address “12C5(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed on the A register value “0” and the data (_WK_STOP_PIC6) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "01110011(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 for the fifth time, the A register stores the symbol combination data “01000000(B)” of the address “12BB(H)”.
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“11111111(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "01000000 (B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, the symbol register data “00000100(B)” of the address “12B3(H)” is stored in the A register.
In step S1035, an AND operation is performed between the A register value “00000100(B)” and the data (_WK_STOP_PIC4) (“0001111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000100(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 of the seventh time, the symbol combination data “00011000(B)” of the address “12AC(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00011000(B)” and the data (_WK_STOP_PIC3) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00011000 (B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“11111111(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000 (B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed with the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“11111111(B)”) of the address indicated by the HL register value. )(_WK_STOP_PIC1) becomes "00000000(B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the right stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (third group) (_WK_STOP_PIC3 ): "00011000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000100 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "01000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "01110011(B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"

5-2. When stopping the middle stop switch 42 When the middle reel 31 is stopped, as described above,
Design control number (_BF_PICTURE ): 9 (replay)
Design that stops on the activated line: "Bell A (No. 10)"
Shall be
In this case, when the middle stop switch 42 is stopped, the processing proceeds as follows.
In FIG. 195, in step S1031, "8(D)" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 of the first time, the A register stores the symbol combination data “00000010(B)” of the address “128D(H)”.
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "00000010(B)" and the data (_WK_STOP_PIC9) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol combination data “11000000(B)” of the address “1286(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "11000000(B)" and the data (_WK_STOP_PIC8) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “01100100(B)” of the address “127D(H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01100100(B)” and the data (_WK_STOP_PIC7) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

In step S1033 of the fourth time, the symbol combination data “01111011(B)” of the address “1275(H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “01111011(B)” and the data (_WK_STOP_PIC6) (“01110011(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "01110011(B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 for the fifth time, the symbol combination data “10101110(B)” of the address “125D(H)” is stored in the A register.
In step S1035, the AND operation is performed between the A register value “10101110(B)” and the data (_WK_STOP_PIC5) (“01000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC4) at the address indicated by the HL register value (“00000100(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In the seventh step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC3) at the address indicated by the HL register value (“00011000(B)”). As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000000(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the middle stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "01110011(B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"

5-3. When stopping the left stop switch 42 When stopping the left stop switch 42, as described above,
Design control number (_BF_PICTURE ): 3 (black BAR)
Design that stops on the activated line: "Replay (No. 5)"
Shall be
In this case, when the left stop switch 42 is stopped, the process proceeds as follows.
195, in step S1031, "3(D)" is stored in the A register value (symbol control number).
In step S1032, "9" is set in the B register (number of symbol groups).
In step S1033 (first time), “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BF(H)" (address of stop symbol data (9th group) (_WK_STOP_PIC9)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC9) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (9th group) (_WK_STOP_PIC9) becomes "00000000(B)".
In step S1036, the B register value is updated to "8", and the process returns to step S1033.

In step S1033 of the second time, the symbol register data “11000001(B)” of the address “1233(H)” is stored in the A register.
In step S1034, "F0BE(H)" (address of stop symbol data (8th group) (_WK_STOP_PIC8)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "11000001(B)" and the data (_WK_STOP_PIC8) ("00000000(B)") at the address indicated by the HL register value. As a result, the stop symbol data (8th group) (_WK_STOP_PIC8) becomes "00000000(B)".
In step S1036, the B register value is updated to "7", and the process returns to step S1033.

In step S1033 of the third time, the symbol combination data “11001100(B)” of the address “122E(H)” is stored in the A register.
In step S1034, “F0BD(H)” (address of stop symbol data (7th group) (_WK_STOP_PIC7)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “11001100(B)” and the data (_WK_STOP_PIC7) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (7th group) (_WK_STOP_PIC7) becomes "00000000(B)".
In step S1036, the B register value is updated to "6", and the process returns to step S1033.

At step S1033 of the fourth time, the symbol combination data “10100000 (B)” of the address “1228 (H)” is stored in the A register.
In step S1034, "F0BC(H)" (address of stop symbol data (sixth group) (_WK_STOP_PIC6)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value "10100000 (B)" and the data (_WK_STOP_PIC6) ("01110011(B)") at the address indicated by the HL register value. As a result, the stop symbol data (sixth group) (_WK_STOP_PIC6) becomes "00100000 (B)".
In step S1036, the B register value is updated to "5", and the process returns to step S1033.

In step S1033 for the fifth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0BB(H)" (address of stop symbol data (fifth group) (_WK_STOP_PIC5)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC5) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fifth group) (_WK_STOP_PIC5) becomes "00000000(B)".
In step S1036, the B register value is updated to "4", and the process returns to step S1033.

In step S1033 of the sixth time, the symbol combination data “00000100(B)” of the address “121D(H)” is stored in the A register.
In step S1034, "F0BA(H)" (address of stop symbol data (fourth group) (_WK_STOP_PIC4)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000100(B)” and the data (_WK_STOP_PIC4) at the address indicated by the HL register value (“00000000(B)”). As a result, the stop symbol data (fourth group) (_WK_STOP_PIC4) becomes "00000000(B)".
In step S1036, the B register value is updated to "3", and the process returns to step S1033.

In step S1033 for the seventh time, the symbol combination data “10000110(B)” of the address “1217(H)” is stored in the A register.
In step S1034, "F0B9(H)" (address of stop symbol data (third group) (_WK_STOP_PIC3)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “10000110(B)” and the data (_WK_STOP_PIC3) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (third group) (_WK_STOP_PIC3) becomes "00000000(B)".
In step S1036, the B register value is updated to "2", and the process returns to step S1033.

In the eighth step S1033, "00000000(B)" is stored in the A register (symbol combination data).
In step S1034, "F0B8(H)" (address of stop symbol data (second group) (_WK_STOP_PIC2)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC2) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (second group) (_WK_STOP_PIC2) becomes "00000000(B)".
In step S1036, the B register value is updated to "1", and the process returns to step S1033.

In step S1033 for the ninth time, “00000000(B)” is stored in the A register (symbol combination data).
In step S1034, "F0B7(H)" (address of stop symbol data (first group) (_WK_STOP_PIC1)) is stored in the HL register value.
In step S1035, an AND operation is performed between the A register value “00000000(B)” and the data (_WK_STOP_PIC1) (“00000000(B)”) at the address indicated by the HL register value. As a result, the stop symbol data (first group) (_WK_STOP_PIC1) becomes "00000000 (B)".
In step S1036, the B register value is updated to "0", and it is determined to be "Yes", so that the stopped symbol set is ended.

By the above processing, the stop symbol data at the time of the stop operation of the left stop switch 42 is as follows.
Stop symbol data (first group) (_WK_STOP_PIC1 ): "00000000 (B)"
Stop symbol data (second group) (_WK_STOP_PIC2 ): "00000000 (B)"
Stop symbol data (3rd group) (_WK_STOP_PIC3 ): "00000000 (B)"
Stop symbol data (4th group) (_WK_STOP_PIC4 ): "00000000 (B)"
Stop symbol data (5th group) (_WK_STOP_PIC5 ): "00000000 (B)"
Stop symbol data (6th group) (_WK_STOP_PIC6 ): "00100000 (B)"
Stop symbol data (7th group) (_WK_STOP_PIC7 ): "00000000 (B)"
Stop symbol data (8th group) (_WK_STOP_PIC8 ): "00000000 (B)"
Stop symbol data (9th group) (_WK_STOP_PIC9 ): "00000000 (B)"
Therefore, the data indicates that the small winning combination 14 has won.

By setting the stop symbol data as described above, even if a power failure occurs, it is possible to properly restart the game using the already stored stop symbol data after returning from the power failure.
For example, as shown in FIG. 194, when it is decided to determine the stop position (when “Yes” in step S1017), the stop position is determined and the stop symbol data is updated (step S1035 in FIG. 195). )) (the stop symbol set in step S1024 of FIG. 194) is completed until the voltage (eg, 9.2 V. The same applies below) for which the power-off process is executed is completed (normally, normally). Even if the voltage of 12 V is applied.), the interrupt process is not executed (due to the interrupt waiting process). Therefore, the stop position is determined and the interrupt is stopped before the power-off process is executed. The design data is updated. Therefore, even if the power-off process is executed after the process and the reel 31 is not stopped at the determined stop position, the stop symbol data has already been updated, so when the power is restored thereafter, Normal payout processing can be executed.

Further, even when a plurality of stop switches 42 are simultaneously operated under the condition that all reels 31 are rotating at a constant speed, only one stop switch 42 is operated, so that, for example, the stop is performed. When it is decided to determine the position (when “Yes” in step S1017 of FIG. 194), the stop position is determined, and processing including update of stop symbol data (step S1035 of FIG. 195) (FIG. 194) Even when the reel 31 does not stop at the determined stop position when the voltage drops to a voltage at which the power-off process is executed before the completion of the stop symbol setting in step S1024) Since there is only one, it is possible to avoid the situation where the plurality of reels 31 do not stop at the determined stop position.

Furthermore, for example, even when all the reels 31 are rotating at a constant speed, the power is cut off after the stop switch 42 corresponding to the left reel 31 is operated, and the power-off processing is executed. Since the stop symbol data has been updated, after the power is restored, the stop symbol data before the power failure is generated is used, based on the stop operation of the middle reel 31 and the stop operation of the right reel 31, the stop symbol data. Can be restarted (the game can be restarted).

Here, in general, the data that can be held in one register is 1-byte data, and there are seven types of general-purpose registers that can be used by the one-chip microprocessor (Z80) of the gaming machine (main control board 50). In this way, in order to hold the symbol combination data having the number (9 in the present embodiment) of the stop symbol data that exceeds the type of general-purpose register, it is necessary to store the stop symbol data in the RWM 53. is there.
When the stop symbol data is stored in the general-purpose register, power failure occurs, and when the power is restored after that, the stop symbol data (value stored in the general-purpose register) is cleared (set to the initial value). (For example, it is set to "0".). Therefore, in the case where the stop symbol data is stored in the general-purpose register, for example, the power is cut off after the stop switch 42 corresponding to the left reel 31 is operated, and the power cut-off process is executed. , There is a high possibility that the game cannot be restarted.
Further, when the stop symbol data is stored in the RWM 53, the stop symbol data is updated for each stop operation of the stop switch 42. Therefore, in the development stage, the RWM 53 determines whether or not the stop position is correct for each stop operation. It can be confirmed by inspecting the stop symbol data.

As described above, when the symbol combination to be stopped on the activated line is specified, the payout number is determined based on the stopped symbol data.
FIG. 200 is a flowchart showing 1-line display determination (M_LINE_JUDGE). This process is executed after all reels 31 have stopped and before the payout process. For example, it corresponds to the process of step S291 in FIG. 139.
By this processing, the payout number is determined from the stop symbol data (_WK_STOP_PIC).
In FIG. 200, in step S1101, a payout amount table is set. This process is a process of storing the start address “1400 (H)” of the payout amount table (TBL_WIN_CTL) shown in FIG. 193 in the HL register.

Next, proceeding to step S1102, the stop symbol data 5 (“5” means the fifth group) RWM address is set. This process is a process of storing the address "F0BB(H)" of the stop symbol data (fifth group) (_WK_STOP_PIC5) in the DE register.
In the present embodiment, in the stop symbol data (first group) to the stop symbol data (fourth group), there is no winning combination having a payout at the time of winning the prize, and the stop symbol data (fifth group) to the stop symbol data (the fifth group). Only the 9th group) has a hand that has a payout at the time of winning. Therefore, in order to determine whether or not any one of the stop symbol data (fifth group) to the stop symbol data (9th group) is “1”, as the initial value, the stop symbol data (fifth group) Group) (_WK_STOP_PIC5) address is set.

Next, proceeding to step S1103, designated data acquisition (M_SELDAT_SET) is executed. This process is a process shown in FIG. 201, which will be described later, and is a process of identifying designated data corresponding to the number of payouts from the payout number table (TBL_WIN_CTL).
Next, in step S1104, the payout amount data is stored. Here, at the end of the process of step S1103, a value corresponding to the number of payouts is stored in the A register. Therefore, this process is a process of storing the A register value in the payout amount data (_NB_PAY_MEDAL) of the address “F023(H)”.
Next, in step S1105, the payout number buffer is stored. This process is a process of storing the A register value in the payout amount data buffer (_BF_PAY_MEDAL) of the address "F024(H)". Then, the processing according to this flowchart is ended.

FIG. 201 is a flowchart showing designated data acquisition (M_SELDAT_SET) in step S1103 of FIG. For reference, FIG. 201 also shows the payout amount table (TBL_WIN_CTL) shown in FIG. 193.
201, in step S1111, the number of inspections is set. This process is a process of storing the data stored in the address indicated by the HL register value in the B register. Since the HL register value is “1400(H)” and the data stored at the address “1400(H)” is “6(H)”, “6(H)” is stored in the B register. It
When inspecting the number of payouts,
First time: Stop symbol data (5th group) (_WK_STOP_PIC5) 15-card combination (11111111 (B))
2nd time: 15 symbols of stop symbol data (6th group) (_WK_STOP_PIC6) (00001111(B))
3rd time: Stop symbol data (6th group) (_WK_STOP_PIC6) 3 cards combination (1110000 (B))
Fourth time: Stop symbol data (7th group) (_WK_STOP_PIC7) three-card combination (11111111 (B))
Fifth time: Stop symbol data (8th group) (_WK_STOP_PIC8) 1-card combination (11111111(B))
6th time: Stop symbol data (9th group) (_WK_STOP_PIC9) 1-card combination (00000011 (B))
The number of inspections is set to "6" because the inspection is performed up to 6 times.

In the next step S1112, the table address is updated. In this processing, "1" is added to the HL register value, and the value after adding "1" is set as the HL register value. As a result, the HL register value becomes "1401(H)".
Next, proceeding to step S1113, table data is acquired. This process is a process of storing the data stored in the address indicated by the HL register value in the A register. In the first step S1113, since the HL register value is “1401(H)”, the data “0*32+15” stored at the address “1401(H)” (actually, “00001111(B) ))) in the A register.
Next, proceeding to step S1114, the A register value is divided by "32(D)". Then, the quotient is stored in the A register, and the remainder is stored in the C register. As a result, the A register value is "0" and the C register value is "15(D)" at the first time. This C register value corresponds to the payout number when there is a winning combination.

Next, proceeding to step S1115, RWM data is acquired. Here, the following processing is executed.
(1) The DE register value (address value of stop symbol data) is added to the A register, and the addition result is used as the DE register value.
(2) The data stored at the address indicated by the DE register value is stored in the A register.
Therefore, in step S1115 of the first time, the DE register value is “F0BB(H)” stored in step S1102 of FIG. 200 and the A register value is “0”, so the DE register value after addition is It is “F0BB(H)”.
Next, assuming that the data (stop symbol data (fifth group) (_WK_STOP_PIC5)) stored at the address indicated by "F0BB(H)" is "00000001(B)", the A register value is "00000001(B). )”

Next, proceeding to step S1116, the table address is updated. Here, the following processing is executed.
(1) Add "1" to the HL register value, and set the result after adding "1" as the HL register value. In step S1116 of the first time, the HL register value before this processing is “1401(H)”, and therefore, the addition of “1” makes the HL register value “1402(H)”.
(2) An AND (logical product) of the A register value and the value stored at the address indicated by the HL register value is performed. When the result of the AND operation is "0", the zero flag becomes "1", and when it is not "0", the zero flag does not become "1".
Here, the value “@_PIC5” stored in the address “1402(H)” corresponds to the value in which all the bits of the stop symbol data (fifth group) are set to “1” (see FIG. 176). Therefore, if this value and the A register value (stop symbol data (fifth group) (_WK_STOP_PIC5) actual value) are ANDed, it is determined whether or not any winning combination of the fifth group has won. It will be possible.

Next, proceeding to step S1117, the acquired data is set. This process is a process of storing the C register value in the A register.
In the next step S1118, it is determined whether or not there is designated data. Here, if the zero flag is not "1" (as a result of the calculation in step S1116), it is determined that there is designated data. If it is determined that there is designated data, the process according to this flowchart is ended, and if it is determined that there is no designated data, the process proceeds to step S1119.

In step S1119, it is determined whether or not the number of inspections has been completed. In this processing, if the value of the B register is subtracted by "1" and it is not "0", it is determined to be "No" (the inspection count is not completed). When it is determined that the number of inspections has been completed, the process proceeds to step S1120, and when it is determined that the number of inspections has not been completed, the process returns to step S1112.
In step S1120, no acquisition data is set. This process is a process of storing the B register value in the A register value. Then, the processing according to this flowchart is ended.
Here, when the process proceeds to step S1120, the number of inspections has been completed, so the B register value is "0". Therefore, the A register value becomes "0". This A register value corresponds to the payout number. In this way, when the symbol combination having no payout number is stopped and displayed, it is possible to divert the inspection number data “0” and store the payout number data.

Next, the one-line display determination shown in FIG. 200 will be described with a specific example.
In this example, it is assumed that the small winning combination 19 is winning (the symbol combination corresponding to the small winning combination 19 is stopped).
Therefore, before the 1-line display determination is executed,
Stop symbol data (5th group) (_WK_STOP_PIC5 ): 00000000 (B)
Stop symbol data (6th group) (_WK_STOP_PIC6 ):00000000 (B)
Stop symbol data (7th group) (_WK_STOP_PIC7 ): 00000100 (B)
Stop symbol data (8th group) (_WK_STOP_PIC8 ): 00000000 (B)
Stop symbol data (9th group) (_WK_STOP_PIC9 ): 00000000 (B)
Has become.
Even if the symbol combination actually stopped on the activated line is different from the symbol combination corresponding to the small winning combination 19 due to a malfunction of the motor 32 or power interruption, the stopped symbol data (7th group) ( Since the data stored in _WK_STOP_PIC7) is "00000100(B)", the payout control corresponding to the small winning combination 19 can be executed.

In this case, in step S1101 (payout number table set) of FIG. 200, “1400 (H)” is stored in the HL register value.
In step S1102 (stop symbol data 5RWM address set), "F0BB(H)" is stored in the DE register value.
When the process proceeds to step S1103 (acquisition of designated data), the process proceeds to step S1111 (set of inspection times) of FIG. 201, and “6” is stored in the B register value.
In the next step S1112 (table address update), the HL register value is updated to "1401(H)".
In the next step S1113 (obtaining table data), the data “15(D)” stored in the address “1401(H)” is stored in the A register.

In the next step S1114 (division), the A register value “15(D)” is divided by “32(D)”, the quotient “0” is stored in the A register, and the remainder “15(D)” is stored in the C register. Remember.
In the next step S1115 (RWM data acquisition), the A register value "0" is added to the DE register value "F0BB(H)", so the DE register value remains "F0BB(H)".
Next, the data (stop symbol data (fifth group) (_WK_STOP_PIC5)) “00000000(B)” stored in the address “F0BB(H)” is stored in the A register.

In the next step S1116 (table address update), the HL register value is updated to "1402(H)".
Also, AND (logical product) of the A register value “00000000(B)” and the value “11111111(B)” stored at the address indicated by the HL register value “1402(H)” is performed. As a result, the zero flag becomes "1".
In step S1117 (acquired data set), the C register value “15(D)” is stored in the A register.
In step S1118 (designation data present?), since the zero flag is "1", it is determined to be "No", and the process proceeds to step S1119.
In step S1119 (End of inspection count?), "1" is subtracted from the B register value and updated to "5". Since the B register value is not "0", it is determined to be "No", and the process returns to step S1112.

In step S1112 (second time) (table address update), the HL register value is set to "1403 (H)".
In the next step S1113 (obtaining table data), the data “47(D)” stored in the address “1403(H)” is stored in the A register.
In step S1114 (division), the A register value "47(D)" is divided by "32(D)". As a result, the quotient "1(D)" is stored in the A register, and the remainder "15(D)" is stored in the C register.
In step S1115 (RWM data acquisition), the A register value "1(H)" is added to the DE register value "F0BB(H)" to set the DE register value to "F0BC(H)".
Then, the data (data “00000000(B)” of the stop symbol data (sixth group)) stored in “F0BC(H)” is stored in the A register.

In step S1116 (table address update), the HL register value is updated to "1404 (H)".
Further, the A register value “00000000(B)” and the value “00001111(B)” stored at the address “1404(H)” indicated by the HL register value are ANDed (logical product). As a result, the zero flag becomes "1".
In step S1117 (acquired data set), the C register value “15(D)” is stored in the A register.
In step S1118 (designation data present?), since the zero flag is "1", it is determined to be "No", and the process proceeds to step S1119.
In step S1119 (end of inspection count?), the B register value is subtracted by "1" and updated to "4". Since the B register value is not "0", it is determined to be "No", and the process returns to step S1112.

In step S1112 (third time) (table address update), the HL register value is updated to "1405 (H)".
In the next step S1113 (obtaining table data), the data “3(D)” stored in the address “1405(H)” is stored in the A register.
In step S1114 (division), "3(D)" is divided by "32(D)". As a result, the quotient “0” is stored in the A register, and the remainder “3(D)” is stored in the C register.
In step S1115 (RWM data acquisition), the A register value "0(H)" is added to the DE register value "F0BC(H)" to set the DE register value to "F0BC(H)".
Then, the data (data “00000000(B)” of the stop symbol data (sixth group)) stored in “F0BC(H)” is stored in the A register.

In step S1116 (table address update), the HL register value is updated to "1406 (H)".
Further, the A register value "00000000(B)" and the value "1110000(B)" stored in the address "1406(H)" indicated by the HL register value are ANDed (logical product). As a result, the zero flag becomes "1".
In step S1117, the C register value “3(D)” is stored in the A register.
In step S1118, since the zero flag is "1", it is determined to be "No", and the process proceeds to step S1119.
In step S1119, the B register value is subtracted by "1" and updated to "3". Since the B register value is not "0", it is determined to be "No", and the process returns to step S1112.

In step S1112 (fourth time) (table address update), the HL register value is updated to "1407 (H)".
In the next step S1113 (table data acquisition), the data “35(D)” stored in the address “1407(H)” is stored in the A register.
In step S1114 (division), "35(D)" is divided by "32(D)". As a result, the quotient "1" is stored in the A register, and the remainder "3(D)" is stored in the C register.
In step S1115 (RWM data acquisition), the A register value "1(H)" is added to the DE register value "F0BC(H)" to set the DE register value to "F0BD(H)".
Then, the data (data “0000100(B)” of the stop symbol data (7th group)) stored in “F0BD(H)” is stored in the A register.

In step S1116 (table address update), the HL register value is updated to “1408 (H)”.
Also, the AND (logical product) of the A register value “00000100(B)” and the value “11111111(B)” stored in the address “1408(H)” indicated by the HL register value is performed. As a result, the zero flag becomes "0".
In step S1117, the C register value “3(D)” is stored in the A register.
In step S1118, since the zero flag is "0", it is determined that there is designated data, and the process proceeds to step S1104 in FIG. At this point, "3(D)" is stored in the A register.
In step S1104 of FIG. 200, the A register value “3(D)” is stored in the payout amount data (_NB_PAY_MEDAL) of the address “F023(H)”.
In the next step S1105, the A register value "3(D)" is stored in the payout amount data buffer (_BF_PAY_MEDAL) at the address "F024(H)".
By the above processing, the payout amount “3(D)” is stored in the payout amount data (_NB_PAY_MEDAL) and the payout amount data buffer (_BF_PAY_MEDAL) when the small winning combination 17 is won.

As described above, first, it is determined whether or not any symbol combination forming the 15-card combination is stopped and displayed, and it is determined that any symbol combination forming the 15-card combination is not stopped and displayed. In case of doing, next, it is judged whether or not any of the symbol combinations constituting the three-card combination is stopped and displayed. Further, in the above example, since it is determined that the symbol combination corresponding to the small winning combination 19 which constitutes the three-role combination is stopped and displayed, the subsequent processing is not executed, but the three-role combination is temporarily configured. If it is determined that any of the symbol combinations to be stopped is not stopped and displayed, then it is determined whether or not any of the symbol combinations forming the one-card combination is stopped and displayed.
On the other hand, it is determined whether or not any of the symbol combinations forming the 15-card combination is stopped and displayed, and when it is determined that any of the symbol combinations forming the 15-card combination is stopped and displayed, the three-card combination is set. It is so arranged that it is not judged whether or not any one of the constituent symbols constituting the display is stopped and displayed. With this configuration, the processing time can be shortened.

In addition, whether or not any symbol combination forming the 15-card combination is stopped and displayed, two addresses of stop symbol data (5th group) (_WK_STOP_PIC5) and stop symbol data (6th group) (_WK_STOP_PIC6) Judgment is made based on data (however, for stop symbol data (sixth group), a part of bit data of the address). In this way, when the symbol combination data for giving the same payout number cannot be stored in one address, by arranging the addresses in succession, it is continuously determined whether or not there is the symbol combination data for paying out 15 cards, for example. Can be judged. In other words, between the stop symbol data (fifth group) and the stop symbol data (sixth group), an address for storing the symbol combination data forming the three-piece winning combination and the symbol combination data forming one winning combination Is not provided.

Furthermore, at the same address, the bits are consecutive for the same number of payouts. For example, when the bit for 15-card combination is "X" and the bit for 3-card combination is "Y", "XXYYYYXXX(B)" , The bit “Y” is not arranged between the plurality of bits “X”. If 15 bits in the same address, "X", and 3 bits in the same address, "Y", are arranged, for example, "XXXXXXYYYY(B)" or "YYYYXXXXXX(B)". ..
By arranging the bits in this way, it is possible to prevent an error in the number of paid-out sheets at the development stage.
In addition, it is possible to prevent the player from being disadvantaged by judging from the symbol combination with a large number of payouts. For example, although the winning number “10” is actually determined and the symbol combination corresponding to the small winning combination 01 is stopped and displayed, not only the bit corresponding to the small winning combination 01 but also the small winning combination 25 is displayed due to noise. Even if the corresponding bit is also "1", when judging from the symbol combination with a large number of payouts, it is judged the number of payouts at the time when it is judged that the symbol combination corresponding to the small win 01 is stopped and displayed. Since 15 is finished, 15 sheets corresponding to the small winning combination 01 can be paid out.

FIG. 202 is a flowchart showing RB operation management in the 25th embodiment. This process is a process corresponding to step S944 in FIG. 148 (23rd embodiment). As shown in FIG. 148, in the game end check process (M_GAME_CHK), when the RB operation state flag is not “0” (when “No” in step S943), RB operation management is executed.
The example of FIG. 202 is to update the number of winnings at the time of RB operation based on the stop symbol data.
In FIG. 202, in step S1201, it is determined whether the RB is operating. Here, it is determined whether or not the D4 bit of the operation state flag (_FL_ACTION) is "1", and when it is "1", it is determined that the RB is operating. When it is determined that the RB is operating, the process proceeds to step S1201, and when it is determined that the RB is not operating, the process according to this flowchart is ended.
In step S1202, "1" is subtracted from the number of games played during RB operation. This process is a process of subtracting "1" from the number of games played during RB operation (_CT_BONUS_PLAY).
In the next step S1203, it is determined whether or not the number of games played during RB operation is "0". This processing determines whether or not the zero flag has become "1" in the processing of step S1202, and when the zero flag is "1" means that the number of games during RB operation has become "0".
When the number of games played during RB operation is not "0", the process proceeds to step S1204, and when it is "0", the process proceeds to step S1211.

In the next step S1204, it is determined whether or not the stop symbol data (fifth group) (_WK_STOP_PIC5) is "0". When it is "0", the process proceeds to step S1205, and when it is not "0", the process proceeds to step S1209.
In step S1205, it is determined whether or not the stop symbol data (sixth group) (_WK_STOP_PIC6) is "0". When it is “0”, the process proceeds to step S1206, and when it is not “0”, the process proceeds to step S1209.
In the next step S1206, it is determined whether or not the stop symbol data (7th group) (_WK_STOP_PIC7) is "0". When it is "0", the process proceeds to step S1207, and when it is not "0", the process proceeds to step S1209.
In step S1207, it is determined whether or not the stop symbol data (8th group) (_WK_STOP_PIC8) is "0". When it is "0", the process proceeds to step S1208, and when it is not "0", the process proceeds to step S1209.
Next, in step S1208, it is determined whether or not the stop symbol data (9th group) (_WK_STOP_PIC9) is "0". If it is not "0", the process proceeds to step S1209, and if it is "0", the process according to this flowchart is ended.

In step S1209, "1" is subtracted from the number of winnings when the RB is activated. This process is a process of subtracting "1" from the winning count (_CT_BONUS_WIN) at the time of RB operation.
Next, proceeding to step S1210, it is determined whether or not the number of winnings during RB operation has become “0”. This process determines whether or not the zero flag has become "1" in the process of step S1209, and when the zero flag is "1" means that the number of winnings during RB operation has become "0".
Then, when the number of winnings during RB operation is not "0", the process according to this flowchart is ended, and when it is "0", the process proceeds to step S1211.

When the process proceeds to step S1211, the RB operation end flag is satisfied, so the RB operation state flag is cleared. This process is a process of setting the D4 bit of the operation state flag to "0". Then, the processing according to this flowchart is ended.
As described above, when updating the winning number at the time of RB operation, it is possible to update using the stop symbol data (fifth group) to the stop symbol data (9th group). When any of the stop symbol data (fifth group) to the stop symbol data (9th group) is not "0", a winning combination (any of the small winning combinations 01 to 34 in the present embodiment) has been won. This means that the condition for updating the number of winnings during RB operation is satisfied.

<Twenty-sixth Embodiment>
The 26th embodiment shows a modification of the 25th embodiment.
Further, in the twenty-sixth embodiment, the symbol array, the type of winning combination, the symbol combination corresponding to the winning combination, the number of payouts corresponding to the winning combination, and the definition data (FIGS. 176 to 179) are the same as those in the twenty-fifth embodiment.
FIG. 203 is a diagram showing the structure of the RWM 53 in the twenty sixth embodiment. The types of RWM 53 shown in FIG. 203 are those used in the following description, and are not meant to be limited to these.
In FIG. 203, the same storage area as that of the 25th embodiment (FIGS. 173 to 175) has the same address. The description of the storage area having the same address as that of the 25th embodiment will be omitted unless particularly necessary.

The symbol array address buffers 1 to 3 (_BF_PICARG_ADR1 to 3) shown at the addresses "F0A0 (H)" to "F0A5 (H)" are storage areas for storing addresses for specifying symbol combination data when the reel 31 is stopped. Is. The symbol array address buffer 1 (_BF_PICARG_ADR1) of "F0A0(H)" and "F0A1(H)" is for the first (left) reel 31, and the symbols of "F0A2(H)" and "F0A3(H)" The array address buffer 2 (_BF_PICARG_ADR2) is for the second (middle) reel 31, and the symbol array address buffer 3 (_BF_PICARG_ADR3) of "F0A4(H)" and "F0A5(H)" is the third (right) reel. It is for 31.
At the time of accepting the operation of the start switch 41, the start address “1200 (H)” of the symbol control data table (TBL_PIC_DAT) (described later) is stored in the symbol array address buffer.
Further, at the time of stop acceptance, any address of the # reel symbol search table (TBL_PICARG_#) (described later) is stored in the symbol array address buffer.

In FIG. 204, (A) is a diagram showing a symbol control data table (TBL_PIC_DAT), and (B) is a diagram showing a reel symbol search table address offset table (TBL_PIC_SRCH).
The data stored in each address of the symbol control data table corresponds to the initial values of the stop symbol data (first group) to the stop symbol data (9th group) of the twenty-fifth embodiment.
The symbol group (1st group-9th group) in 26th Embodiment is the same as 25th Embodiment. That is,
First group: RBA to RBH
Second group: RBJ to RBP
Third group: 1BB, Replay 01 to Replay 07
Group 4: Replay 08 to Replay 10 (D0 to D2), unused (D3 to D7)
Fifth group: Small Win 01 to Small Win 08
Group 6: Small Win 09 to Small Win 16
7th group: Small role 17 to Small role 24
8th group: Small role 25 to small role 32
Group 9: Small win 33 to small win 34 (D0 to D1), unused (D2 to D7)
Has become.

For example, the address "1200(H)" stores "11111111(B)", but this value corresponds to the initial value "11111111(B)" of the stop symbol data (first group).
Therefore, the data of the address "1203 (H)" (design 4 group) D4 to D7 bits, and the data of the address "1208 (H)" (design 9 group) D2 to D7 bits are "0", which The other bits are "1".

The reel symbol search table address offset table is a data table for specifying the start address of the # reel symbol search table (TBL_PICARG_#).
Details will be described later,
First reel symbol search table (TBL_PICARG_1): addresses "1300(H)" to "13B3(H)"
Second reel symbol search table (TBL_PICARG_2): addresses "13B4(H)" to "1467(H)"
Third reel symbol search table (TBL_PICARG_3): addresses "1468 (H)" to "151B (H)"
It consists of
In the reel symbol search table address offset table, the address value immediately before the start address of the # reel symbol search table (TBL_PICARG_#) is specified.

205 to 209 are diagrams showing the first reel symbol search table (TBL_PICARG_1).
210 to 214 are diagrams showing a second reel symbol search table (TBL_PICARG_2).
Further, FIGS. 215 to 219 are diagrams showing a third reel symbol search table (TBL_PICARG_3).
In the # reel symbol search table (TBL_PICARG_#), for each reel 31, with respect to the symbol number of the symbol stopped on the activated line, which role the symbol corresponding to the symbol of the symbol number corresponds to the symbol of the # reel 31 is. Is defined for all of the first to ninth groups.
The symbol combination data stored in each address of these # reel symbol search table (TBL_PICARG_#) is the symbol combination stored in each address of the # reel symbol combination table (TBL_PICCMB_#) in the 25th embodiment. It is similar to the data.

Regarding the left reel 31, when the control symbol number (BF_PICTURE) is "0", the symbol on the activated line corresponds to the symbol number "cherry". Therefore, after the address "1300(H)",
Address "1300 (H)" to "1308 (H)": No. 2 symbol "cherry" (first group to ninth group)
Address "1309 (H)" to "1311 (H)": No. 3 symbol "blue BAR" (first group to ninth group)
Address "1312 (H)" to "131A (H)": 4th symbol "Bell A" (first group to ninth group)
:
Address "1399 (H)" to "13A1 (H)": 19th symbol "Bell A" (first group to ninth group)
Address "13A2(H)" to "13AA(H)": No. 0 symbol "Replay" (first group to ninth group)
Address "13AB (H)" to "13B3 (H)": 1st symbol "Watermelon" (1st to 9th groups)
The first reel symbol search table is configured in this order.

Further, 9 addresses are assigned to each symbol, which correspond to the first to ninth groups, respectively. For example, in the second pattern "Cherry",
The address "1300(H)" is the first group,
The address "1301(H)" is the second group,
:
The address "1308(H)" is assigned to the ninth group.
Therefore, in the first reel symbol search table (TBL_PICARG_1), the number of symbols “20”×the number of symbol groups “9”=“180” addresses (1300(H) to 13B3(H)) are assigned. The same applies to the second reel symbol search table (TBL_PICARG_2) and the third reel symbol search table (TBL_PICARG_3).

Further, the symbol combination data stored in each address is such that when the reel 31 stops, when the symbol with that symbol number stops on the activated line, in the symbol group of the Nth group, the symbol combination of which symbol constitutes the symbol combination. It defines what can be.
For example, the symbol combination data of the address "1300(H)" is "0", but this is when the second "Cherry" stops on the activated line when the left reel 31 stops, the winning combination of the first group (RBA). ~RBH) means that it cannot be a symbol constituting a symbol combination.
On the other hand, the symbol combination data of the address "1307(H)" (8th group) is "@WIN_27 OR WIN_30" (00100100(B)). Therefore, when the second "cherry" is stopped when the left reel 31 is stopped, it means that it can be a symbol that constitutes the symbol combination of the small winning combination 27 and the small winning combination 30 of the eighth group. (See Figure 121).
Therefore, the same symbol on the same reel 31 has the same symbol combination data. Specifically, for example, in FIG. 205, addresses “131B(H)” to “1323(H)” store the symbol combination data for the fifth symbol “replay”, but with the same “replay” symbol. Certain addresses "1348 (H)" to "1350 (H)" (No. 10 symbol "Replay"), addresses "1375 (H)" to "137D (H)" (No. 15 symbol "Replay"), address "13A2" (H)” to “13AA(H)” (No. 0 symbol “replay”) are also the same as the symbol combination data of the addresses “131B(H)” to “1323(H)”.

As described above, the first reel symbol search table (TBL_PICARG_1) stores symbol combination data from the second symbol (cherry). This is because when the control symbol number (BF_PICTURE) is "0", the symbol on the activated line on the left reel 31 is number 2.
On the other hand, in the second reel symbol search table (TBL_PICARG_2) shown in FIGS. 210 to 214, symbol combination data from the first symbol “cherry” is stored. This is because when the control symbol number (BF_PICTURE) is "0", the symbol on the activated line in the middle reel 31 becomes 1.
Similarly, in the third reel symbol search table (TBL_PICARG_3), the symbol combination data is stored from the 0th symbol "bell B". This is because when the control symbol number (BF_PICTURE) is “0”, the symbol on the activated line on the right reel 31 becomes 0.
In this way, the symbol data stored in the left, middle, and right reel symbol search tables is stored with an offset (difference) (shifting the symbol number) (stored in consideration of the difference). By setting), it becomes unnecessary to perform correction (add or subtract difference) for each acquired control symbol number (BF_PICTURE). Therefore, the program processing can be simplified and the capacity of the ROM 54 can be reduced.
As shown in FIG. 229 (Example 2 of 27th embodiment) described later, in each of the symbol array tables of the left reel 31, the middle reel 31, and the right reel 31, the symbol data of the symbol number “0” There is also a method of sequentially storing the difference data corresponding to each reel 31 from the beginning. Then, when acquiring the symbol data, the difference data of the reel 31 is added to or subtracted from the symbol number of the symbol stopped at the reference position to obtain the symbol data of the symbol on the activated line. In this case, even if there is a change in the effective line, only the difference data needs to be changed, so that the development man-hours can be reduced.

Since the effective line of this embodiment is as shown in FIG. 115, the offset (difference) is set to “+2” for the left reel 31 and for the middle reel 31 in the left, middle, and right reel symbol search tables. “+1” and the right reel 31 are set to “0”. In other words, the offset value indicates the amount of deviation (number of steps) between the position of the effective line and the reference position.
Therefore, for example, when the control symbol number (BF_PICTURE) shows a symbol that stops at the bottom, and the active line is "left middle"-"middle middle"-"right middle", each of the left, middle and right reels In the symbol search table, each offset is “+1”.
Further, for example, when the control symbol number (BF_PICTURE) shows a symbol that stops in the middle stage, and the effective line is "left middle stage"-"middle middle stage"-"right middle stage", each of the left, middle and right reels In the symbol search table, the offset is unnecessary (or "0").

Next, a specific example of the symbol array address buffer in the 26th embodiment will be described.
For example, assume that "Replay (No. 5)"-"Cherry (No. 16)"-"Bell B (No. 0)" stops on the activated line.
In this case, in the symbol array address buffer 1 (_BF_PICARG_ADR1), the first address "131A (H)" of the first address "131B (H)" of the fifth symbol (replay) of the first reel symbol search table (TBL_PICARG_1) Is stored.
Further, in the symbol array address buffer 2 (_BF_PICARG_ADR2), the first address "143A(H)" of the first address "143B(H)" of the 16th symbol (cherry) of the second reel symbol search table (TBL_PICARG_2) Is memorized.
Furthermore, in the symbol array address buffer 3 (_BF_PICARG_ADR3), the first address "1467 (H)" of the first address "1468 (H)" of the 0th symbol (bell B) of the third reel symbol search table (TBL_PICARG_3) is "1467 (H )” is stored.
It should be noted that what kind of processing is performed to store the above value will be described later.

220 and 221 are diagrams showing a payout amount table (TBL_WIN_CTL) in the twenty-sixth embodiment.
In the twenty-sixth embodiment, one address is provided for every combination and the number of payouts is stored. The address "1600 (H)" is set to the payout number "0" of the RBA of the symbol 1 group, and the addresses of all the winning combinations of the symbol 1 group, all the winning combinations of the symbol 2 group,... It is provided and stores the number of payouts.
In the group of symbols 4, in order to correspond to the bits, the addresses “1618(H)” to “161A(H)” are set as the replay 08, the replay 09, and the replay 10 corresponding to the D0 to D2 bits, and the address “161B( H)" to "161F(H)" are unused areas corresponding to the D3 to D7 bits.
Then, for example, when winning the small prize 01, the address "1620(H)" is specified, and "15(D)" stored in the address "1620(H)" is the payout number. It is stored in the data (_NB_PAY_MEDAL).

Next, the control processing in the twenty-sixth embodiment will be described using a flowchart.
FIG. 222 is a flowchart showing main processing in the twenty-sixth embodiment. The flowchart in FIG. 222 mainly shows the process according to the twenty-sixth embodiment, and does not mean that only the process shown in FIG. 222 is performed.
The main process is a process executed by the main control board 50 once per game, and is, for example, a process corresponding to FIG. 139 of the 23rd embodiment.
In FIG. 222, the game start time processing of step S1131 is processing corresponding to steps S271 and S272 in FIG. 139, and executes operation state flag update processing and the like (see, for example, FIG. 42).
In the next step S1132, a medal acceptance start time process is executed. This process is, for example, the process shown in steps S273 to S276 of FIG. 139, and it is a process of detecting whether or not a medal has been inserted or whether or not the bet switch 40 has been operated, or when a medal has been inserted or when the bet switch 40 has been inserted. When is operated, the bet number is updated.

In the next step S1133, start switch acceptance processing is executed. This process is a process shown in FIG. 223 described later, and the same process as step S751 of FIG. 139 is executed. Specifically, when it is determined that the start switch 41 has been operated, a predetermined lottery process or the like is executed. However, in FIG. 223 described later, the processing illustrated in FIG. 140 is simplified and described.
Next, proceeding to step S1134, the rotation of the reel 31 is started. In the next step S1135, reel stop control is performed. This process is a process shown in FIG. 225, which will be described later, and is a process for stopping the corresponding reel 31 at a predetermined position based on the winning number when the operation of the stop switch 42 is detected.
In the next step S1136, it is determined whether or not all reels 31 are stopped (corresponding to step S289 in FIG. 139). When it is determined that all reels 31 are stopped, the process proceeds to step S1137, and all reels 31 are stopped. If it is determined that there is not, the process returns to step S1135.

In step S1137, display determination processing is performed. This process is a process shown in FIG. 227 described later and is a process corresponding to step 291 of FIG. 139.
In the next step S1138, a game end check process is performed. This process is a process corresponding to step 753 in FIG. 139. Then, the processing according to this flowchart is ended.

FIG. 223 is a flow chart showing the start switch reception time process in step S1133 of FIG. 222.
In FIG. 223, in step S1141, a game start time process is executed. This process is a process for executing a lottery for the winning number (winning combination), a lottery for the advantageous section (AT), and the like, and corresponds to the process including the processes of steps S761 to S768 in FIG.
In the next step S1142, reel rotation start preparation processing is executed. This process is a process shown in FIG. 224, which will be described later, and is a process of setting initial values in the above-mentioned symbol array address buffers 1 to 3 (_BF_PICARG_ADR1 to 3). Then, the processing according to this flowchart is ended.

FIG. 224 is a flowchart showing the reel rotation start preparation processing in step S1142 of FIG. 223.
In FIG. 224, in step S1151, the symbol control data table (TBL_PIC_DAT) is set. This process is a process of storing the head address "1200 (H)" of the symbol control data table in the HL register.
Next, proceeding to step S1152, the address of the symbol control data table is stored in the symbol array address buffer 1 (_BF_PICARG_ADR1). This process is a process of storing the HL register value (1200 (H)) in the symbol array address buffer 1 of the address "F0A0 (H)".
In the next step S1153, the address of the symbol control data table is stored in the symbol array address buffer 2 (_BF_PICARG_ADR2). This process is a process of storing the HL register value (1200 (H)) in the symbol array address buffer 2 of the address "F0A2 (H)".
In the next step S1154, the address of the symbol control data table is stored in the symbol array address buffer 3 (_BF_PICARG_ADR3). This process is a process of storing the HL register value (1200 (H)) in the symbol array address buffer 3 of the address “F0A4 (H)”. Then, the processing according to this flowchart is ended.
By the above processing, as the initial value at the start of reel rotation,
Symbol array address buffer 1 (_BF_PICARG_ADR1 ): 1200 (H)
Symbol array address buffer 2 (_BF_PICARG_ADR2 ): 1200 (H)
Symbol array address buffer 3 (_BF_PICARG_ADR3 ): 1200 (H)
Is memorized.

FIG. 225 is a flowchart showing reel stop control in step S1135 of FIG. 222.
In FIG. 225, in step S1161, it is determined whether or not the stop switch 42 has been operated for the spinning reel 31. Although detailed description of this processing is omitted, as shown in FIG. 194 of the twenty-fifth embodiment, the input port rising data A is detected, and the rising data of the stop switch 42 corresponding to the spinning reel 31 is turned on. If YES, it is determined to be “Yes” in step S1161.
When it is determined in step S1161 that the stop switch 42 has been operated, the processing proceeds to step S1162, and when it is determined that the stop switch 42 has not been operated, the processing according to this flowchart ends.

In step S1162, the value corresponding to the (operated) stop switch 42 is stored in the stop/control reel number data (_NB_STOP_REEL). For example, with the left stop switch 42, "1" is stored.
In the next step S1163, a stop symbol determination process is executed. This process is a process of determining the stop position of the reel 31 based on the timing when the stop switch 42 is operated, the winning number in the game, and the like. By this processing, the symbol number to be stopped in the middle stage is stored in the # reel symbol number (for stop position) (_NB_RL#_STPPIC).
In the next step S1164, the symbol number is stored in the control symbol number (_BF_PICTURE). In this process, the control symbol number (_BF_PICTURE) is calculated by subtracting "1" from the # reel symbol number (for stop position) (_NB_RL#_STPPIC) and stored. In addition, in the calculation, when "1" is subtracted from "0", the special calculation which becomes "19(D)" is executed.
Next, proceeding to step S1165, a symbol array address buffer is set. This process is a process shown in FIG. 226 which will be described later, and is a process of acquiring and storing the reel symbol array table address. Then, the processing according to this flowchart is ended.

FIG. 226 is a flowchart showing the symbol array address buffer set in step S1165 of FIG. 225.
226, in step S1171, stop/control reel number data is acquired. This process is a process of storing the value stored in the stop/control reel number data (_NB_STOP_REEL) in the A register.
Next, proceeding to step S1172, the RWM address is set in the symbol array address buffer corresponding to the stop/control reel number data. Here, the following processing is executed.
(1) The A register value and the A register value are added, and the addition result is taken as the A register value. In other words, the process is a process of doubling the A register value.
(2) The address “F09E(H)” value shifted by “2” address from the address “F0A0(H)” of the symbol array address buffer 1 (_BF_PICARG_ADR1) is stored in the DE register.
(3) Add the A register value to the DE register value. The result of the addition is set as the DE register value.
Thus, for example, when the stop/control reel number data (_NB_STOP_REEL) is "1", the DE register value becomes "F0A0(H)".
When the stop/control reel number data (_NB_STOP_REEL) is "2", the DE register value is "F0A2(H)".
Furthermore, when the stop/control reel number data (_NB_STOP_REEL) is "3", the DE register value is "F0A4(H)".
By the processing of step S1172, the DE register stores the address of the symbol array address buffer (_BF_PICARG_ADR#) corresponding to the reel 31.

In the next step S1173, the reel symbol search table address offset table is set. This process is a process of storing a value "1207 (H)" obtained by subtracting "2" from the start address "1209 (H)" of the reel symbol search table address offset table (TBL_PIC_SRCH) in the HL register.
In the next step S1174, a reel symbol arrangement table address corresponding to the stop/control reel number data is acquired. Here, the following processing is executed.
(1) The A register value is added to the HL register value, and the addition result is set as the HL register value.
For example, when the A register value is "2", the HL register value is "1209 (H)".
When the A register value is "4", the HL register value is "120B(H)".
Furthermore, when the A register value is "6", the HL register value is "120D(H)".
Therefore, the address of the reel symbol search table address offset table (TBL_PIC_SRCH) corresponding to the reel 31 is stored in the HL register (see FIG. 204(B)).

(2) The data stored in the address indicated by the HL register value is stored in the HL register value.
For example, when the HL register value is "1209 (H)", the HL register value is "12FF (H)".
When the HL register value is "120B(H)", the HL register value is "13B3(H)".
Furthermore, when the HL register value is "120D(H)", the HL register value is "1467(H)".

Next, proceeding to step S1175, the reel symbol array table address corresponding to the control symbol number is acquired. Here, the following processing is executed.
(1) The data stored in the control symbol number (_BF_PICTURE) is stored in the A register.
(2) The A register value is multiplied by “9” and the calculation result is stored in the A register. Here, multiplying by “9” corresponds to the number of symbol groups.
(3) The A register value is added to the HL register value, and the addition result is used as the HL register value.

The above process will be described with specific examples (Examples 1 to 3).
(Example 1)
In the left reel 31, when the control symbol number (_BF_PICTURE) is "10" (the "bell B" of number 12 stops on the activated line),
12FF(H)+10×9(D)(5A(H))=1359(H)
Is the address immediately before the head address "135A(H)" corresponding to the 12th "bell B" of the left reel 31.
(Example 2)
In the middle reel 31, when the control symbol number (_BF_PICTURE) is "10" (the 11th "cherry" stops on the activated line),
13B3(H)+10×9(D)=140D(H)
Therefore, the address is one address before the head address “140E(H)” corresponding to the 11th “cherry” on the middle reel 31.
(Example 3)
Furthermore, in the right reel 31, when the control symbol number (_BF_PICTURE) is "10" (the 10th "bell B" stops on the activated line),
1467 (H) + 10 x 9 (D) = 14C1 (H)
Therefore, the address is one address before the head address “14C2(H)” corresponding to the tenth “bell B” of the right reel 31.
Thus, in step S1175, the first address value of the head address corresponding to the stop symbol number of the reel 31 is stored in the HL register.

Next, proceeding to step S1176, a symbol array address buffer corresponding to the stop/control reel number data (_NB_STOP_REEL) is acquired. This process is a process of storing the HL register value at the address indicated by the DE register value.
Note that, as shown in step S1172,
Stop/control reel number data “1” → DE register value “F0A0(H)”
Stop/control reel number data “2” → DE register value “F0A2(H)”
Stop/control reel number data “3” → DE register value “F0A4(H)”
Is.
Therefore, in the case of the left reel 31, in the example 1, “1359 (H)” is stored in the symbol array address buffer 1 of the address “F0A0 (H)”.
Further, in the case of the middle reel 31, in the above-described example 2, “140D(H)” is stored in the symbol array address buffer 2 of the address “F0A2(H)”.
Furthermore, in the case of the right reel 31, in the example 3, “14C1(H)” is stored in the symbol array address buffer 3 of the address “F0A4(H)”.
Then, the processing according to this flowchart is ended.

As described above, since the symbol array address buffer of each reel stores the address value in which the symbol combination data is stored, even if the power is cut off, it is already stored after returning from the power cut. The game can be correctly restarted using the existing address value.
For example, in a situation where all reels 31 are rotating at a constant speed, power is cut off after the stop switch 42 corresponding to the left reel 31 is operated, and even if the power cut process is executed, the symbol Since the array address buffer 1 stores the address value where the symbol combination data of the left reel 31 is stored, after the power is restored, based on the stop operation of the middle reel 31 and the stop operation of the right reel 31, The process of storing the address values in the symbol array address buffers 2 and 3 can be restarted (the game can be restarted).

In addition, when the address value (the value stored in the symbol array address buffer) where the symbol combination data is stored is stored in the general-purpose register, the power is cut off, and when the power is restored after that, the address is stored. The value (value stored in the general-purpose register) is cleared (set to the initial value, for example, set to "0"). Therefore, when the address value in which the symbol combination data is stored is stored in the general-purpose register, the power is cut off after the stop switch 42 corresponding to the left reel 31 is operated, and the power cut processing is executed. In this case, there is a high possibility that the game cannot be restarted after the power is restored.
Further, when the symbol array address buffer is provided in the RWM 53 and the address value where the symbol combination data is stored is stored, the address value is stored in the symbol array address buffer each time the stop switch 42 is stopped. At the development stage, it is possible to confirm whether or not the stop position is correct for each stop operation by inspecting the symbol array address buffer of the RWM 53.

FIG. 227 is a flowchart showing the display determination processing in step S1137 of FIG. 222.
This process is a process of determining the symbol combination data based on the address value stored in the symbol array address buffer, and determining whether or not the winning combination corresponding to the symbol combination data has a payout.
In FIG. 227, in step S1181, “9” is set to the number of symbol groups. In this process, "9" is stored in the B register and "8" is stored in the C register. “8” in the C register is a value corresponding to the number of bits.
In the next step S1182, the symbol array address buffer 1 (_BF_PICARG_ADR1) is acquired. This process is a process of storing the symbol combination data stored in the symbol array address buffer 1 in the HL register.

Next, proceeding to step S1183, the first reel symbol arrangement table data corresponding to the number of symbol groups is acquired. Here, the following processing is executed.
(1) The B register value is added to the HL register value, and the addition result is used as the HL register value.
(2) The symbol combination data stored in the address indicated by the HL register value is stored in the A register value.
For example, when the HL register value is “12FF(H)”, it becomes “12FF(H)+9(H)=1308(H)”, so “@WIN_33” stored at the address “1308(H)” is stored. That is, “00000001(B)” is stored in the A register.

In the next step S1184, the symbol array address buffer 2 (_BF_PICARG_ADR2) is acquired. This process is a process of storing the symbol combination data stored in the symbol array address buffer 2 in the HL register.
Next, proceeding to step S1185, a logical product of the second reel symbol arrangement table data according to the number of symbol groups is executed. Here, the following processing is executed.
(1) The B register value is added to the HL register value, and the addition result is used as the HL register value.
(2) An AND (logical product) operation of the symbol combination data stored at the address indicated by the HL register value and the A register value is executed. The calculation result is used as the A register value.

In the next step S1186, the symbol array address buffer 3 (_BF_PICARG_ADR3) is acquired. This process is a process of storing the symbol combination data stored in the symbol array address buffer 3 in the HL register.
Next, proceeding to step S1187, a logical product of the third reel symbol array table data according to the number of symbol groups is executed. Here, the following processing is executed.
(1) The B register value is added to the HL register value, and the addition result is used as the HL register value.
(2) An AND (logical product) operation of the symbol combination data stored at the address indicated by the HL register value and the A register value is executed. The calculation result is used as the A register value.
At this point, if the calculation result is "0", the zero flag becomes "1".

By the processing of steps S1181 to S1187, when the B register value is “9”, for example, the symbol combination data of the ninth group of the stop symbol data of the left reel 31 and the ninth stop symbol data of the middle reel 31 The symbol combination data of the group and the symbol combination data of the ninth group of the stop symbol data of the right reel 31 will be ANDed.
Specifically, for example,
B register value = 9
Symbol array address buffer 1 (_BF_PICARG_ADR1) = 12FF (H) (No. 2 symbol (cherry))
Symbol array address buffer 2 (_BF_PICARG_ADR2) = 13B3 (H) (No. 1 symbol (cherry))
Symbol array address buffer 3 (_BF_PICARG_ADR3) = 1482 (H) (3rd symbol (red 7))
When
Design combination data of address "1308(H)" (@WIN_33)
AND
Design combination data of address "13BC(H)" (@WIN_33)
AND
Design combination data of address "148B(H)" (@WIN_33)
Thus, the logical product data becomes "@WIN_33" (00000001(B)).
On the other hand, if any of the symbol combination data among the symbol combination data of the address “1308(H)”, the address “13BC(H)”, or the address “148B(H)” is “0”, AND The logical product data becomes "0" by the calculation.

Next, proceeding to step S1188, it is determined whether the logical product data is "0". In this process, it is determined whether or not the zero flag is "1", and when the zero flag is "1", "Yes" is determined. If it is determined that the logical product data is "0", the process proceeds to step S1195, and if it is determined that the logical product data is not "0", the process proceeds to step S1189.
In step S1195, "1" is subtracted from the number of symbol groups. This process executes a process of subtracting "1" from the B register value.
In the next step S1196, it is determined whether or not the number of symbol groups has become “0”. This processing determines whether or not the result of subtracting "1" from the B register in step S1195 is "0". When the B register value after subtracting "1" is "0", it is determined to be "Yes" (the number of symbol groups has become "0").
When it is determined in step S1196 that the number of symbol groups is “0”, the process according to this flowchart is ended. On the other hand, when it is determined that the number of symbol groups is not “0”, the process returns to step S1182.

On the other hand, if the process proceeds from step S1188 to step S1189, the payout number table address corresponding to the number of symbol groups is set. Here, the following processing is executed.
(1) The B register value is multiplied by the C register value “8”. Then, the multiplication result is stored in the BC register.
(2) "8" is subtracted from the start address "1600(H)" of the payout number table (TBL_WIN_CTL) and the result of subtracting "1" is stored in the HL register. Therefore, "15F7(H)" is stored in the HL register.
(3) The BC register value is added to the HL register value.
Next, proceeding to step S1190, "1" is added to the table address. This process is a process of adding “1” to the HL register value and setting the addition result as the HL register value.

Here, in steps S1189 and S1190,
"1600 (H)"-"8 (H)"-"1 (H)" + B register value (value of symbol group) x C register value "8" (number of data included in one symbol group) + "1"(H)"
= "1600 (H)" + (value of symbol group-1) x (number of data "8" included in one symbol group)
Is being calculated.
Examples 1 and 2 are given below as specific examples.
(1) Example 1
When the B register value at the time of proceeding to step S1189 is “1” (symbol 1 group),
1600(H)+(1-1)×8=1600(H)
And the top address of the group of symbols is designated.
(2) Example 2
When the B register value at the time of proceeding to step S1189 is “5” (symbol 5 group),
1600(H)+(5-1)×8=1600(H)+20(H)(32(D))
= 1620 (H)
And the leading address of the group of symbols 5 is designated.

In the next step S1191, the logical product data is shifted to the right by "1". This process is a process of shifting the bit of the A register value to the right by "1".
Then, in the next step S1192, it is determined whether or not the carry flag becomes "1" by the process of shifting "1" to the right. When it is determined that the carry flag has become "1", it is determined to be "Yes" and the flow proceeds to step S1193. On the other hand, when it is determined that the carry flag is not "1", the process returns to step S1190.

In step S1193, it is determined whether the payout number is “0”. This processing determines whether or not the data stored at the address indicated by the HL register value is "0", and when it is "0", the payout amount is determined to be "0". When it is determined that the number of payouts is "0", the processing according to this flowchart is ended. On the other hand, when it is determined that the number of payouts is not “0”, the process proceeds to step S1194.
In step S1194, the payout amount data is stored. This process is a process of storing the value indicated by the address indicated by the HL register value in the payout amount data (_NB_PAY_MEDAL). Then, the processing according to this flowchart is ended.

Examples 1 and 2 will be given as specific examples of steps S1190 to S1192.
(1) Example 1 (when the small combination 33 symbol combination is stopped)
In the first step S1190, when the B register value is "9" and the logical product data is "@WIN_33" (00000001(B)), the HL register value is "1640(H)".
When the logical product data "00000001(B)" is shifted to the right by 1 bit in the next step S1191, the carry flag becomes "1", and therefore, "Yes" is determined in step S1192. Therefore, in step S1194, the data “1” stored at the address “1640(H)” indicated by the HL register value is stored as the payout amount data.

(2) Example 2 (when the symbol combination of the small role 03 is stopped)
In the first step S1190, when the B register value is "5" and the logical product data is "@WIN_03" (00000100(B)), the HL register value is "1620(H)".
When the logical product data “00000100(B)” is right-shifted by 1 bit to “00000010(B)” in the next step S1191, the carry flag is “0”, so that it is determined as “No” in step S1192. , And returns to step S1190.
In step S1190 (second time), the HL register value becomes "1621(H)". In the next step S1191, if the logical product data “00000010(B)” is right-shifted by 1 bit to be “00000001(B)”, the carry flag is “0”, so it is determined as “No” in step S1192. Then, the process returns to step S1190.
In step S1190 (third time), the HL register value becomes "1622(H)". In the next step S1191, when the logical product data “00000001(B)” is shifted to the right by 1 bit, the carry flag becomes “1”, and thus in step S1192, it is determined as “Yes”. Therefore, in step S1194, the data “15(D)” stored at the address indicated by the HL register value “1622(H)” is stored as the payout amount data.

The display determination process described above will be described with reference to specific examples (first and second examples below).
(Example 1)
In the game determined by the winning number “10” by the role lottery, the left stop switch 42 is operated when the symbol of the symbol number “10” is passing through the middle stage of the left reel 31, and then the middle reel 31 The middle stop switch 42 is operated when the symbol of the symbol number "9" is passing through the middle stage, and then the right stop switch 42 is passed when the symbol of the symbol number "3" is passing through the middle stage of the right reel 31. "Watermelon (No.11)"-"Cherry (No.11)"-"Bell A (No.4)" stopped on the activated line due to the operation of, and small win 01 (15 pieces) was won. To do.
In this case, the symbol array address buffer set of FIG. 226 is as follows.
1. Left reel 31
In step S1171, the A register value=“1” (stop/control reel number data).
In step S1172,
(1) A register value=1×2=2
(2) DE register value=F09E(H)
(3) DE register value=DE register value+A register value=F0A0 (H)
In step S1173,
HL register value=1207 (H)
Becomes
In step S1174,
(1) HL register value=HL register value+A register value=1209 (H)
(2) HL register value=address value indicated by HL register value=12FF(H)
Becomes
In step S1175,
(1) A register value = "9" (control symbol number (_BF_PICTURE))
(2) A register value = A register value x 9 = 81 (D) (51 (H))
(3) HL register value=HL register value+A register value=1350 (H)
Becomes

2. Middle reel 31
In step S1171, the A register value=“2” (stop/control reel number data).
In step S1172,
(1) A register value=2×2=4
(2) DE register value=F09E(H)
(3) DE register value=DE register value+A register value=F0A2(H)
In step S1173,
HL register value=1207 (H)
Becomes
In step S1174,
(1) HL register value=HL register value+A register value=120B (H)
(2) HL register value=value of address indicated by HL register value=13B3(H)
Becomes
In step S1175,
(1) A register value = "10 (D)" (control symbol number (_BF_PICTURE))
(2) A register value = A register value x 9 = 90 (D) (5A (H))
(3) HL register value=HL register value+A register value=140D (H)
Becomes

3. Right reel 31
In step S1171, the A register value=“3” (stop/control reel number data).
In step S1172,
(1) A register value=3×2=6
(2) DE register value=F09E(H)
(3) DE register value=DE register value+A register value=F0A4 (H)
In step S1173,
HL register value=1207 (H)
Becomes
In step S1174,
(1) HL register value=HL register value+A register value=120D (H)
(2) HL register value=value of address indicated by HL register value=1467 (H)
Becomes
In step S1175,
(1) A register value = "4 (D)" (control symbol number (_BF_PICTURE))
(2) A register value=A register value×9=36 (D) (24 (H))
(3) HL register value=HL register value+A register value=148B(H)
Becomes

From the above,
Symbol array address buffer 1: 1350 (H)
Symbol array address buffer 2: 140D (H)
Symbol array address buffer 3:148B(H)
Becomes
In this case, in step S1181 in FIG.
B register value = 9
C register value = 8
Set.
(First time)
In step S1182,
HL register value=1350 (H) (value of symbol array address buffer 1)
Becomes
In the next step S1183,
HL register value=1350(H)+9(H)(HL+B)=1359(H)
A register value = 0 (value stored at the address indicated by the HL register value)
Becomes

In the next step S1184,
HL register value=140D(H) (value of symbol array address buffer 2)
Becomes
In the next step S1185,
HL register value=140D(H)+9(H)(HL+B)=1416(H)
Data indicated by address of HL register value =00000001(B) (@WIN_33)
A register value = data indicated by the address of the HL register value (@WIN_33) AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+9(H)(HL+B)=1494(H)
A register value = HL register value (@WIN_34) AND A register value = 0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=9-1=8
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(Second time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350(H)+8(H)(HL+B)=1358(H)
A register value = 00011010 (B) (@WIN_26 OR @WIN_28 OR @WIN_29)
Becomes

In step S1184,
HL register value=140D(H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=140D(H)+8(H)(HL+B)=1415(H)
Data indicated by HL register value address = 00110000 (B) (@WIN_29 OR @WIN_30)
A register value = data indicated by the address of the HL register value AND A register value = 00010000 (B)
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+8(H)(HL+B)=1349(H)
Data indicated by HL register value address = 00001000 (B) (@WIN_28)
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=8-1=7
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(3rd time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350 (H)+7 (H) (HL+B)=1357 (H)
A register value =00000011 (B) (@WIN_17 OR @WIN_18)
Becomes

In step S1184,
HL register value=140D(H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=140D(H)+7(H)(HL+B)=1414(H)
Data indicated by HL register value address = 0000010 (B) (@WIN_18)
A register value = data indicated by the address of the HL register value AND A register value =00000010(B)
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+7(H)(HL+B)=1492(H)
Data indicated by the address of the HL register value = 0
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value = 7-1 = 6
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(4th time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350 (H)+6 (H) (HL+B)=1356 (H)
A register value =00000010 (B) (@WIN_10)
Becomes

In step S1184,
HL register value=140D(H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=140D(H)+6(H)(HL+B)=1413(H)
Data indicated by the address of the HL register value = 0
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+6(H)(HL+B)=1491(H)
Data indicated by HL register value address = 00110000 (B) (@WIN_13 OR @WIN_14)
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=6-1=5
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(5th time)
In step S1182, the HL register value=1350 (H) (the value of the symbol array address buffer 1) is set. In step S1183,
HL register value=1350(H)+5(H)(HL+B)=1355(H)
A register value = 11001011 (B) (@WIN_01_02 OR @WIN_04 OR @WIN_07_08)
Becomes

In step S1184,
HL register value=140D(H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value = 140D (H) + 5 (H) (HL + B) = 1412 (H)
Data indicated by address of HL register value = 01000001 (B) (@WIN_01 OR @WIN_07)
A register value = data indicated by the address of the HL register value AND A register value = 01000001 (B)
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+5(H)(HL+B)=1490(H)
Data indicated by the address of the HL register value = 00001101(B) (@WIN_01 OR @WIN_03 OR @WIN_04)
A register value=data indicated by the address of the HL register value AND A register value=00000001(B)
Becomes
Therefore, the zero flag≠“1”.
Therefore, “No” is obtained in step S1188, and the process proceeds to step S1189.
In step S1189,
BC register value=B register value (value of symbol group)×C register value (number of data included in one symbol group)=5×8=40 (D) (28 (H))
HL register value=15F7(H)
HL register value=HL register value+BC register value=15F7(H)+28(H)=161F(H)
Becomes

In step S1190,
HL register value=161F(H)+1(H)=1620(H)
Becomes
In step S1191, the A register value “00000001(B)” is shifted to the right by 1 to become “00000000(B)” and the carry flag becomes “1”.
In step S1192, the carry flag is "1", so "Yes" is determined and the process proceeds to step S1193.
In step S1193,
Data indicated by the address of the HL register value=15 (D)
Therefore, it is determined that the number of payouts is not “0”, and the process proceeds to step S1194.
In step S1194, “15(D)” is stored in the payout amount data (_NB_PAY_MEDAL).
As described above, the address “1620(H)” of the payout amount table (TBL_WIN_CTL) is specified and the payout amount “15(D)” is stored when the small prize 01 is won.

Next, as a second example of the display determination process, in the game in which the winning number “26” is determined by the winning lottery, the left stop is performed when the symbol of the symbol number “10” is passing through the middle stage of the left reel 31. The switch 42 is operated, and then the middle stop switch 42 is operated when the symbol of the symbol number "2" is passing through the middle stage of the middle reel 31, and then the middle stage of the right reel 31 is changed to the symbol number "3". By operating the right stop switch 42 while the symbol is passing, "Watermelon (No. 11)"-"Black BAR (No. 3)"-"Bell A (No. 4)" stops on the effective line. The following shows an example of winning a non-win prize. This symbol combination differs from the symbol combination of the first example only in the symbol of the middle reel 31.
First, the middle reel 31 is as follows by the symbol array address buffer set of FIG. 226.

In step S1171, the A register value=“2” (stop/control reel number data).
In step S1172,
(1) A register value=2×2=4
(2) DE register value=F09E(H)
(3) DE register value=DE register value+A register value=F0A2(H)
In step S1173,
HL register value=1207 (H)
Becomes
In step S1174,
(1) HL register value=HL register value+A register value=120B (H)
(2) HL register value=value of address indicated by HL register value=13B3(H)
Becomes
In step S1175,
(1) A register value = "2 (D)" (control symbol number (_BF_PICTURE))
(2) A register value = A register value x 9 = 18 (D) (12 (H))
(3) HL register value=HL register value+A register value=13C5 (H)
Becomes

Therefore,
Symbol array address buffer 1: 1350 (H)
Symbol array address buffer 2:13C5(H)
Symbol array address buffer 3:148B(H)
Becomes
In this case, in step S1181 in FIG.
B register value = 9
C register value = 8
Set.
(First time)
In step S1182,
HL register value=1350 (H) (value of symbol array address buffer 1)
Becomes
In the next step S1183,
HL register value=1350(H)+9(H)(HL+B)=1359(H)
A register value = 0 (value stored at the address indicated by the HL register value)
Becomes

In the next step S1184,
HL register value=135C(H) (value of symbol array address buffer 2)
Becomes
In the next step S1185,
HL register value=13C5(H)+9(H)(HL+B)=13CE(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+9(H)(HL+B)=1494(H)
A register value = HL register value (@WIN_34) AND A register value = 0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=9-1=8
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(Second time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350(H)+8(H)(HL+B)=1358(H)
A register value = 00011010 (B) (@WIN_26 OR @WIN_28 OR @WIN_29)
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+8(H)(HL+B)=13CD(H)
Data indicated by the address of the HL register value=00000111 (B) (@WIN_25 OR @WIN_26 OR @WIN_27)
A register value = data indicated by the address of the HL register value AND A register value =00000010(B)
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+8(H)(HL+B)=1349(H)
Data indicated by HL register value address = 00001000 (B) (@WIN_28)
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=8-1=7
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(3rd time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350 (H)+7 (H) (HL+B)=1357 (H)
A register value =00000011 (B) (@WIN_17 OR @WIN_18)
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+7(H)(HL+B)=13CC(H)
Data indicated by HL register value address = 00010000 (B) (@WIN_21)
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+7(H)(HL+B)=1492(H)
Data indicated by the address of the HL register value = 0
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value = 7-1 = 6
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(4th time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350 (H)+6 (H) (HL+B)=1356 (H)
A register value =00000010 (B) (@WIN_10)
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+6(H)(HL+B)=13CB(H)
Data indicated by the address of the HL register value = 10000000 (B) (@WIN_16)
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+6(H)(HL+B)=1491(H)
Data indicated by HL register value address = 00110000 (B) (@WIN_13 OR @WIN_14)
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=6-1=5
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(5th time)
In step S1182, the HL register value=1350 (H) (the value of the symbol array address buffer 1) is set. In step S1183,
HL register value=1350(H)+5(H)(HL+B)=1355(H)
A register value = 11001011 (B) (@WIN_01_02 OR @WIN_04 OR @WIN_07_08)
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+5(H)(HL+B)=13CA(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+5(H)(HL+B)=1490(H)
Data indicated by the address of the HL register value = 00001101(B) (@WIN_01 OR @WIN_03 OR @WIN_04)
A register value=data indicated by the address of the HL register value AND A register value=0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=5-1=4
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(6th time)
In step S1182, the HL register value=1350 (H) (the value in the symbol array address buffer 1).
In step S1183,
HL register value=1350(H)+4(H)(HL+B)=1354(H)
A register value = 0
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+4(H)(HL+B)=13C9(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+4(H)(HL+B)=1491(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value = 4-1 = 3
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(7th time)
In step S1182, the HL register value=1350 (H) (the value of the symbol array address buffer 1) is set. In step S1183,
HL register value=1350(H)+3(H)(HL+B)=1353(H)
A register value = 01000000 (B) (@REP_06)
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+3(H)(HL+B)=13C8(H)
Data indicated by the address of the HL register value =00000010(B) (@REP_01)
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+3(H)(HL+B)=148E(H)
Data indicated by the address of the HL register value = 10101010 (B) (@REP_01 OR @REP_05 OR @REP_07)
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value = 3-1 = 2
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(8th time)
In step S1182, the HL register value=1350 (H) (the value of the symbol array address buffer 1) is set. In step S1183,
HL register value=1350(H)+2(H)(HL+B)=1352(H)
A register value = 0
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+2(H)(HL+B)=13C7(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+2(H)(HL+B)=148D(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value=2-1=1
Becomes
In step S1196, “No” (B register value≠0) is set, and the process returns to step S1182.

(9th time)
In step S1182, the HL register value=1350 (H) (the value of the symbol array address buffer 1) is set. In step S1183,
HL register value=1350(H)+1(H)(HL+B)=1351(H)
A register value = 0
Becomes

In step S1184,
HL register value = 13C5 (H) (value of symbol array address buffer 2)
Becomes
In step S1185,
HL register value=13C5(H)+1(H)(HL+B)=13C6(H)
Data indicated by the address of the HL register value = 1110000 (B) (@SRB_E_H)
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes

In the next step S1186,
HL register value=148B(H) (value of symbol array address buffer 3)
Becomes
In the next step S1187,
HL register value=148B(H)+1(H)(HL+B)=148C(H)
Data indicated by the address of the HL register value = 0
A register value = data indicated by the address of the HL register value AND A register value = 0
Becomes
Therefore, the zero flag=“1”.
Therefore, since “Yes” is obtained in the step S1188, the process proceeds to a step S1195,
B register value = 1-1 = 0
Becomes
In step S1196, “Yes” (B register value=0) is set, and the process according to this flowchart ends.
As a result, the payout amount data remains "0".

<Twenty-seventh embodiment>
The 27th embodiment relates to a symbol arrangement table.
228 and 229 are diagrams showing the symbol arrangement table in the 27th embodiment. The symbol array table stores the symbol data corresponding to the symbol number at each address. In the 27th embodiment, the specific contents of the symbol data stored at each address are omitted.
The symbol arrangement table in the twenty-fifth embodiment is configured as follows.
(1) First reel symbol array table (TBL_PICARG_1) (Fig. 181)
1203 (H): 2nd design + 3rd design 1204 (H): 4th design + 5th design:
120B (H): 18th symbol + 19th symbol 120C (H): 0th symbol + 1st symbol (2) Second reel symbol arrangement table (TBL_PICARG_2) (Fig. 185)
123A (H): 1st design + 2nd design 123B (H): 3rd design + 4th design:
1242 (H): 17th symbol + 18th symbol 1243 (H): 19th symbol + 0th symbol (3) Third reel symbol arrangement table (TBL_PICARG_3) (Fig. 189)
128F(H): 0 number design + 1 number design 1290 (H): 2 number design + 3 number design:
1297 (H): 16th design + 17th design 1298 (H): 18th design + 19th design

As can be seen from the above, for the first (left) reel 31, the second address (upper 4 bits) is stored at the head address (1203 (H)). Since the reference position of the control symbol number (_BF_PICTURE) is in the lower row, the left reel 31 has an effective line (upper row) when the 0th symbol stops in the lower row, which is the reference position. This is because the second symbol stops.
As for the second (middle) reel 31, the first address (upper 4 bits) is stored at the head address (123A(H)). This is because, in the middle reel 31, when the 0th symbol stops at the lower level which is the reference position, the 1st symbol stops at the effective line (middle stage).
Similarly, for the third (right) reel 31, the 0th symbol (upper 4 bits) is stored at the head address (128F(H)). This is because the reference position on the right reel 31 and the position on the activated line match.

181, FIG. 185, and the example of FIG. 189 in the twenty-fifth embodiment store data of two symbols per address (one symbol data in the upper 4 bits, one symbol data in the lower 4 bits).
On the other hand, when one symbol data is stored at one address, it is configured as shown in FIGS. 228 and 229.
In the symbol arrangement table of the 27th embodiment, for simplification of description, the symbol data of the left reel 31 starts from the address “1000 (H)”, and the symbol data of the middle reel 31 starts at the address “1100 (H)”. , And the symbol data of the right reel 31 starts from the address “1200 (H)”.

FIG. 228 is a diagram showing an example (example 1) when data of one symbol per address is used in the symbol arrangement table of the twenty-fifth embodiment. As shown in FIG. 228, with respect to the symbol data of the left reel 31, the symbol data of the symbol number 2 is stored in order from the head address. Further, the symbol data of the middle reel 31 is stored from the symbol data of the symbol number 1 in order from the leading address. Furthermore, as for the symbol data of the right reel 31, the symbol data of the symbol number 0 is stored in order from the head address.

In this way, in the symbol arrangement table of the left, middle, and right reels 31, by shifting the symbol number of the symbol data of the head address, the symbol number of the symbol stopped at the reference position (position on the reference line) is an offset value. As a result, it is possible to obtain the symbol number of the symbol stopped on the activated line.
For example, when the symbol of the symbol number 0 stops at the reference position (lower stage) when the left reel 31 stops, the symbol number of the symbol stopped on the activated line (upper stage) is "1000 (H) (start address value). It is possible to acquire the symbol data (for symbol number 2) stored at the address “1000(H)” by “+“0 (symbol number)”=“1000(H)”.
Similarly, when the symbol with the symbol number 10 is stopped at the reference position (lower stage) when the left reel 31 is stopped, the symbol number of the symbol stopped on the activated line (upper stage) is “1000 (H)”+“10( D)”=“100A(H)” makes it possible to obtain the symbol data (for symbol number 12) stored at the address “100A(H)”.

Regarding the middle reel 31, for example, when the symbol number 0 is stopped at the reference position (lower stage) when the middle reel 31 is stopped, the symbol number of the symbol stopped on the activated line (middle stage) is "1100 (H) ( It is possible to acquire the symbol data (for symbol number 1) stored at the address "1100(H)" by "start address value)" + "0 (symbol number)" = "1100(H)". ..
Similarly, when the symbol with the symbol number 10 is stopped at the reference position (lower stage) when the middle reel 31 is stopped, "1100 (H)"+"10( as the symbol number of the symbol stopped on the activated line (middle stage) D)”=“110A(H)” makes it possible to obtain the symbol data (for symbol number 11) stored at the address “110A(H)”.

Regarding the right reel 31, when the symbol with the symbol number 0 stops at the reference position (lower stage) of the right reel 31, as the symbol number of the symbol stopped on the activated line (lower stage), "1200 (H) (first) It is possible to obtain the symbol data (for the symbol number 0) stored at the address “1200(H)” by “address value)”+“0 (symbol number)”=“1200(H)”.
Similarly, when the symbol with the symbol number 10 stops at the reference position (lower stage) when the right reel 31 stops, "1200 (H)"+"10( as the symbol number of the symbol stopped on the activated line (lower stage) D)”=“120A(H)” makes it possible to obtain the symbol data (for symbol number 10) stored at the address “120A(H)”.

Since the effective line of this example is "upper left"-"middle middle"-"lower right", the symbol data is shifted as described above, but the effective line is, for example, a V line-shaped "upper left". -"Middle lower tier"-"Upper right tier",
(1) Symbol arrangement table of the left reel 31 1000(H): For symbol number 2 1001(H): For symbol number 3:
(2) Symbol arrangement table of the middle reel 31 1100(H): for symbol number 0 1101(H): for symbol number 1
(3) Symbol arrangement table for the right reel 31 1200 (H): for symbol number 2 1201 (H): for symbol number 3:
And it is sufficient.

FIG. 229 is a diagram showing an example (Example 2) in which the symbol data of the left, middle, and right reels 31 is not shifted in the symbol arrangement table. Further, in this example, the reference line is “upper left stage”-“middle upper stage”-“upper right stage” (the valid line is the same as in FIG. 228).
Then, as shown in FIG. 229, in each of the symbol array tables of the left, middle, and right reels 31, the symbol data is stored in order from the symbol data for the symbol number 0.
On the other hand, in this example, difference data is stored at the final address.
In the case of Example 2, it is possible to add the difference data to the symbol number that stops at the reference position and obtain the symbol number that stops at the activated line.

For example, when the design number 0 is stopped at the reference position of the left reel 31, "1000 (H) (starting address value)" + "0 (design number)" + "0 (difference data)" = "1000 ( H)” makes it possible to obtain the symbol data (for symbol number 0) stored at the address “1000(H)”.
Similarly, when the symbol with the symbol number 10 stops at the reference position of the left reel 31, the address "100A" is given by "1000(H)"+"10(D)"+"0"="100A(H)". It is possible to obtain the data (for symbol number 10) stored in (H)”.

Regarding the middle reel 31, when the symbol with the symbol number 0 stops at the reference position of the medium reel 31, "1100 (H) (start address value)" + "0 (symbol number)" + "1 (difference Data)”=“1101(H)” makes it possible to obtain the data (for symbol number 1) stored at the address “1101(H)”.
Similarly, when the symbol with the symbol number 10 stops at the reference position of the middle reel 31, it is stored in “1100 (H)”+“10(D)”+“1”=“110B(H)”. It is possible to acquire data (for symbol number 11).

Furthermore, regarding the right reel 31, when the symbol with the symbol number 0 stops at the reference position of the right reel 31, "1200 (H) (starting address value)" + "0 (symbol number)" + "2( It is possible to acquire the data (for the symbol number 2) stored at the address “1202(H)” by the difference data)”=“1202(H)”.
Similarly, when the symbol of the symbol number 10 stops at the reference position of the right reel 31, the address "120C(H)" is given by "1200(H)"+"10"+"2"="120C(H)". It is possible to acquire the data (for the symbol number 12) stored in ".
As described above, in order to obtain the symbol number of the symbol stopped on the activated line from the symbol number of the symbol stopped at the reference position, a method of storing the symbol data in the symbol array data in advance, or the symbol is stored. There is a method in which the symbol data in the array data is stored without shifting and the symbol number is obtained using the difference data.

In the 27th embodiment described above, in the example 1 of FIG. 228, the symbol numbers of the symbol data specified by the head address are different. In this way, the symbol data stored in the symbol array table of the first reel 31, the second reel 31, and the third reel 31 is stored with the symbol numbers shifted (stored in consideration of the difference. By setting), there is no need to perform correction (add or subtract difference) for each acquired control symbol number (BF_PICTURE). Therefore, the program processing can be simplified and the capacity of the ROM 54 can be reduced.

On the other hand, as in Example 2 of FIG. 229, in each of the symbol array tables of the left reel 31, the middle reel 31, and the right reel 31, all are stored in order from the symbol data of the symbol number 0, and the symbol data is acquired. In this case, when the difference data of the reel 31 is added to or subtracted from the symbol number of the symbol stopped at the reference position, even if the effective line is changed, the difference data is simply changed. Since it is good, development man-hours can be reduced.

The example of the 27th embodiment (including the 25th embodiment) is an example in which the effective line does not change depending on the specified number. On the other hand, when the effective line changes depending on the specified number, for example, the following is performed.
First, in the case of Example 1 of FIG. 228 (including the twenty-fifth embodiment), it is possible to provide a symbol arrangement table for each specified number.
Further, in the case of Example 2 in FIG. 228, it is possible to provide difference data for each specified number. In particular, in the case of Example 2 in FIG. 228, the symbol arrangement table does not change depending on the prescribed number (the symbol arrangement table is the same even if the prescribed number changes), so it is possible to suppress an increase in the storage area.

Further, in the example of the twenty-seventh embodiment (including the twenty-fifth embodiment), the example in which the number of effective lines is one has been shown, but when the number of effective lines is plural, the following is performed, for example. ..
First, in the case of Example 1 of FIG. 228 (including the twenty-fifth embodiment), a symbol arrangement table is provided for each activated line.
Further, in the case of the example 2 in FIG. 228, difference data may be provided for each valid line. In particular, in the case of Example 2 in FIG. 228, the symbol array table does not change even if the effective line increases (the symbol array table is the same even if the effective line changes), so the increase in the storage area is suppressed. be able to.
Furthermore, in the case where the positions and the number of effective lines change depending on the specified number, in the case of Example 1 of FIG. 228 (including the twenty-fifth embodiment), a symbol arrangement table is provided for every effective line, for example, a predetermined number. In the case of the prescribed number of, it is possible to specify which (one or more) symbol arrangement table is used.
Similarly, in the case of Example 2 in FIG. 228, difference data is provided for every valid line, and for example, in the case of a predetermined prescribed number, which (one or more) difference data is used can be designated. Can be mentioned.

<Twenty-eighth Embodiment>
In the 25th to 27th embodiments described above, the number of effective lines is one.
On the other hand, in the twenty-eighth embodiment, a case where a plurality of effective lines are provided will be described.
FIG. 230 is a diagram showing the display window 18, the effective line and the RWM region in the twenty-eighth embodiment. In the figure, (A) shows the relationship between each symbol in the display window 18 and the RWM area, and (B) shows the relationship between the effective lines L1 to L5 and the RWM area.
In the twenty-eighth embodiment, nine symbols “3×3” are displayed in the display window 18 as in the twenty-third embodiment shown in FIG. 115.

As shown in (A) in the figure, one RWM (storage) area is provided for each stop position (symbol). For example, in the left reel 31, the RWM area of the upper row “1” is defined as “_WK_PIC_LFT1”, the RWM area of the middle row “2” is defined as “_WK_PIC_LFT2”, and the RWM area of the lower row “3” is defined as “_WK_PIC_LFT3”. Therefore, nine RWM areas corresponding to all nine stop positions (designs) are also provided. Each RWM area is composed of 2 bytes.
Further, as shown in (B) in the figure, an RWM region is provided for each effective line. There are five effective lines L1 to L5 in the twenty-eighth embodiment. Then, for example, the RWM region of the effective line L1 that is descending to the right is "_WK_PIC_L1".
Furthermore, the RWM area "_WK_ALL_PIC" for all the valid lines is provided. "_WK_ALL_PIC" is a value obtained by performing an OR (logical sum) operation from "_WK_PIC_L1" to "_WK_PIC_L5".

FIG. 231 is a diagram showing a symbol array in the twenty-eighth embodiment. In the 23rd embodiment shown in FIG. 114, the number of symbols per reel 31 is “20”, but in the 28th embodiment, the number of symbols is “21”.
232 is a diagram showing the first reel symbol array table (TBL_PICARG_1) in the twenty-eighth embodiment and corresponds to FIG. 181 in the twenty-fifth embodiment.
233 is a diagram showing a second reel symbol array table (TBL_PICARG_2) in the twenty-eighth embodiment, and corresponds to FIG. 185 in the twenty-fifth embodiment.
Furthermore, FIG. 234 is a diagram showing a third reel symbol array table (TBL_PICARG_3) in the twenty-eighth embodiment and corresponds to FIG. 189 in the twenty-fifth embodiment.

In FIG. 232, in the first symbol arrangement table (TBL_PICARG_1) of the left reel 31, symbol data of each symbol is provided in order from the start address toward the symbol numbers “0” to “20” of FIG. 231 ( Along with the addresses "1200(H)" to "1228(H)"), the last two data are the symbol data of the symbol numbers "0" and "1". Therefore, the symbol data of the address “122A(H)” is the same as the symbol data of the address “1200(H)”, and the symbol data of the address “122C(H)” is the symbol data of the address “1201(H)”. It is the same.
As for the second symbol arrangement table (TBL_PICARG_2) of the middle reel 31 and the third symbol arrangement table (TBL_PICARG_3) of the right reel 31, as in the first symbol arrangement table (TBL_PICARG_1), the symbol number "0" in order from the top address. , The symbol data of the symbol number “1”,..., The symbol data of the symbol number “20”, the symbol data of the symbol number “0”, and the symbol data of the symbol number “1” are arranged.

Then, for example, when the left reel 31 is stopped, when the "bell" of the symbol number "0" is in the upper stage, the replay of the symbol number "1" is in the middle stage, and the "blank" of the symbol number "2" is stopped in the lower stage,
_WK_PIC_LFT1=00001000(B), 00000001(B) (bell)
_WK_PIC_LFT2=00000011 (B), 00000001 (B) (replay)
_WK_PIC_LFT3=0000000(B), 00000000(B) (blank)
Is memorized.
The same applies when the middle reel 31 and the right reel 31 are stopped.
Further, as a method of storing the symbol data in each storage area when each reel 31 stops, the following method can be mentioned.
(Example 1) Method Using Upper Stage as Reference For example, when the left reel 31 is stopped, the address corresponding to the symbol data of the symbols stopped on the upper stage is specified. Specifically, when the address corresponding to the symbol data of the symbol stopped at the upper stage is "1200(H)", the symbol data stored at the address "1200(H)" is stored in "_WK_PIC_LFT1". To do.
Next, in "_WK_PIC_LFT2", the symbol data stored in the address "1202(H)" obtained by adding "2(H)" to the address "1200(H)" is stored.

Further, the symbol data stored in the address "1204 (H)" obtained by adding "4 (H)" to the above address "1200 (H)" is stored in "_WK_PIC_LFT3".
When the symbol number of the symbol stopped at the upper stage is "0", the symbol data stored in the address "1200(H)" is used instead of the symbol data stored in the address "122A(H)". To do. Similarly, when the symbol number of the symbol stopped at the upper stage is "1", not the symbol data stored in the address "122C(H)", but the symbol data stored in the address "1202(H)" use.

(Example 2) Method Using Lower Stage as Reference For example, when the left reel 31 is stopped, an address corresponding to the symbol data of the symbol stopped in the lower stage is specified. Specifically, when the address corresponding to the symbol data of the symbol stopped at the lower stage is "1204(H)", the symbol data stored at the address "1204(H)" is stored in "_WK_PIC_LFT3". To do.
Next, in "_WK_PIC_LFT2", the symbol data stored in the address "1202(H)" obtained by subtracting "2(H)" from the address "1204(H)" is stored.
Further, the symbol data stored in the address “1200(H)” obtained by subtracting “4(H)” from the address “1204(H)” is stored in “_WK_PIC_LFT1”.

When the symbol number of the symbol stopped at the lower stage is "0", the symbol data stored in the address "122A(H)" is used instead of the symbol data stored in the address "1200(H)". To do. Similarly, when the symbol number of the symbol stopped at the upper stage is "1", not the symbol data stored in the address "1202(H)" but the symbol data stored in the address "122C(H)" use.
In any of the methods of Example 1 and Example 2 described above, the symbol data of one row can be used as a reference for each reel 31 to acquire the symbol data of another row.
Then, as in FIGS. 232 to 234, the symbol combination data is stored in excess of the number of symbol numbers (the symbol combination data of the symbol number 0 is stored again next to the symbol combination data of the symbol number 20, and further Next, by storing the symbol combination data of the symbol number 1 again), for example, even if the symbol of the symbol number 0 is stopped in the lower row, the symbol combination of the symbol number 20 will be stopped in the middle row. It is possible to easily acquire the data and the symbol combination data of the symbol number 19 which will be stopped at the upper stage.

Next, a method of identifying the symbol combination data to be stopped on the activated line will be described.
Note that, for example, the symbol data of the left reel 31 of the symbol combination data “_WK_PIC_L1” of the activated line L1 is “_WK_PIC_L1_L”, the symbol data of the middle reel 31 is “_WK_PIC_L1_C”, and the symbol data of the right reel 31 is “_WK_PIC_L1_R”. The other effective lines L2 to L5 are similarly provided.
First, as a result of the winning lottery, "bell"-"bell"-"bell" is determined as a winning number that can be stopped on the activated line, and when the symbol of symbol number 20 passes through the middle stage of the left reel 31. The left stop switch 42 is operated, then the middle stop switch 42 is operated when the symbol of the symbol number 1 is passing through the middle stage of the middle reel 31, and then the middle stage of the right reel 31 is the symbol of the symbol number 3 When the right stop switch 42 is operated while the
"1" (upper left): Design number "0" (bell)
"2" (left middle row): Design number "1" (replay)
"3" (lower left): Design number "2" (blank)
"4" (middle and upper): Design number "2" (bell)
"5" (middle and middle): Design number "3" (blue cherry)
"6" (lower middle): Designation number "4" (replay)
"7" (upper right): Design number "4" (bell)
"8" (middle right): Design number "5" (replay)
"9" (bottom right): Design number "6" (red cherry)
Suppose that stops.

In this case, the symbol data stored in the storage area corresponding to each stop position is
_WK_PIC_LFT1: 00001000 (B), 00000000 (B)
_WK_PIC_LFT2:00000011 (B), 00000001 (B)
_WK_PIC_LFT3: 00000000(B), 00000000(B)
_WK_PIC_CEN1: 00111000(B), 00000001(B)
_WK_PIC_CEN2: 00110000 (B), 00000000 (B)
_WK_PIC_CEN3: 00110011(B), 00000000(B)
_WK_PIC_RIG1: 00111001 (B), 00000001 (B)
_WK_PIC_RIG2: 00110010 (B), 00000000 (B)
_WK_PIC_RIG3: 00110000 (B), 00000000 (B)
Becomes

For the effective line L1,
_WK_PIC_L1_L=_WK_PIC_LFT1: 00001000(B), 00000000(B)
_WK_PIC_L1_C=_WK_PIC_CEN2: 00110000 (B), 00000000 (B)
_WK_PIC_L1_R=_WK_PIC_RIG3: 00110000 (B), 00000000 (B)
Becomes
The value obtained by performing the AND (logical product) operation of the upper bytes (three) and the AND operation of the lower bytes (three) is defined as “_WK_PIC_L1”.
Specifically, “00001000(B)” AND “00110000(B)” AND “00110000(B)” are set as the upper byte.
In addition, "00000000(B)" AND "00000000(B)" AND "00000000(B)" are set to the lower byte. The calculation result is “_WK_PIC_L1”.
Therefore,
_WK_PIC_L1: 00000000(B), 00000000(B)
Becomes

Further, "_WK_ALL_PIC" is updated by an OR (logical sum) operation of this data and "_WK_ALL_PIC". “_WK_ALL_PIC” is “0” before the first calculation.
In the OR operation, the OR operation of the upper 1-byte data and the OR operation of the lower 1-byte data are performed.
Therefore,
_WK_ALL_PIC = 00000000(B), 00000000(B)
Becomes

Next, regarding the effective line L2,
_WK_PIC_L2_L=_WK_PIC_LFT1: 00001000(B), 00000000(B)
_WK_PIC_L2_C=_WK_PIC_CEN1: 00111000(B), 00000001(B)
_WK_PIC_L2_R=_WK_PIC_RIG1: 00111001 (B), 00000001 (B)
Becomes
Therefore,
_WK_PIC_L2: 00001000 (B), 00000000 (B)
Becomes
In addition, the updated "_WK_ALL_PIC" (which is ORed with "_WK_ALL_PIC" for the valid line L1) is
_WK_ALL_PIC = 00001000(B), 00000000(B)
Becomes

For the effective line L3,
_WK_PIC_L3_L=_WK_PIC_LFT2:00000011 (B), 00000001 (B)
_WK_PIC_L3_C=_WK_PIC_CEN2: 00110000 (B), 00000000 (B)
_WK_PIC_L3_R=_WK_PIC_RIG2: 00110010(B), 00000000(B)
Becomes
Therefore,
_WK_PIC_L3: 00000000(B), 00000000(B)
Becomes
Also, after updating "_WK_ALL_PIC",
_WK_ALL_PIC = 00001000(B), 00000000(B)
Becomes

Regarding the effective line L4,
_WK_PIC_L4_L=_WK_PIC_LFT3: 00000000(B), 00000000(B)
_WK_PIC_L4_C=_WK_PIC_CEN3: 00110011(B), 00000000(B)
_WK_PIC_L4_R=_WK_PIC_RIG3: 00110000 (B), 00000000 (B)
Becomes
Therefore,
_WK_PIC_L4: 00000000(B), 00000000(B)
Becomes
Also, after updating "_WK_ALL_PIC",
_WK_ALL_PIC = 00001000(B), 00000000(B)
Becomes

For the effective line L5,
_WK_PIC_L5_L=_WK_PIC_LFT3: 00000000(B), 00000000(B)
_WK_PIC_L5_C=_WK_PIC_CEN2: 00110000 (B), 00000000 (B)
_WK_PIC_L5_R=_WK_PIC_RIG1: 00111001 (B), 00000001 (B)
Becomes
Therefore,
_WK_PIC_L5: 00000000(B), 00000000(B)
Becomes
Also, after updating "_WK_ALL_PIC",
_WK_ALL_PIC = 00001000(B), 00000000(B)
Becomes
From the above, "_WK_ALL_PIC" is calculated when the symbol combination data of the five effective lines L1 to L5 is calculated (combined), and this symbol combination data becomes the data of the symbol combination stopped on any of the activated lines. ..

FIG. 235 is a diagram showing a winning combination definition in the twenty-eighth embodiment.
An AND (logical product) operation is performed on the high-order byte of "_WK_ALL_PIC" and each small win or replay win definition, and if "0", it is determined that the win has not been won, If not, it is determined that the winning combination has won.
Also, the lower byte of “_WK_ALL_PIC” and the winning combination definition of the winning character are ANDed (logical product) one by one. If not, it is determined that the accessory has won the prize.

Also, the above determination may be executed for all small wins, replays, and bonuses, but if the specifications are such that there are no overlapping winnings, then it is determined that the winning combination is The calculation may be stopped.
In the above example, since the upper byte of "_WK_ALL_PIC" is "00001000(B)", if the AND operation is performed with the winning combination definition of the small winning combination or replay, "00001000(B)" is obtained when the AND operation is performed with the winning combination definition of the small winning combination B. "≠ "0", and it is determined that the small winning combination B has won.
Further, since the lower byte of “_WK_ALL_PIC” is “00000000(B)”, it becomes “0” when ANDed with the role definition of any role.

Further, as a result of the winning combination lottery, in the game in which the winning combination number for which the symbol combination corresponding to the small winning combination C (red cherry) or the small winning combination D (blue cherry) can be stop-displayed is determined, there is no overlap winning. , When the left reel 31 is stopped, no matter whether the "red cherry" or "blue cherry" is stopped at "1" (upper left stage), "2" (left middle stage), or "3" (lower left stage) The number of sheets is uniform (for example, two).
On the other hand, as a result of the winning combination lottery, in the game in which the symbol combination corresponding to the small combination C or the small combination D is determined as the winning number that can be stopped and displayed, if the specification is such that there is a double winning, the left reel 31 is stopped. At this time, if the "red cherry" or the "blue cherry" stops at "2" (middle left), the single win of the activated line L3 is achieved. On the other hand, if the “red cherry” or the “blue cherry” stops at “1” (upper left), the winning lines of the activated lines L1 and L2 will be duplicated. Similarly, if the "red cherry" or the "blue cherry" stops at "3" (lower left), the effective lines L4 and L5 will be doubled.
Then, in the case of a single winning, two coins are paid out, and in the case of overlapping (two overlapping) winnings, four coins are paid out.
As a method for calculating the payout number in such a case, the following method can be given.

(First method)
Small winning part C (red cherry) and small winning part D (blue cherry) do not stand alone (“red cherry” and “blue cherry” do not stop in the middle left column), and only double winning (on left reel 31) When the "red cherry" or the "blue cherry" is stopped, it may be stopped at either the upper left stage or the lower left stage.
In this case, when the number of payouts at the time of winning the small role C or the small role D is set to “2”, the double payout is always made at the time of winning the small role C or the small role D. It is possible to set to "4" sheets.

(Second method)
At the time of winning the small winning combination C or the small winning combination D, the stop position of the symbol of “blue cherry” or “red cherry” on the left reel 31 may be determined.
For example, when the symbol data of “_WK_PIC_LFT1”, “_WK_PIC_LFT2”, and “_WK_PIC_LFT3” is determined, and the symbol data of “_WK_PIC_LFT2” (left middle row) is the symbol data corresponding to the small win C or the small win D, 2 It will be paid out.
On the other hand, when the symbol data of “_WK_PIC_LFT1” or “_WK_PIC_LFT3” (upper left row or lower left row) is the symbol data corresponding to the small winning combination C or the small winning combination D, four payouts can be given.

(Third method)
For example, it is possible to determine the winning combination and the number of payouts for each of the activated lines.
When "(red or blue) cherry" is stopped in the left middle row when the left reel 31 is stopped, only the symbol combination data of "_WK_PIC_L3" becomes data other than "0". As a result, it is determined that the payout is two.
On the other hand, when "(red or blue) cherry" stops on the upper left side when the left reel 31 stops, the symbol combination data of "_WK_PIC_L1" and the symbol combination data of "_WK_PIC_L2" are data other than "0". Become. Thereby, it is determined that the payout is two based on the symbol combination data of “_WK_PIC_L1”, and the payout is two based on the symbol combination data of “_WK_PIC_L2”. Then, both of them are summed to make four payouts.

When set in this way, it can also be used, for example, when the small winning combination C or the small winning combination D (cherry) and the small winning combination A (bell) are set to be double-winned.
For example, when the "Red Cherry" with the symbol number 3 is stopped at the upper stage when the left reel 31 is stopped and "Bell"-"Bell"-"Bell" is stopped on the activated line L3, the number of bells to be paid out Assuming 8 sheets,
Symbol combination data of "_WK_PIC_L1": 2 payouts Symbol combination data of "_WK_PIC_L2": 2 payouts Symbol combination data of "_WK_PIC_L3": 8 payouts, and a total of 12 payouts can be made.

It is also assumed that the upper limit of the number of payouts in one game is set to, for example, 15 and that the number of payouts when the small prize C or the small prize D is independently won is set to 8.
In this case, 8 coins are paid out when the small prize C or the small prize D is independently won.
Also, when the small winning combination C or the small winning combination D is double-winned, the number is “8×2=16”, but the upper limit value of 15 is given priority, and 15 are paid out. Specifically, there is a method of performing a comparison operation between the operation result "16" of "8+8" and the upper limit value "15" and setting the upper limit value when the upper limit value is exceeded.

Furthermore, in the twenty-eighth embodiment, the initialization timing of the storage areas “_WK_PIC_LFT1” to “_WK_PIC_RIG3”, “_WK_PIC_L1” to “_WK_PIC_L3”, and “_WK_ALL_PIC” is, for example, after the payout processing is finished, and next time. Until the reel 31 can be stopped in the game. For example, it may be set to a predetermined timing after the payout processing is completed, a predetermined timing after the start switch 41 is operated, or a predetermined timing after the rotation of the reel 31 is started.

Furthermore, in the twenty-eighth embodiment, nine storage areas “_WK_PIC_LFT1” to “_WK_PIC_RIG3” and “_WK_ALL_PIC” shown in FIG. It is also possible not to provide.
In this case, the following calculation method can be used.
First, for example, the value obtained by performing an AND operation of the upper bytes (three) of "_WK_PIC_LFT1", "_WK_PIC_CEN2", and "_WK_PIC_RIG3" and an AND operation of the lower bytes (three), for example, in the HL register. (For example, the upper byte is stored in the H register and the lower byte is stored in the L register value).
Further, "_WK_ALL_PIC" is updated by an OR (logical sum) operation of this data and "_WK_ALL_PIC". The initial value of "_WK_ALL_PIC" is "0".
In the OR operation, the OR operation of the upper 1-byte data and the OR operation of the lower 1-byte data are performed.
As a result, the symbol combination data on the activated line L1 is reflected in "_WK_ALL_PIC".

Next, the value obtained by performing an AND operation of the upper bytes (three) and the AND operation of the lower bytes (three) of “_WK_PIC_LFT1”, “_WK_PIC_CEN1”, and “_WK_PIC_RIG1” is stored in the HL register. Remember.
Further, "_WK_ALL_PIC" is updated by an OR (logical sum) operation of this data and "_WK_ALL_PIC".
As a result, the symbol combination data on the activated line L2 is reflected in “_WK_ALL_PIC”.
Next, the value obtained by performing the AND operation of the upper bytes (three) of "_WK_PIC_LFT2", "_WK_PIC_CEN2", and "_WK_PIC_RIG2" and the AND operation of the lower bytes (three) is stored in the HL register. Remember.
Further, "_WK_ALL_PIC" is updated by an OR (logical sum) operation of this data and "_WK_ALL_PIC".
As a result, the symbol combination data on the activated line L3 is reflected in "_WK_ALL_PIC".

Next, the value obtained by performing an AND operation of the upper bytes (three) of the "_WK_PIC_LFT3", "_WK_PIC_CEN3", and "_WK_PIC_RIG3" and an AND operation of the lower bytes (three) is stored in the HL register. Remember.
Further, "_WK_ALL_PIC" is updated by an OR (logical sum) operation of this data and "_WK_ALL_PIC".
As a result, the symbol combination data on the activated line L4 is reflected in "_WK_ALL_PIC".
Next, the value obtained by performing the AND operation of the upper bytes (three) and the lower byte (three) of the “_WK_PIC_LFT3”, “_WK_PIC_CEN2”, and “_WK_PIC_RIG1” is stored in the HL register. Remember.
Further, "_WK_ALL_PIC" is updated by an OR (logical sum) operation of this data and "_WK_ALL_PIC".
As a result, the symbol combination data on the activated line L5 is reflected in "_WK_ALL_PIC".
If the calculation is executed as described above, it is not necessary to provide the storage areas “_WK_PIC_L1” to “_WK_PIC_L5”, so that the storage area of the RWM 53 can be reduced.

Although the twenty-fifth to twenty-eighth embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications such as the following are possible.
(1) For example, in the twenty-fifth embodiment, the stop symbol data (_WK_STOP_PIC) is composed of nine (first group to ninth group) based on the number of 1BB, RB, replay, and small winning combination. Various settings can be made according to the type and number of winning combinations.
For example, when the number of winning combinations is 8 or less, the stop symbol data can be composed of 1-byte data.

Further, in the twenty-fifth embodiment, in order to separate the replay and the small winning combination, the D3 to D7 bits of the stop symbol data (fourth group) are not used, and the bits corresponding to the small winning combinations 01 and after are set to the stop symbol data (the first symbol). It was provided after 5 groups). However, without being limited to this, the D3 bit of the stop symbol data (fourth group) is a small winning symbol 01 winning symbol, the D4 bit is a small symbol 02 winning symbol,..., There is no unused bit, and RWM storage of the stop symbol data You may save space.
In this case, when calculating the payout number data, the data of the stop symbol data (fourth group) and “11111000(B)” are AND-operated to mask the data relating to the replay operation symbol. ..

Or, conversely to the above,
Stop symbol data (5th group): Small winning combination 01 winning design to small winning combination 08 winning design (15 payouts)
Stop symbol data (6th group): Small winning 09 winning symbol to small winning 12 winning symbol (15 payouts)
Stop symbol data (7th group): Small winning combination 13 winning symbol to small winning combination 20 winning symbol (3 payouts)
Stop symbol data (8th group): Small prize 21 prize symbol to small prize 24 prize symbol (3 pieces payout)
Stop symbol data (9th group): Small winning 25 winning symbol to small winning 32 winning symbol (1 payout)
Stop symbol data (10th group): Small winning symbol 33 winning symbol to small winning symbol 34 winning symbol (1 payout)
It is also possible to divide one stop symbol data so as not to include data with different payout numbers.
In this case, the addresses of the stop symbol data (fifth group) to the stop symbol data (10th group) are preferably continuous.

(2) In the designated data acquisition (M_SELDAT_SET) shown in FIG. 201, if it is determined that there is designated data in step S1118, the flowchart is ended. However, for example, in the case of a specification having a double winning of a small winning combination, even if it is determined that there is designated data, the flowchart is not ended, and the payout number is determined for all the stop symbol data. On the other hand, in the specification in which there is no overlapping winning of small winning combinations, as shown in FIG. 201, the flow chart can be ended when it is determined that there is designated data.
Further, in the case of a specification having a double winning of a small winning combination, when the maximum payout number in one game is set to 15, the following method may be mentioned.
Firstly, when it is determined that 15 winning combinations such as the small winning combination 01 (the maximum payout number in one game) have been won, the designated data acquisition is finished as in the present embodiment.

Secondly, the number of payouts is determined for all the stop symbol data, and the number of payouts is added and stored every time it is determined that the small winning combination is won (for example, the number of payout data (_NB_PAY_MEDAL) or A It is stored in a general-purpose register such as a register), and finally, when the total value exceeds “15 (D)”, the payout number is corrected to “15 (D)” (set to the upper limit value). To be Alternatively, the payout number is summed up every time it is determined that the small winning combination has been won, and it is determined whether or not the summed value exceeds “15 (D)”, and the summed value exceeds “15 (D)”. In this case, the payout number is corrected to "15(D)" and the specified data acquisition is ended. When the total value does not exceed "15(D)", the specified data acquisition is continued.

(3) In the twenty-seventh embodiment, as shown in FIGS. 232 to 234, the address of each symbol combination data in the reel symbol array table is composed of 2 bytes. However, the number of symbol combinations is not limited to this, and when the number of symbol combinations is eight or less, it can be configured from 1 byte.

(4) In the twenty-fifth embodiment, after the stop symbol set (FIG. 195) is executed and before shifting to the one-line display determination (FIG. 200), for example, the following processing is executed.
In the example shown in FIG. 173, the operation state flag is not provided with replay, but as shown in FIG. 35 (the eleventh embodiment), for example, the D0 bit of the operation state flag is provided with a flag relating to replay.
Then, after all reels 31 have stopped, the operating state flags are checked, and when the operating state flags relating to replay, 1BB, and RB are ON, the one-line display determination (FIG. 200) is not proceeded. As a result, it is possible to proceed to the one-line display determination only when the small winning combination is won or the winning combination is not winning.

(5) In FIG. 229, a storage area for differential data is provided at the final address of the symbol arrangement table. However, not limited to this, it is a matter of course that the difference data may be stored outside the symbol arrangement table.

(6) In FIG. 173, when it is determined that the operating state flag (_FL_ACTION) of the address “F00C(H)” has a small winning combination (winning combination), it becomes “1”, and there is no winning. If it is determined, a bit area that becomes “0” may be provided. In that case, in the game during the RB operation, it is determined whether or not the data of the bit area is "1", and when it is "1", the number of winnings during the RB operation of the address "F010(H)" Can be configured to be updated (for example, “1” can be subtracted or “1” can be added), and when “0”, the winning count during RB operation can be configured not to be updated.

(7) As shown in step S1017 of FIG. 194, the stop position is determined based on the rising data of the stop switch 42. Here, it is possible to adopt level data instead of rising data.
However, when the level data is used instead of the rising data, for example, the stop switch 42 is continuously operated before the reel 31 reaches the constant speed, and then the reel 31 reaches the constant speed, and the reel 31 is stopped. The reel 31 corresponding to the continuously operated stop switch 42 is stopped and controlled at the timing when the reel 31 can be accepted. For this reason, the reel 31 will stop regardless of the skill of the player. In this case, by adjusting the timing at which the stop operation of the reel 31 can be accepted, it is possible to stop the symbol combination (for example, the symbol combination of 1BB) that needs to be pushed regardless of the skill of the player. In some cases. On the other hand, if the stop position is determined based on the rising data, the above problem does not occur. Therefore, from such a viewpoint, it can be said that it is preferable to determine the stop position based on the rising data.

(8) In the example of FIG. 194, the stop position is determined and stopped after it is determined that the stop position is determined based on the rising data of the stop switch 42 (when “Yes” in step S1017). Until the process including the update of the symbol data (step S1035 of FIG. 195) (stop symbol set of step S1024 of FIG. 194) is completed, the interrupt waiting process is executed so that the interrupt process does not enter (step S1011). However, the present invention is not limited to this, and instead of interrupt waiting processing, interrupt processing may be prohibited during that period so that interrupt processing is not executed.

(9) In the twenty-fifth embodiment, the stop symbol data is updated from the ninth group. However, the present invention is not limited to this, and may be executed from the first group.
Specifically, in FIG. 195, the B register is set to "9" in step S1032 and the B register value is subtracted from "1" in step S1036. Instead, however, the B register is set to "1" in step S1032. Is set, and a process of adding “1” to the B register value may be executed in step S1036. In this case, in step S1036, when the B register value after adding "1" becomes "10(D)", the process may be terminated.
The above also applies to the display determination processing (FIG. 227) in the twenty-sixth embodiment. Specifically, in FIG. 227, the B register is set to “9” in step S1181, the B register value is subtracted by “1” in step S1195, and it is determined in step S1196 whether the B register value is “0”. Judged. Instead, the register B is set to "1" in step S1181, the register B value is incremented by "1" in step S1195, and it is determined in step S1196 whether the register B value is "10(D)". If it is determined that the B register value is "10(D)", the process may be terminated.

(10) In the above-described embodiment, the slot machine 10 is taken as an example of one of the gaming machines, but the slot machine 10 is a “revolving-type gaming machine” installed in the fourth branch office to which the wind management law is applied. The present invention is not limited to (a so-called "pachislot gaming machine"), and can be applied to, for example, a casino machine. Further, the present invention can be applied to a management gaming machine in which the gaming machine does not use medals, regardless of whether the gaming machine is a rotating type gaming machine.
(11) All of the embodiments and various modifications described in the present specification including the twenty-fifth to twenty-eighth embodiments are not limited to be implemented alone, but may be implemented in an appropriate combination.

<Twenty-ninth Embodiment>
In the following description of the twenty-ninth to thirty-sixth embodiments, the left reel 31 may be referred to as the first reel 31, the middle reel 31 may be referred to as the second reel 31, and the right reel 31 may be referred to as the third reel 31.
In the description of the 29th to 36th embodiments, the left stop switch 42 is referred to as a first stop switch 42, the middle stop switch 42 is referred to as a second stop switch 42, and the right stop switch 42 is referred to as a third stop switch 42. There is a case to call.

Furthermore, in the description of the twenty-ninth to thirty-sixth embodiments, “#” refers to all of “1” to “3” and any one of “1” to “3”. Have.
Further, in FIGS. 237, 243, 249, 253, and 254 described later, the numerical value in parentheses in the “address” column indicates the number of bytes in the storage area.
In addition, in FIG. 237, FIG. 243, FIG. 249, FIG. 253, and FIG. 254 described later, “D0” to “D7” indicate the D0 bit to the D7 bit of 8-bit data, respectively.

In the twenty-ninth embodiment, the medal payout process (M_WIN_PAY) at the time of winning is not executed before the predetermined period of performing the four-phase excitation output for stopping the reel 31 has elapsed, and at the time of winning after the predetermined period has elapsed. The medal payout process (M_WIN_PAY) is executed.
Here, the “four-phase excitation output” has the same meaning as the “four-phase excitation state” in the fourth embodiment and FIG. 13.
The "predetermined period for performing the 4-phase excitation output" has the same meaning as the "time from the start of the 4-phase excitation state to the end of the 4-phase excitation state" in the fourth embodiment and FIG.

Also in this embodiment, as in the other embodiments, the slot machine 10 includes three reels 31 (left reel 31, middle reel 31, right reel 31), and 3 reels corresponding to each reel 31. The individual stop switches 42 (left stop switch 42, middle stop switch 42, right stop switch 42) are provided.
Further, the symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
Furthermore, also in the present embodiment, the motor 32 for rotating the reel 31 is a four-phase stepping motor as in the fourth and twenty-third embodiments, and while the reel 31 and the motor 32 are rotating, When 1-phase excitation and 2-phase excitation are alternately performed, 1-2-phase excitation output is performed, and when the reel 31 and the motor 32 are stopped, 4-phase excitation output for simultaneously exciting 4 phases is performed.

Further, also in the present embodiment, similarly to the twenty-fifth embodiment, in step S1013 of the reel stop acceptance check (M_STOP_CHK) (FIG. 194) during the main process (M_MAIN), the all-motor-index passage check is performed.
Here, for all reels 31, after the # reel motor index has changed, the first reel symbol number (for passing position) (_NB_RL1_PASPIC) (FIG. 135), the second reel symbol number (for passing position) The values of (_NB_RL2_PASPIC) (FIG. 136) and the third reel symbol number (for passing position) (_NB_RL3_PASPIC) (FIG. 137) are all values other than “FF(H) (11111111(B))”. Therefore, when "1" is added to the operation result obtained by sequentially performing an OR operation of these values, the value becomes a value other than "0".

Further, in step S1014 of FIG. 194, it is determined whether the operation of the stop switch 42 can be accepted (stop acceptance). If the calculation result of step S1013 is a value other than "0", the result of step S1014 is "Yes". After that, when the stop switch 42 is operated, the result of step S1017 in FIG. 194 is "Yes", the flow proceeds to step S1022, and the operation of the stop switch 42 is accepted.

Also in the present embodiment, as described in the fourth embodiment and the twenty-third embodiment, when the stop switch 42 is operated (the stop button 42a of the stop switch 42 is pressed), the detection sensor 42e changes from off to on. Then, the signal of the stop switch 42 is changed from OFF to ON, and “1” is stored in the input port level data A (_PT_IN_A_LV) (FIG. 133) of the address “F012(H)”.
For example, when the left stop switch 42 is operated, the signal of the left stop switch 42 changes from off to on, and "1" is stored in the D0 bit of the input port level data A (_PT_IN_A_LV ). At this time, if the middle stop switch 42, the right stop switch 42, and the start switch 41 are not operated, the input port level data A (_PT_IN_A_LV) becomes “00000001(B)”.

When the middle stop switch 42 is operated, the signal of the middle stop switch 42 is changed from OFF to ON, and "1" is stored in the D1 bit of the input port level data A (_PT_IN_A_LV ). At this time, if the left stop switch 42, the right stop switch 42, and the start switch 41 are not operated, the input port level data A (_PT_IN_A_LV) becomes “00000010 (B)”.

Furthermore, when two of the left stop switch 42 and the middle stop switch 42 are operated, the signals of both the left stop switch 42 and the middle stop switch 42 are changed from OFF to ON, and the input port level data A (_PT_IN_A_LV) "1" is stored in each of the D0 bit and the D1 bit of the. At this time, if the right stop switch 42 and the start switch 41 are not operated, the input port level data A (_PT_IN_A_LV) becomes “00000011 (B)”.

Then, when the input port level data A (_PT_IN_A_LV) changes from "0" to "1" and "1" is stored in the input port rising data A (_PT_IN_A_UP) of the address "F017(H)", the stop switch 42 It is determined that the operation of has been accepted.
For example, when the D0 bit of the input port level data A (_PT_IN_A_LV) at the time of the previous interrupt processing is “0” and the D0 bit of the input port level data A (_PT_IN_A_LV) at the time of the current interrupt processing is “1”. "1" is stored in the D0 bit of the input port rising data A (_PT_IN_A_UP). As a result, it is determined that the operation of the left stop switch 42 has been accepted.

Further, when the D1 bit of the input port level data A (_PT_IN_A_LV) at the time of the previous interrupt processing is “0” and the D1 bit of the input port level data A (_PT_IN_A_LV) at the time of the current interrupt processing is “1”. "1" is stored in the D1 bit of the input port rising data A (_PT_IN_A_UP). As a result, it is determined that the operation of the middle stop switch 42 has been accepted.

Furthermore, both the D0 bit and D1 bit of the input port level data A (_PT_IN_A_LV) at the time of the previous interrupt processing are “0”, and the D0 bit of the input port level data A (_PT_IN_A_LV) at the time of the current interrupt processing and When both D1 bits are "1", "1" is stored in both the D0 bit and D1 bit of the input port rising data A (_PT_IN_A_UP). Thereby, it is determined that the two operations of the left stop switch 42 and the middle stop switch 42 are simultaneously accepted.

Note that, also in the present embodiment, the cycle of interrupt processing is set to "1.117 ms" as in the twenty-third embodiment. Then, when the signals of both the left stop switch 42 and the middle stop switch 42 are turned on during this "1.117 ms", both the D0 bit and the D1 bit of the input port rising data A (_PT_IN_A_UP) are set to " 1” is stored, and it is determined that two operations of the left stop switch 42 and the middle stop switch 42 are simultaneously accepted.

Further, when the stop switch 42 is operated, the signal of the stop switch 42 changes from off to on, but it may be changed from on to off. That is, the signal of the stop switch 42 is not limited to active high, but may be active low. Then, when the signal of the stop switch 42 changes from on to off, it may be determined that the operation of the stop switch 42 has been accepted.
That is, "the operation of the stop switch 42 is accepted" means that the signal of the stop switch 42 changes from OFF to ON when the signal is active high, and the signal of the stop switch 42 when the signal is active low. Means from on to off. The same applies to other switches as well as the stop switch 42.

When the operation of the stop switch 42 is accepted (“1” is stored in the input port rising data A(_PT_IN_A_UP)) in step S1022 of FIG. 194, the process proceeds to step S1023.
In step S1023, "4(D)" indicating "deceleration start" is stored in the # reel drive state (_WK_RL#_STS) (FIGS. 135 to 137).

Further, in step S1023, the stop position of the reel 31 is determined based on the result of the current game lottery and the position of the reel 31 at the moment when the operation of the stop switch 42 is accepted, and according to the determined stop position. The symbol number is stored in the # reel symbol number (for stop position) (_NB_RL#_STPPIC) (FIGS. 135 to 137).

For example, when the winning number “10” is won by the winning combination lottery means 61, the small winning combination A1 condition device (FIG. 124) is activated, and a small winning combination 01 of 15 payouts or a small winning combination of 3 payouts 13 is performed. Any one of to 17 can win the prize.
Here, when the small win A1 condition device is activated during the general game of the 1BB game (when 1BB is activated) and the stop switch 42 is operated in the correct answer pushing order (left middle right), the small win 01 (15 pieces). When the stop switch 42 is operated in an incorrect pressing order (a pressing order other than the correct pressing order), one of the small winning combinations 13 to 17 (three winning combinations) wins.
On the other hand, when the accessory is not in operation, there is no correct answer pressing order when the small win A1 condition device is operating. Even if all are in the pressing order, one of the small wins 13 to 17 (three wins) Win a prize.
Then, at the moment when the operation of the stop switch 42 is accepted during the operation of the small role A1 condition device when the accessory is not operated, within the range of the maximum number of moving frames from the effective line, for example, the pattern forming the small role 13. When is located, the symbol number of the symbol is stored in the # reel symbol number (for stop position) (_NB_RL#_STPPIC).

Further, in step S909 of the reel drive control (I_REEL_CTL) (FIG. 154) during the interrupt process (I_INTR) executed after the process of step S1023, the # reel symbol number (for passing position) (_NB_RL#_PASPIC), When it is determined that the # reel symbol number (for stop position) (_NB_RL#_STPPIC) has become the same value, the # reel motor signal data (_PT_MOTOR#) (FIG. 134) is pulse data during deceleration. "00001111 (B)" (4 phase ON) is stored, and "1 (D)" indicating "deceleration" is stored in the # reel drive state (_WK_RL#_STS) (FIGS. 135 to 137). ..
Then, in the port output process of step S462 during the interrupt process (I_INTR) executed thereafter, φ1 of the motor 32 is determined based on “000011111(B)” stored in the # reel motor signal data (_PT_MOTOR#). A 4-phase excitation output for simultaneously exciting four phases of φ4 is performed. As a result, the motor 32 is braked to stop the rotation of the reel 31 and the motor 32.

In this way, when the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stop position) (_NB_RL#_STPPIC) become the same value, the # reel motor signal data (_PT_MOTOR) The deceleration pulse data “00001111(B)” is stored in #), and the 4-phase excitation output is performed.
Therefore, even if the operation of the stop switch 42 is accepted, the four-phase excitation output is not immediately performed.

In addition, not only when the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stop position) (_NB_RL#_STPPIC) become the same value, for example, # reel Symbol number (for passing position) (_NB_RL#_PASPIC) and # reel symbol number (for stop position) (_NB_RL#_STPPIC) are the same value, and step number of 1 symbol on # reel 13 (_NB_RL#_STEP ) Has become a predetermined value (for example, “3”), the deceleration pulse data “00001111(B)” is stored in the # reel motor signal data (_PT_MOTOR#), and the four-phase excitation output is output. It may be performed.

Further, in the present embodiment, the four-phase excitation output is performed for each interrupt processing of "1.117 ms" while "000011111(B)" is stored in the # reel motor signal data (_PT_MOTOR#).
Furthermore, at the start of deceleration, the # reel drive pulse output counter (_CT_RL#_PLSOUT) (FIGS. 135 to 137) shows “90 (D)” (pulse output counter during deceleration) corresponding to the address “1050 (H)”. ) (FIG. 156) is stored, and thereafter, the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) is decremented by “1” every two interrupts.

When the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) becomes “0”, “00000000(B)”, which is the pulse data at the time of stop, is stored in the # reel motor signal data (_PT_MOTOR#). At the same time, "0 (D)" indicating "stop" is stored in the # reel drive state (_WK_RL#_STS). As a result, the 4-phase excitation output ends.

As described above, while the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) is “1” or more and “00001111(B)” is stored in the #reel motor signal data (_PT_MOTOR#), The 4-phase excitation output continues, the value of the # reel drive pulse output counter (_CT_RL#_PLSOUT) becomes “0”, and “00000000(B)” is stored in the # reel motor signal data (_PT_MOTOR#). Then, the four-phase excitation output is stopped.
Further, the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) becomes “0”, the stop pulse data “00000000(B)” is stored in the #th reel motor signal data (_PT_MOTOR#), and "0(D)" indicating "stop" is stored in the reel drive state (_WK_RL#_STS), and the state in which the four-phase excitation output is completed is the state in which the reel 31 is stopped.

Further, in the present embodiment, the interrupt processing cycle is set to "1.117 ms", and the value of the # reel drive pulse output counter (_CT_RL#_PLSOUT) is decremented by "1" for every two interrupts. ..
Therefore, by the time the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) changes from “90 (D)” to “0 (D)”, “1.117×2×90=201.06 ms” Therefore, the four-phase excitation output continues for "201.06 ms", and the four-phase excitation output ends when "201.06 ms" elapses.
That is, in the present embodiment, the “predetermined period” in which the four-phase excitation output for stopping the reel 31 is performed corresponds to “201.06 ms”.

The interrupt processing cycle is not limited to "1.117 ms", and the subtraction of the value of the # reel drive pulse output counter (_CT_RL#_PLSOUT) is not limited to every 2 interrupts.
For example, the interrupt processing cycle may be set to "2.235 ms" and the value of the # reel drive pulse output counter (_CT_RL#_PLSOUT) may be subtracted by "1" for each interrupt.

Further, when the stop switch 42 is released (the player's hand is released from the stop button 42a of the stop switch 42 that has been pushed in, and the stop button 42a returns to the original position (the position of FIG. 12A)). , The detection sensor 42e is switched from ON to OFF, the signal of the stop switch 42 is switched from ON to OFF, and “0” is stored in the input port level data A (_PT_IN_A_LV) (FIG. 133) of the address “F012(H)”. To be done.
That is, "stop switch 42 is released" means that the signal of stop switch 42 changes from on to off in the case of active high, and the signal of stop switch 42 turns off in the case of active low. Means to turn on. The same applies to other switches as well as the stop switch 42.

Then, in the present embodiment, after the operation of the stop switch 42 corresponding to the reel 31 that stops last is accepted, before the predetermined period of performing the four-phase excitation output for stopping the reel 31 that stops last passes. (For example, the timing when the four-phase excitation output for stopping the third reel 31 and the timing before the four-phase excitation output for stopping the third reel 31 are performed) Even if the stop switch 42 corresponding to the reel 31 to be stopped is released, the medal payout process (M_WIN_PAY) at the time of winning is not executed, and after the predetermined period has elapsed (after the end of the four-phase excitation output), The medal payout process (M_WIN_PAY) is executed.
For this reason, the stop switch 42 corresponding to the reel 31 stopped last is released within a predetermined period (during the 4-phase excitation output) during which the 4-phase excitation output for stopping the reel 31 stopped last is performed. Also, the medal payout process (M_WIN_PAY) at the time of winning is not executed, but the medal payout process (M_WIN_PAY) at the time of winning is executed after the predetermined period has elapsed (after the completion of the 4-phase excitation output).

Further, in the present embodiment, if any operation of the start switch 41 and the three (left, middle, right) stop switches 42 is accepted, “No” is obtained in step S1307 of FIG. Since the process does not proceed to S291 and thereafter, the medal payout process (M_WIN_PAY) at the time of winning is not executed regardless of whether or not a predetermined period for performing the four-phase excitation output for stopping the reel 31 that is stopped last has passed. ..
Then, when a predetermined period of time for performing a four-phase excitation output for stopping the reel 31 that stops lastly elapses and the start switch 41 and the three (left, middle, right) stop switches 42 are released, FIG. The result of step S1307 is "Yes", and the process proceeds to step S291 and subsequent steps, so that the display determination process and the medal payout process (M_WIN_PAY) at the time of winning can be executed.

FIG. 236 is a flowchart showing the main processing (M_MAIN) in the twenty-ninth embodiment, which corresponds to FIG. 139 of the twenty-third embodiment.
In the flowchart of the twenty-ninth embodiment shown in FIG. 236, steps different from FIG. 139 are underlined in step numbers, and steps identical to FIG. 139 are given identical step numbers.

Also, in the main process (M_MAIN) of the twenty-ninth embodiment, the process of steps S295 to S300 of FIG. 139 is executed, but the process of steps S295 to S300 is omitted in FIG. 236.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 236, in the twenty-ninth embodiment, when the reel stop acceptance check (M_STOP_CHK) of step S752 is executed, the process proceeds to step S1301, and the main control board 50 sets the address “F012(H)” of the RWM 53 The data stored in the input port level data A (_PT_IN_A_LV) (FIG. 133) is stored in the A register. Then, the process proceeds to the next step S1302.

In step S1302, the main control board 50 performs a logical product (AND) operation of the A register value and the mask data “01000111(B)”, and stores the result in the A register. Then, the process proceeds to the next step S1303.
Here, the mask data “01000111(B)” used in step S1302 is data for masking (setting “0”) bit data other than D0 bit, D1 bit, D2 bit, and D6 bit. That is, by performing a logical product (AND) operation of the input port level data A (_PT_IN_A_LV) and "01000111(B)", the D0 bit (left stop switch signal), the D1 bit (middle stop switch signal), Bit data other than the D2 bit (right stop switch signal) and the D6 bit (start switch signal) can be masked (set to "0").

In step S1303, the main control board 50 logically sums (ORs) the A register value and the data stored in the first reel drive state (_WK_RL1_STS) (FIG. 135) of the address “F04D(H)” of the RWM 53. The calculation is performed and the result is stored in the A register. Then, the process proceeds to the next Step S1304.
In step S1304, the main control board 50 logically ORs the A register value with the data stored in the second reel drive state (_WK_RL2_STS) (FIG. 136) of the address “F058(H)” of the RWM 53. The calculation is performed and the result is stored in the A register. Then, the process proceeds to the next step S1305.

In step S1305, the main control board 50 performs the logical OR (OR) of the A register value and the data stored in the third reel drive state (_WK_RL3_STS) (FIG. 137) of the address “F063(H)” of the RWM 53. The calculation is performed and the result is stored in the A register. Then, the process proceeds to the next Step S1306.

In step S1306, the main control board 50 performs a logical product (AND) operation of the A register value and the mask data “01111111(B)”. Then, the process proceeds to the next step S1307.
Here, the mask data “01111111(B)” used in step S1306 is data for masking (setting “0”) the D7-bit bit data. That is, by performing a logical product (AND) operation of the data of the # reel drive state (_WK_RL#_STS) and “01111111(B)”, the D7 bit (data indicating whether or not it is the excitation update timing) is obtained. It can be masked (set to "0").

In step S1307, it is determined whether the zero flag is "1". That is, it is determined whether or not the result of the logical product (AND) operation in step S1306 is "0".
Then, when the zero flag is "1" (the result of the AND operation in step S1306 is "0"), it is determined that all reels 31 have stopped, the result is "Yes" in step S1307, and the display determination in step S291 is made. Proceed to. As a result, the subsequent medal payout process (M_WIN_PAY) at the time of winning in step S294 can be executed.

That is, when the data of the first reel drive state (_WK_RL1_STS), the data of the second reel drive state (_WK_RL2_STS), and the data of the third reel drive state (_WK_RL3_STS) are all data indicating stop, all It is determined that the reel 31 has stopped, and the display determination and the medal payout process at the time of winning can be executed.

On the other hand, when the zero flag is not "1", it is determined that one of the reels 31 is not stopped, the determination is "No" in step S1307, and the process returns to the reel stop acceptance check (M_STOP_CHK) in step S752. In this case, the processing after step S752 will be repeated. As a result, the display determination in step S291 does not proceed, so the medal payout process (M_WIN_PAY) at the time of winning in step S294 is not executed.

That is, if any of the data of the first reel drive state (_WK_RL1_STS), the data of the second reel drive state (_WK_RL2_STS), and the data of the third reel drive state (_WK_RL3_STS) is not data indicating stop , The medal payout process at the time of winning is not executed.
For example, the left reel 31 and the middle reel 31 are stopped, and the right reel 31 receives the operation of the right stop switch 42, but is still in the deceleration start state or during deceleration (during four-phase excitation output). In some cases, the medal payout process at the time of winning is not executed.

Here, when the D0 bit, the D1 bit, the D2 bit, and the D6 bit of the input port level data A (_PT_IN_A_LV) (FIG. 133) are all “0”, that is, the left stop switch signal, the middle stop switch signal, When both the right stop switch signal and the start switch signal are off, the result of the logical product (AND) operation in step S1302 is “00000000(B)”.

When the first reel driving state (_WK_RL1_STS), the second reel driving state (_WK_RL2_STS), and the third reel driving state (_WK_RL3_STS) are all "00000000 (B)" or "10000000 (B)", that is, , When all reels 31 are stopped, the first reel drive state (_WK_RL1_STS), the second reel drive state (_WK_RL2_STS), and the third reel drive state (_WK_RL3_STS) are sequentially ORed (OR), and the result is obtained. And the mask data “01111111(B)” are ANDed (AND) to obtain “00000000(B)”.

Therefore, the result of the logical product (AND) operation in step S1306 becomes "00000000(B)" because the left stop switch signal, the middle stop switch signal, the right stop switch signal, and the start switch signal are all off. , And only when all reels 31 are stopped. Only at this time, "Yes" in step S1307, and the display determination in step S291 and the medal payout process (M_WIN_PAY) at the time of winning in step S294 can be executed.

Further, when at least one of the left stop switch signal, the middle stop switch signal, the right stop switch signal, and the start switch signal is on, that is, the left stop switch 42, the middle stop switch 42, and the right stop switch 42. , And the operation of one or more of the start switches 41 is accepted, even if all reels 31 are stopped, the result of the logical product (AND) operation in step S1306 is “00000000(B)”. "do not become.

Specifically, for example, even if the four-phase excitation output of all the motors 32 of the reels 31 including the motor 32 of the reel 31 to be stopped finally is finished, the operation of the stop switch 42 corresponding to the reel 31 to be stopped finally is operated. If it has been accepted, the result of the logical product (AND) operation in step S1306 does not become “00000000(B)”.
In this case, since "No" in step S1307, neither the display determination in step S291 nor the medal payout process (M_WIN_PAY) at the time of winning in step S294 is executed.

Further, for example, even if the four-phase excitation output of the motors 32 of all reels 31 including the motor 32 of the reel 31 that stops last (for example, the right reel 31) ends, the reel 31 that stops last (for example, the right reel 31). In a situation where the operation of the stop switch 42 corresponding to No. 1 is accepted, the stop switch 42 corresponding to the reel 31 stopped first (for example, the left reel 31) is operated, and then the stop switch corresponding to the reel 31 stopped first is operated. Even if the stop switch 42 corresponding to the reel 31 stopped last is released while operating 42, since the stop switch corresponding to the reel 31 stopped first is operated, the logical product (AND) operation of step S1306 is performed. Result does not become "00000000(B)".

In this case as well, since "No" in step S1307, neither the display determination in step S291 nor the medal payout process (M_WIN_PAY) at the time of winning in step S294 is executed.
In this way, under the situation where any of the stop switches 42 is operated, by preventing the medal payout process (M_WIN_PAY) at the time of winning in step S294 from being executed, the number of credits is set at the player's desired timing. Can be added or medals can be paid out from the hopper 35.

Further, even if the left stop switch signal, the middle stop switch signal, the right stop switch signal, and the start switch signal are all off, that is, the left stop switch 42, the middle stop switch 42, the right stop switch 42, and the start switch. Even if all 41 are separated, if there is at least one reel 31 that is not stopped, the result of the logical product (AND) operation in step S1306 does not become "00000000 (B)".

Specifically, for example, even if all the stop switches 42 including the stop switch 42 corresponding to the reel 31 that stops last and the start switch 41 are released, four-phase excitation of the motor 32 of the reel 31 that stops last is performed. If the output is not completed, the result of the logical product (AND) operation in step S1306 does not become "00000000(B)".
In this case, since "No" in step S1307, neither the display determination in step S291 nor the medal payout process (M_WIN_PAY) at the time of winning in step S294 is executed.

Here, for example, the winning number “10” is won by the winning combination lottery means 61, the small winning combination A1 condition device (FIG. 124) is activated, and a small winning combination of 15 payouts, or three winnings is paid out. It is assumed that any of the small wins 13 to 17 is ready to win.
Further, the two reels 31 are stopped (the excitation output for stopping the reels 31 is finished), the operation of the stop switch 42 corresponding to the third reel 31 is accepted, and the three reels are paid out. It is assumed that the symbol combination (FIG. 119) corresponding to the small winning combination 13 can be stopped and displayed.

Under such a circumstance, after the operation of the stop switch 42 corresponding to the third reel 31 is accepted and before the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses. (For example, the timing when the four-phase excitation output for stopping the third reel 31 and the timing before the four-phase excitation output for stopping the third reel 31 are performed) Even if the stop switch 42 corresponding to the eye reel 31 is released, the medal payout process (M_WIN_PAY) at the time of winning is not executed.
Therefore, even if the stop switch 42 corresponding to the third reel 31 is released within the predetermined period of performing the four-phase excitation output for stopping the third reel 31, the payout of the medal at the time of winning the prize is performed. Do not execute the process (M_WIN_PAY ).
Then, after a lapse of a predetermined period for performing the four-phase excitation output for stopping the third reel 31, it is possible to execute the medal payout process (M_WIN_PAY) at the time of winning the prize.

Further, as shown in FIG. 49, in the medal payout process (M_WIN_PAY) at the time of winning, the credit amount data is acquired in step S393, and in the next step S394, the acquired credit amount data is "50(D)". Determine if there is. That is, it is determined whether or not the number of credits has reached the upper limit value “50”.
Then, when the number of credits has reached the upper limit value “50”, “Yes” is determined in the step S394, and the process proceeds to the one medal payout process of the step S398. In this case, the process of adding the credit amount in step S397 does not proceed.

On the other hand, when the number of credits does not reach the upper limit “50”, “No” is obtained in step S394. In this case, the process proceeds to the process of adding the number of credits in step S397, and does not proceed to the process of paying out one medal in step S398.
Further, when proceeding to the one-medal payout process of step S398, as described in the first embodiment (C), the process of outputting the drive signal of the hopper motor 36 is executed, and the hopper motor 36 is actually driven. Pay out the medal from the hopper 35. Further, by detecting ON/OFF of the payout sensors 37a and 37b, it is determined that one medal has been paid out from the hopper 35.

As described above, in the medal payout process (M_WIN_PAY) at the time of winning, the process of adding the credit number is executed until the credit number reaches the upper limit value “50”, and when the credit number reaches the upper limit value “50”. , A process of outputting a drive signal of the hopper motor 36 is executed, the hopper motor 36 is driven, and an actual medal is paid out from the hopper 35.
Further, common processing is executed halfway between when the hopper motor 36 is driven to pay out medals from the hopper 35 and when the number of credits is added. As a result, the processing can be simplified and the amount of ROM used by the program can be reduced.

That is, when the number of credits is the upper limit value "50", the winning lottery means 61 wins the winning number "10", the small win A1 condition device is activated, and the two reels 31 are stopped. In the game in which the operation of the stop switch 42 corresponding to the third reel 31 is accepted and the symbol combination corresponding to the small winning combination 13 in which three medals are awarded is stopped and displayed, After the operation of the stop switch 42 corresponding to the reel 31 is accepted, the third reel 31 is moved to the third reel 31 at a predetermined timing before a predetermined period of performing an excitation output for stopping the third reel 31 has elapsed. Even if the corresponding stop switch 42 is released, the drive signal output process of outputting the drive signal of the hopper 35 is executed after the elapse of a predetermined period of performing the excitation output for stopping the third reel 31. To do.

As a result, the hopper motor 36 is not driven while the motor 32 (stepping motor) is being four-phase excited, and the hopper motor 36 can be driven after the four-phase excitation of the motor 32 is completed. It is possible to secure the current required to drive the motor 36.

On the other hand, when the number of credits is “0”, the winning lottery means 61 wins the winning number “10”, the small win A1 condition device is activated, and the two reels 31 are stopped. In the game in which the operation of the stop switch 42 corresponding to the third reel 31 is accepted and the symbol combination corresponding to the small winning combination 13 in which three medals are awarded is stopped and displayed, After the operation of the stop switch 42 corresponding to the reel 31 is accepted, the third reel 31 is moved to the third reel 31 at a predetermined timing before a predetermined period of performing an excitation output for stopping the third reel 31 has elapsed. Even when the corresponding stop switch 42 is released, the addition process of adding the credit number is executed after the lapse of a predetermined period of performing the excitation output for stopping the third reel 31.

In this case, the drive signal output process of the hopper 35 is not executed, but the number of credits is the same under the same conditions (stop of all reels 31, signals of various switches (start switch 41, (left, middle, right) stop switch 42) are turned off). By executing the addition process of, the processes up to the medal payout process (M_WIN_PAY) at the time of winning can be made common. That is, the processes up to the medal payout process (M_WIN_PAY) at the time of winning can be made common without determining the credit amount at the start of the game, so that the amount of ROM used by the program can be reduced.

In addition, for example, the winning number “10” is won by the winning combination lottery means 61, the small winning combination A1 condition device (FIG. 124) is activated, and a small winning combination 01 of 15 payouts or a small winning of 3 payouts. It is assumed that any of the winning combinations 13 to 17 is ready for winning.
Further, the two reels 31 are stopped, the operation of the stop switch 42 corresponding to the third reel 31 (third reel 31) is accepted, and the symbol combination corresponding to the small winning combination 13 in which three payouts are made. It is assumed that (FIG. 119) can be stopped and displayed.

Under such a situation (when two reels 31 are stopped), the third reel 31 is stopped even if a predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses. If the operation of the stop switch 42 corresponding to the reel 31 is still accepted, the medal payout process (M_WIN_PAY) at the time of winning is not executed. When the stop switch 42 corresponding to the third reel 31 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.

In this way, in the game in which the symbol combination for paying out (giving) of medals is stopped and displayed, if the stop switch 42 corresponding to the third reel 31 is continuously operated, the medal payout process at the time of winning (M_WIN_PAY ) Is not executed and the stop switch 42 corresponding to the third reel 31 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

In addition, the start switch 41 and the three (left, middle, right) stop switches 42 are irrespective of whether or not a predetermined period for performing the four-phase excitation output for stopping the third reel 31 has elapsed. If any of the above operations is accepted, the result is “No” in step S1307 of FIG. 236, and the process after step S291 is not proceeded. Therefore, the medal payout process (M_WIN_PAY) at the time of winning is not executed.
Then, when the start switch 41 and the three (left, middle, right) stop switches 42 are all released and a predetermined period for performing the four-phase excitation output for stopping the third reel 31 has elapsed, FIG. Since the result of step S1307 is “Yes” and the process proceeds to step S291 and subsequent steps, the medal payout process (M_WIN_PAY) at the time of winning can be executed.

In this way, in the game in which the symbol combination for paying out (giving) of medals is stopped and displayed, operation of one of the start switch 41 and the three (left, middle, right) stop switches 42 is continued. Then, when the medal payout process (M_WIN_PAY) at the time of winning is not executed and the start switch 41 and the three (left, middle, right) stop switches 42 are all released, the medal payout process at the time of winning (M_WIN_PAY) is executed. It will be possible.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Even if the power switch 11 is unintentionally turned off and the power-off process is executed under the condition that the stop switch 42 corresponding to the third reel 31 is operated, By turning on the power switch 11 while the stop switch 42 corresponding to the eye reel 31 is being operated, the medal payout process (M_WIN_PAY) at the time of winning is not executed and the reel 31 is used. When the stop switch 42 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
Thus, even when the power is cut off at an unintended timing, the player can add the number of credits or pay out medals from the hopper 35 at a desired timing.

Similarly, for example, even if the four-phase excitation output of the motors 32 of all reels 31 including the motor 32 of the reel 31 that stops last (for example, the right reel 31) ends, the reel 31 that stops last (for example, the right reel 31). ), the stop switch 42 corresponding to the reel 31 stopped first (for example, the left reel 31) is operated, and then the stop switch corresponding to the reel 31 stopped first is operated. When the stop switch 42 corresponding to the reel 31 stopped last is released while the switch 42 is being operated, even if the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses, Do not execute the medal payout process (M_WIN_PAY) when winning. Then, when the stop switch 42 corresponding to the reel 31 that stopped first (for example, the left reel 31) is released (at least when all the stop switches are released), it is possible to execute the medal payout process (M_WIN_PAY) at the time of winning. Become.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Also in the present embodiment, as in the sixth embodiment, the medal payout device 15 rotates the hopper 35 for storing medals, the hopper disc 101 provided at the bottom of the hopper 35, and the hopper disc 101. A hopper motor 36 for this purpose and payout sensors 37a and 37b for detecting the payout of medals are provided.
Furthermore, the main control board 50 is electrically connected to the medal payout device 15 and controls the drive of the hopper motor 36.

Further, the hopper motor 36 is a DC motor (direct current motor), and when the drive signal of the hopper motor 36 is turned on and a current is supplied to the hopper motor 36, the rotation of the drive shaft is gradually accelerated from the stopped state. , And eventually reaches a constant speed (constant speed). After that, when the drive signal of the hopper motor 36 is turned off, the rotation of the drive shaft is gradually decelerated from the constant speed state, and then stopped.
When the rotation of the drive shaft is stopped, the rotation of the drive shaft can be suddenly stopped by supplying a current to the hopper motor 36 in a direction opposite to the direction in which the medals are paid out.

Here, the maximum value of the current required to perform the four-phase excitation output to the motor 32 (stepping motor) to stop the reel 31 is set to “500 to 800 mA” for one motor 32. ..
Further, the maximum value of the current required to drive the hopper motor 36 is set to "2.5 to 4.0 A (2500 to 4000 mA)".
Furthermore, when the lamps and LEDs controlled by the main control board 50 side (for example, the credit number display LED 76, the acquired number display LED 78, etc.) are turned on, a current of "1A" is required.

When a current exceeding “10 A” flows on the main control board 50 side, the protection circuit provided on the main control board 50 determines that the current is an overcurrent (overload) and turns off the power (turns off). Is set.
When the power is shut off at this time, the power shutoff process may not be executed. Temporarily, during a game (for example, when the number of credits is "50", the winning lottery means 61 wins the winning number "10", all reels 31 stop, and a symbol combination for giving three medals In the case where is displayed in a stopped state, such a power interruption occurs in the medal payout processing at the time of winning (immediately before executing the medal payout processing by driving the hopper motor 36), and the power cutoff processing is executed. If not, even if it recovers from the power failure, it will be a non-recoverable error, and after canceling the non-recoverable error (performing setting change processing), the game will be restored in the state in which the power failure occurred There is a case in which it becomes impossible (for example, the process of giving three medals is not executed), and the player is disadvantaged.

The fuse of the power supply board may be cut off when an overcurrent flows on the main control board 50 side. In this case, if the fuse blows, even if the power switch 11 is turned on, it will not recover from the power failure (failure).
On the side of the sub control board 80, power management is performed separately from the side of the main control board 50.

As described above, the maximum value of the current required to drive the hopper motor 36 (DC motor) is the maximum value of the current required to perform the four-phase excitation output to the motor 32 (stepping motor) to stop the reel 31. It is set larger than the maximum value.
Therefore, when the hopper motor 36 is driven, it is preferable not to execute the control that requires a large current in order to secure the current necessary for that purpose.

Therefore, as described above, after the operation of the stop switch 42 corresponding to the third reel 31 is accepted and before the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses. (For example, the timing at which the 4-phase excitation output for stopping the third reel 31 is performed or the timing before the 4-phase excitation output for stopping the third reel 31 is performed) Even if the stop switch 42 corresponding to the reel 31 of the eye is released, the medal payout process (M_WIN_PAY) at the time of winning is not executed, but the medal payout process at the time of winning (M_WIN_PAY) is executed after the predetermined period has elapsed. I have to.

Thus, the hopper motor 36 (DC motor) is not driven while the motor 32 (stepping motor) is being four-phase excited, and the hopper motor 36 can be driven after the four-phase excitation of the motor 32 is completed. Therefore, it is possible to secure the electric current required to drive the hopper motor 36. That is, the current required to drive the hopper motor 36 can be reliably ensured, and thus the hopper motor 36 can be reliably driven.

Further, as described in the twenty-third embodiment, in the reel drive management (I_REEL_ADM) (FIG. 151, FIG. 152) of step S841 during the interrupt process (I_INTR), the right reel 31, the middle reel 31, and the left reel 31 are sequentially arranged. The drive control of the motors 32 (stepping motors) of the three reels 31 is sequentially performed. As a result, the drive control of the three motors 32 can be executed by one interrupt process.
Then, in the port output process (FIG. 151) of step S462 during the interrupt process (I_INTR), drive signals can be simultaneously output to the three motors 32.

This makes it possible to start the rotations of the three reels 31 and the motor 32 all at once, and then to rotate all of them at a constant speed.
Further, when the operation of any one of the stop switches 42 is accepted when the three reels 31 are rotating at a constant speed, the other two reels 31 are operated while being rotated at a constant speed. It is possible to stop the rotation by performing a four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 that has been accepted.

Furthermore, when three reels 31 are rotating at a constant speed, when any two stop switches 42 are sequentially operated quickly, the remaining one reel 31 is rotated at a constant speed. As it is, the motor 32 of the reel 31 corresponding to the stop switch 42 for which the operation has been accepted first is subjected to the four-phase excitation output to stop the rotation, and the operation is performed later regardless of whether or not the four-phase excitation output is completed. It is possible to stop the rotation by performing a four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 that has been accepted.

Further, before the first reel 31 is stopped and a predetermined period for performing the four-phase excitation output for stopping the second reel 31 has elapsed (for example, when the second reel 31 is stopped by The operation of the stop switch 42 corresponding to the third reel 31 is accepted at the timing of performing the phase excitation output or the timing before performing the four-phase excitation output for stopping the second reel 31). In this case, the four-phase excitation output for stopping the third reel 31 can be executed even before the predetermined period has elapsed.
As described above, in order to stop one of the reels 31, the operation of the other stop switch 42 is accepted and the stop switch 42 is operated before the predetermined period of time for performing the four-phase excitation output to the motor 32 of the reel 31 elapses. By enabling the four-phase excitation output to the motor 32 of the reel 31 corresponding to 42, the game can be smoothly advanced.

Further, as described above, the maximum value of the current required to perform the four-phase excitation output to one motor 32 (stepping motor) is “500 to 800 mA”, and therefore the three motors 4 have four phases. The maximum value of the current required to perform the excitation output is “1500 to 2400 mA”.
Since the maximum value of the current required to drive one hopper motor 36 is "2500-4000 mA", the maximum value of the current required to perform the four-phase excitation output to one motor 32. Is smaller than the maximum value of the current required to drive one hopper motor 36. Further, the maximum value of the current required to perform the four-phase excitation output to the three motors 32 is smaller than the maximum value of the current required to drive the single hopper motor 36.
Therefore, even if three-phase motors 32 are simultaneously subjected to four-phase excitation output, sufficient current can be secured to stop them.

The twenty-ninth embodiment of the present invention has been described above, but the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the above embodiment, in step S1301, the data stored in the input port level data A (_PT_IN_A_LV) (FIG. 133) of the address “F012(H)” of the RWM 53 is stored in the A register. Not exclusively.
For example, the data of the input port 51 to which the left stop switch signal, the middle stop switch signal, the right stop switch signal, and the start switch signal are input may be directly stored in the A register.

(2) In the above embodiment, the logical product (AND) operation of the A register value and the mask data “01000111(B)” is performed in step S1302, but the invention is not limited to this.
For example, data indicating ON/OFF of the signal of the 3-bet switch 40b is stored in the D3 bit of the input port level data A(_PT_IN_A_LV) (FIG. 133) of the address “F012(H)” of the RWM 53. Similarly, data indicating ON/OFF of the signal of the 1 bet switch 40a is stored in the D4 bit, data indicating ON/OFF of the signal of the settlement switch 43 is stored in the D5 bit, and the door switch is stored in the D7 bit. Data indicating ON/OFF of the signal of 17 is stored.

Then, in step S1301, the data of the input port level data A (_PT_IN_A_LV) is stored in the A register, and in the next step S1302, the logical product (AND) operation of the A register value and the mask data “11111111(B)” is performed. You can go.
Thus, in addition to the start switch 41, the left stop switch 42, the middle stop switch 42, and the right stop switch 42, even when one of the signals of the 1 bet switch 40a, the 3 bet switch 40b, and the door switch 17 is turned on, It is possible to make a determination of “No” in step S1307 of FIG. 236. That is, it is possible to prevent the display determination in step S291 of FIG. 236 and the medal payout process (M_WIN_PAY) at the time of winning in step S294 from proceeding.

(3) In the above embodiment, the logical product (AND) operation of the A register value and the mask data “01111111(B)” is performed in step S1306, but the invention is not limited to this.
For example, in step S1306, even if "00001111(B)" is used as the mask data, the same calculation result as above can be obtained.
Further, in the present embodiment, since the reel drive control (I_REEL_CTL) is executed once every two interrupts, the D7 bit of the # reel drive state (_WK_RL#_STS) is "0" or "1" for each interrupt process. It will be. Therefore, if the D7 bit of the # reel drive state (_WK_RL#_STS) is always “0”, not limited to such specifications, in step S1306, the mask data is “11111111(B)”. It is also possible to use.

(4) For example, when the # reel driving state (_WK_RL#_STS) of the reel 31 to be stopped finally becomes “10000000 (B)” or “00000000 (B)”, the four-phase excitation output is finished. It may be determined that the reel 31 has stopped.
Then, the input port level data A (_PT_IN_A_LV) is "00000000 (B)", and the #3 reel drive state (_WK_RL#_STS) of the reel 31 that stops last is "10000000 (B)" or "0000000 (B)". )”, the display determination in step S291 of FIG. 236 or the medal payout process (M_WIN_PAY) at the time of winning in step S294 may be performed.

(5) For example, when the # reel motor signal data (_PT_MOTOR#) of the reel 31 to be stopped last is “00000000(B)”, that is, the φ1 to φ4 data of the motor 32 are all “0”. When it becomes, it may be determined that the four-phase excitation output has ended and that the reel 31 has stopped.
When the input port level data A (_PT_IN_A_LV) is “00000000(B)” and the #31 reel motor signal data (_PT_MOTOR#) of the reel 31 to be stopped at the end is “00000000(B)”, You may make it progress to the display determination of step S291 of 236, and the medal payout process (M_WIN_PAY) at the time of winning in step S294.

(6) For example, when the # reel motor signal data (_PT_MOTOR#) of all the reels 31 becomes “00000000(B)”, the four-phase excitation output of all the motors 32 ends and all the reels 31 May be determined to have stopped.
That is, the first reel motor signal data (_PT_MOTOR1), the second reel motor signal data (_PT_MOTOR2), and the third reel motor signal data (_PT_MOTOR3) are sequentially ORed (OR), and the result is "0000000(B)". It may be determined that the four-phase excitation outputs of all the motors 32 have ended and all the reels 31 have stopped.
When the input port level data A (_PT_IN_A_LV) is “00000000(B)” and the # reel motor signal data (_PT_MOTOR#) of all reels 31 is “00000000(B)”, You may make it progress to the display determination of step S291, and the medal payout process (M_WIN_PAY) at the time of winning in step S294.

(7) For example, when the # reel drive pulse output counter (_CT_RL#_PLSOUT) of the reel 31 to be stopped finally is “00000000(B)”, it is determined that the four-phase excitation output has ended, and the reel 31 May be determined to have stopped.
When the input port level data A (_PT_IN_A_LV) is “00000000(B)” and the reel #31 drive pulse output counter (_CT_RL#_PLSOUT) of the reel 31 to be stopped finally is “00000000(B)”. The display determination in step S291 of FIG. 236 or the medal payout process (M_WIN_PAY) at the time of winning in step S294 may be performed.
Note that, again, the # reel drive pulse output counter (_CT_RL#_PLSOUT) is updated (subtracted) by interrupt processing. This point is the same in the other embodiments.

(8) For example, when the # reel drive pulse output counters (_CT_RL#_PLSOUT) of all reels 31 are “00000000(B)”, the four-phase excitation outputs of all the motors 32 are completed, It may be determined that the reel 31 has stopped.
That is, the first reel drive pulse output counter (_CT_RL1_PLSOUT), the second reel drive pulse output counter (_CT_RL2_PLSOUT), and the third reel drive pulse output counter (_CT_RL3_PLSOUT) are sequentially ORed (OR), and the result is "0000000". (B)”, it may be determined that the four-phase excitation outputs of all the motors 32 have ended and all the reels 31 have stopped.
When the input port level data A (_PT_IN_A_LV) is "00000000 (B)" and the # reel drive pulse output counters (_CT_RL#_PLSOUT) of all reels 31 are "00000000 (B)", You may make it progress to the display determination of step S291 of 236, and the medal payout process (M_WIN_PAY) at the time of winning in step S294.

(9) In the above-described embodiment, after the operation of any one of the stop switches 42 is accepted, before the predetermined period of performing the four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 elapses (for example, At the timing of performing the four-phase excitation output for stopping the reel 31 and the timing before performing the four-phase excitation output for stopping the reel 31), the operation of the other stop switch 42 is accepted and other Although the four-phase excitation output can be executed for the motor 32 of the reel 31 corresponding to the stop switch 42, the present invention is not limited to this.
For example, after the operation of any one of the stop switches 42 is accepted and before the predetermined period of time for performing the four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 has passed, the operation of the other stop switch 42 is performed. May not be accepted and the stop control of the other reels 31 may not be executed.

In addition, after the operation of any one of the stop switches 42 is accepted, the operation of another stop switch 42 is accepted until the four-phase excitation output is started to the motor 32 of the reel 31 corresponding to the stop switch 42. Instead, the stop control of the other reels 31 may not be executed.
Furthermore, the operation of the other stop switch 42 is not accepted and the stop control of the other reel 31 is not executed within a predetermined period in which the motor 32 of one of the reels 31 outputs the four-phase excitation. Can also

Here, as in the above-described embodiment, after the operation of any one of the stop switches 42 is accepted, before a predetermined period of performing the four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 elapses ( For example, when the operation of the other stop switch 42 is accepted at the timing of performing the four-phase excitation output for stopping the reel 31 or the timing before performing the four-phase excitation output for stopping the reel 31), If the four-phase excitation output can be executed for the motor 32 of the reel 31 corresponding to the other stop switch 42, the operation order of the stop switch 42 and the stop order of the reel 31 may be switched.

Specifically, for example, when the three reels 31 are rotating at a constant speed, it is assumed that the left stop switch 42 and the middle stop switch 42 are quickly operated in this order. Then, it is assumed that the operation of the left stop switch 42 is accepted and then the operation of the middle stop switch 42 is accepted before the left reel 31 is stopped. At this time, after the operation of the left stop switch 42 is accepted, the number of moving symbols (the number of sliding frames) from when the left reel 31 is stopped is set to “4”, and after the operation of the middle stop switch 42 is accepted. It is assumed that the number of moving symbols until the middle reel 31 is stopped is set to "0". In such a case, the middle reel 31 may stop first, and then the left reel 31 may stop.

Therefore, after the operation of any one of the stop switches 42 is accepted, before the predetermined period of performing the four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 elapses, the operation of the other stop switch 42 is performed. If the stop control of other reels 31 is not executed and the stop order of the stop switch 42 and the stop order of the reels 31 are switched, it is possible to prevent them from being exchanged.

Similarly, until the operation of one of the stop switches 42 is accepted and the four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 is started, the operation of the other stop switch 42 is performed. Even when the stop control of the other reels 31 is not executed without being accepted, it is possible to prevent the operation order of the stop switch 42 and the stop order of the reels 31 from being interchanged.
Also, when the operation of the other stop switch 42 is not accepted and the stop control of the other reel 31 is not executed during the predetermined period in which the motor 32 of one of the reels 31 outputs the four-phase excitation. It is possible to prevent the operation order of the stop switch 42 and the stop order of the reel 31 from being interchanged.

(10) In the above embodiment, when the reel 31 and the motor 32 are stopped, the four-phase excitation output is performed to the motor 32 (stepping motor) as the excitation output for stopping the reel 31. However, the present invention is not limited to this. Absent.
When the reel 31 and the motor 32 are stopped, the excitation output for stopping the reel 31 may be, for example, one-phase excitation output, two-phase excitation output, or three-phase excitation output. May be. In addition, first, two-phase excitation output is performed to weaken the brake, then the two-phase excitation output is switched to the four-phase excitation output, and the stronger brake is applied to stop the rotation of the reel 31 and the motor 32. It may be allowed to.
(11) The first to twenty-ninth embodiments and the various modifications shown in the first to twenty-ninth embodiments are not limited to be performed alone, but may be appropriately combined and performed.

<30th Embodiment>
In the thirtieth embodiment, based on the data stored in the #reel management timer (_WK_RL#_TIME) (FIG. 237) of the RWM 53, the predetermined period for performing the four-phase excitation output for stopping the reel 31 has elapsed. Determine whether or not. Also, during the predetermined period of performing the 4-phase excitation output, the medal payout process (M_WIN_PAY) at the time of winning is not executed. Then, when the data stored in the # reel management timer (_WK_RL#_TIME) becomes “0”, it is determined that the predetermined period for performing the 4-phase excitation output has passed (the 4-phase excitation output has ended), and then , The medal payout process (M_WIN_PAY) at the time of winning is executed.

The symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
FIG. 237 is a diagram showing main data according to the thirtieth embodiment among the data stored in the RWM 53 in the thirtieth embodiment. Note that the data shown in FIG. 237 is a part of data, and various data other than the illustrated data is stored in the RWM 53.
In FIG. 237, the input port 2 level data (_PT_IN2_OLD) of the address “F005 (H)” is the input sensor 1 signal (D0 bit), the input sensor 2 signal (D1 bit), which is input to each bit of the input port 2. This is a storage area for storing ON/OFF of the full detection signal (D3 bit) and the stop cancellation signal (D4 bit).

The input sensor 1 signal means a signal that is turned on when the input sensor 44a (FIG. 2) detects a medal and is turned off when no medal is detected.
Further, the insertion sensor 2 signal means a signal which is turned on when the insertion sensor 44b (FIG. 2) detects a medal and is turned off when no medal is detected.
Furthermore, a sub-tank for accommodating medals overflowing from the hopper 35 and a full sensor that is turned on when the sub-tank comes into contact with the medals when the sub-tank is full are provided. Means a signal that is turned on when is touched and turned off when the medal is not touched.

Further, it is possible to execute a normal game and a special game (1BB game) that is advantageous to the player, and when the normal game is shifted to the special game, the game is stopped at the end of the special game and the progress of the game is stopped. Is possible. The condition for stopping is not limited to the end of the special game, and can be set appropriately. In addition, a stop release switch is provided, and when the condition for stopping is satisfied, the stop release switch is operated to release the stop so that the game can proceed. The stop release signal means a signal that is turned on when the stop release switch is operated and turned off when released. The stop release switch can also be used as other switches such as the setting switch 13 and the reset switch 14.

Then, in the interrupt processing this time, the signal input to each bit of the input port 2 is read, and it is determined whether the closing sensor 1 signal, the closing sensor 2 signal, the full detection signal, or the stop cancellation signal is turned on or off, When it is, "1" is stored in the corresponding bit, and when it is off, "0" is stored in the corresponding bit.

In FIG. 237, the input port 4 level data (_PT_IN4_OLD) of the address “F006 (H)” is the setting/reset switch signal (D1 bit), the settlement switch signal (D3 bit), which is input to each bit of the input port 4. This is a storage area for storing ON/OFF of the 1 bet switch signal (D4 bit), the 2 bet switch signal (D5 bit), the 3 bet switch signal (D6 bit), and the start switch signal (D7 bit).
The setting/reset switch signal means a signal of the setting change (reset) switch 153 which also serves as a setting change switch and a reset switch.

The settlement switch signal means a signal that is turned on when the settlement switch 43 is operated and turned off when released.
The 1 bet switch signal means a signal that is turned on when the 1 bet switch 40a is operated and turned off when the 1 bet switch 40a is released.

Furthermore, the 3-bet switch signal means a signal that turns on when the 3-bet switch 40b is operated and turns off when the 3-bet switch 40b is released.
Further, a 2-bet switch for inserting two medals is provided, and the 2-bet switch signal means a signal which is turned on when the 2-bet switch is operated and turned off when the 2-bet switch is released.
Furthermore, the start switch signal means the signal of the start switch 41.

Then, in the interrupt processing this time, a signal input to each bit of the input port 4 is read, and a setting/reset switch signal, a settlement switch signal, a 1 bet switch signal, a 2 bet switch signal, a 3 bet switch signal, and a start signal. The on/off state of the switch signal is judged. When it is on, "1" is stored in the corresponding bit, and when it is off, "0" is stored in the corresponding bit.

In FIG. 237, the input port 3 level data (_PT_IN3_OLD) of the address “F00A(H)” is the first stop switch signal (D0 bit) and the second stop switch signal (D1 bit) input to each bit of the input port 3. ) And ON/OFF of the third stop switch signal (D2 bit).

The #th stop switch signal means a signal which is turned on when the #stop switch 42 is operated and turned off when the #stop switch 42 is released.
Then, in the interrupt processing this time, the signal input to each bit of the input port 3 is read, the on/off state of the first stop switch signal, the second stop switch signal, and the third stop switch signal is determined, and the on state is turned on. When it is, "1" is stored in the corresponding bit, and when it is off, "0" is stored in the corresponding bit.

In FIG. 237, reel stop order data (_NB_STOP_ORDER) at address “F007(H)” is a storage area for storing data that manages the stop order of the reels 31.
In step S1311, which will be described later, in FIG. 238, reel stop order data (_NB_STOP_ORDER) is initialized (cleared, initial value “0” is set). After that, the value of the reel stop order data (_NB_STOP_ORDER) is incremented by "1" every time step S1323 of FIG. 239 described later is executed. Then, when the value of the reel stop order data (_NB_STOP_ORDER) becomes the number of reels "3", it becomes "Yes" in step S1315 of FIG. 238 described later.

In FIG. 237, stop reel number data (_NB_STOP_REEL) at the address “F008(H)” is a storage area for storing data indicating the reel number at the time of stop acceptance.
When the first stop switch signal is turned on (the operation of the first stop switch 42 is accepted), the stop reel number data (_NB_STOP_REEL) indicates "1 ( D)” is stored.

When the second stop switch signal is turned on (operation of the second stop switch 42 is accepted), the stop reel number data (_NB_STOP_REEL) indicates the second reel 31 in step S1322 of FIG. 239 described later. 2(D)” is stored.
Further, when the third stop switch signal is turned on (operation of the third stop switch 42 is accepted), the stop reel number data (_NB_STOP_REEL) indicates the third reel 31 in step S1322 of FIG. 239 described later. 3(D)” is stored.

In FIG. 237, the first reel management timer (_WK_RL1_TIME) at the address “F020(H)” is a timer that manages the four-phase excitation output time of the first reel 31. That is, it is a storage area for storing data for measuring a predetermined time for performing a four-phase excitation output for stopping the first reel 31.
When deceleration of the first reel 31 is started (when four-phase excitation output to the motor 32 of the first reel 31 is started), the initial value “108(D)” is set in the first reel management timer (_WK_RL1_TIME). .. After that, the value of the first reel management timer (_WK_RL1_TIME) is decremented by "1" every time the interrupt process is executed. When the value of the first reel management timer (_WK_RL1_TIME) is "1" or more, four-phase excitation output is performed to the motor 32 of the first reel 31 for each interrupt process. Then, when the value of the first reel management timer (_WK_RL1_TIME) becomes “0”, the four-phase excitation output to the motor 32 of the first reel 31 ends.

In the present embodiment, the interrupt processing cycle is set to “2.235 ms”, and the value of the # reel management timer (_WK_RL#_TIME) is decremented by “1” for each interrupt processing.
Therefore, it takes "2.235×108=241.38 ms" until the value of the # reel management timer (_WK_RL#_TIME) changes from "108 (D)" to "0 (D)". The four-phase excitation output continues for “241.38 ms”, and the four-phase excitation output ends when “241.38 ms” elapses.
That is, in the present embodiment, the “predetermined period” in which the four-phase excitation output for stopping the reel 31 is performed corresponds to “241.38 ms”.

Further, in FIG. 237, the second reel management timer (_WK_RL2_TIME) of the address “F030(H)” is a timer for managing the four-phase excitation output time of the second reel 31. That is, it is a storage area for storing data for measuring a predetermined time for performing the four-phase excitation output for stopping the second reel 31.
Further, in FIG. 237, the third reel management timer (_WK_RL3_TIME) of the address “F040(H)” is a timer for managing the four-phase excitation output time of the third reel 31. That is, it is a storage area for storing data for measuring a predetermined time for performing the four-phase excitation output for stopping the third reel 31.
These contents are the same as the first reel management timer (_WK_RL1_TIME) of the address "F020 (H)".

FIG. 238 is a flowchart showing the main processing (M_MAIN) in the thirtieth embodiment, and is a flowchart corresponding to FIG. 139 of the twenty-third embodiment.
In the flowchart of the thirtieth embodiment shown in FIG. 238, steps different from those in FIG. 139 are underlined in step numbers, and steps identical to those in FIG. 139 are given identical step numbers.

Further, also in the main process (M_MAIN) of the thirtieth embodiment, the processes of steps S295 to S300 of FIG. 139 are executed, but in FIG. 238, the processes of steps S295 to S300 are omitted.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 238, in the thirtieth embodiment, when the start switch acceptance process (M_START_CTL) of step S751 is executed, the process proceeds to step S1311, and the main control board 50 initializes the reel stop order data (_NB_STOP_ORDER). (Clear, set initial value "0"). Then, the process proceeds to next Step S1312.
In step S1312, the main control board 50 executes a reel stop acceptance check. This process is a process shown in FIG. 239 described later. When the reel stop acceptance check in step S1312 is completed, the process advances to step S1313.

When proceeding to step S1313, the main control board 50 executes an input inspection. This process is a process shown in FIG. 240 described later. Then, when the input inspection in step S1313 is completed, the process proceeds to step S1314.
In step S1314, the main control board 50 determines whether or not there is input port level data (the carry flag of the flag register is set to "1").
Here, proceeding to step S1337 in FIG. 240 described later, “1” is set to the carry flag bit of the flag register. The carry flag set in step S1337 serves as a flag indicating that there is input port level data.
The flag register is updated when some arithmetic processing is executed. Therefore, even if the carry flag bit is "1", it may be updated to "0" by another operation process.

Closing sensor 1 signal, closing sensor 2 signal, stop release signal, first stop switch signal, second stop switch signal, third stop switch signal, setting/reset switch signal, settlement switch signal, 1 bet switch signal, 2 bet switch If any of the signal, the 3-bet switch signal, and the start switch signal is turned on, a flag indicating that there is input port level data is set in step S1337 of FIG. 240, which will be described later (in the carry register bit of the flag register. "1" is set).

On the other hand, when all of the above signals are off, step S1337 of FIG. 240, which will be described later, is skipped, so that the flag indicating that there is input port level data is not set.
Note that, in step S1337 of FIG. 240, which will be described later, the signal to be checked when the flag indicating the presence of the input port level data is set is not limited to the above signals, but can be set appropriately.
For example, some of the above signals, such as the stop cancellation signal and the setting/reset switch signal, do not need to be checked when setting the flag indicating that there is input port level data.
On the contrary, in addition to the above signals, for example, signals of other switches such as the door switch 17 and the setting key switch 152 may be checked when the flag indicating the presence of the input port level data is set.

Then, in step S1314, when the carry flag bit is set to "1", it is determined that there is input port level data ("Yes"), and the process returns to step S1313. In this case, the processes of steps S1313 and S1314 are repeated.
The flag register is updated when returning to the input inspection in step S1313 and performing some arithmetic processing. As a result, even if the carry flag bit is "1", it may be updated to "0" by another operation process.

On the other hand, in step S1314, when the carry flag bit is not set to "1", it is determined that there is no input port level data ("No"), and the flow advances to step S1315.
Accordingly, when any of the above signals is on, the process does not proceed to step S1315, and when all of the above signals are off, the process can proceed to step S1315.

In step S1315, the main control board 50 determines whether the value of the reel stop order data (_NB_STOP_ORDER) and the number of reels “3” are the same value. That is, it is determined whether stop control has been executed for all reels 31.
If it is determined that the value of the reel stop order data (_NB_STOP_ORDER) and the number of reels "3" are not the same, the process returns to step S1312. As a result, the processing from step S1312 to step S1315 is repeated until the stop control is executed for all reels 31. When it is determined that the value of the reel stop order data (_NB_STOP_ORDER) and the number of reels “3” are the same value, it is determined that the stop control has been executed for all reels 31, and the process proceeds to step S1316.

When proceeding to step S1316, the main control board 50 executes an all reel stop check. This process is a process shown in FIG. 241 described later. Then, when the check for stopping all reels in step S1316 is completed, the process proceeds to step S291.
In step S291, the main control board 50 executes display determination. That is, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed. Then, the process proceeds to the next step S292.

If “No” in the step S292 and the process of the step S293 is executed, the process proceeds to a step S294.
In step S294, the main control board 50 executes a medal payout process (M_WIN_PAY) at the time of winning. That is, when the number of credits has not reached the upper limit value “50”, the number of credits is added, and when the number of credits has reached the upper limit value “50”, the hopper motor 36 is driven to make the actual value. The medals are paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

FIG. 239 is a flowchart showing the reel stop acceptance check in step S1312 of FIG. 238.
In step S1321, the main control board 50 determines whether or not there is stop acceptance. That is, it is determined whether the operation of any of the first stop switch 42 to the third stop switch 42 has been accepted.
Specifically, the main control board 50 sets the D0 bit (first stop switch signal), D1 bit (second stop switch signal), D2 bit of the input port 3 level data (_PT_IN3_OLD) of the address "F00A(H)". It is determined whether or not (third stop switch signal) is on. Then, step S1321 is repeated until there is stop acceptance, and if there is stop acceptance, the process proceeds to the next step S1322.

In step S1322, the main control board 50 stores stop reel number data according to the stop switch signal.
Specifically, when the first stop switch signal is ON (operation of the first stop switch 42 is accepted), "1 (D)" indicating the first reel 31 is added to the stop reel number data (_NB_STOP_REEL). Remember.

When the second stop switch signal is ON (operation of the second stop switch 42 is accepted), “2(D)” indicating the second reel 31 is stored in the stop reel number data (_NB_STOP_REEL).
Further, when the third stop switch signal is ON (operation of the third stop switch 42 is accepted), “3(D)” indicating the third reel 31 is stored in the stop reel number data (_NB_STOP_REEL).
Then, when the stop reel number data corresponding to the stop switch signal is stored, the process proceeds to the next step S1323.

In step S1323, the main control board 50 adds "1" to the value of the reel stop order data (_NB_STOP_ORDER) of the address "F007(H)". Then, the process proceeds to the next step S1324.
When the processing proceeds to step S1324, the main control board 50 executes the processing at the time of stop acceptance. In this processing, the stop position of the #reel 31 is determined based on the result of the lottery result of the game this time and the position of the #reel 31 at the moment when the operation of the #stop switch 42 is accepted, and the determined stop is determined. The symbol number corresponding to the position is stored in the # reel symbol number (for stop position). Further, the stop symbol data for determining the symbol combination to be stopped on the activated line is updated. Then, the processing according to this flowchart is ended.

More specifically, in the process at the time of stop acceptance in step S1324 of FIG. 239, the process corresponding to steps S1022 to S1024 in FIG. 194 of the 25th embodiment is executed. That is, with respect to the reel 31 corresponding to the stop switch 42 determined to be on in step S1321, by the process corresponding to steps S1022 to S1023 of FIG. 194, the winning combination lottery result of this game and the operation of the stop switch 42 are accepted. The stop position of the reel 31 is determined based on the position of the reel 31 at the moment, and the symbol number corresponding to the determined stop position is stored in the reel symbol number (for the stop position). Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated. Then, the processing according to this flowchart is ended.

By the interrupt process executed after the process of step S1324 (the process corresponding to steps S1022 to S1024 in FIG. 194 of the twenty-fifth embodiment), the # reel symbol number (for passing position) and the # reel symbol number ( 4) for stopping the motor 32 of the #31 reel 31 by setting the initial value "108(D)" to the #reel management timer (_WK_RL#_TIME) when it is determined that the same value is obtained. Start phase excitation output.
Further, the # reel symbol number (for passing position) and the # reel symbol number (for stop position) have the same value, and the step number of one symbol of the # reel 13 is a predetermined value (for example, “ 3”), the initial value “108(D)” may be set in the # reel management timer to start the four-phase excitation output for stopping the motor 32 of the # reel 31.

FIG. 240 is a flowchart showing the input inspection in step S1313 of FIG. 238.
In step S1331, the main control board 50 acquires the data stored in the input port 2 level data (_PT_IN2_OLD) (FIG. 237) of the address “F005(H)” of the RWM 53. Then, the process proceeds to the next Step S1332.

In step S1332, the main control board 50 determines whether or not the closing sensor 1 signal, the closing sensor 2 signal, and the stop cancellation signal are on.
Specifically, whether or not the D0 bit (close sensor 1 signal), D1 bit (close sensor 2 signal), D4 bit (stop cancellation signal) of the acquired input port 2 level data (_PT_IN2_OLD) is "1". To judge.
Then, in step S1332, when it is determined that any of the signals is on, the process proceeds to step S1337, and when it is determined that any of the signals is off, the process proceeds to next step S1333.

In step S1333, the main control board 50 acquires the data stored in the input port 3 level data (_PT_IN3_OLD) (FIG. 237) of the address “F00A(H)” of the RWM 53. Then, the process proceeds to the next Step S1334.
In step S1334, the main control board 50 determines whether the first stop switch signal, the second stop switch signal, and the third stop switch signal are on.

Specifically, the D0 bit (first stop switch signal), D1 bit (second stop switch signal), D2 bit (third stop switch signal) of the acquired input port 3 level data (_PT_IN3_OLD) is "1". Determine if there is.
Then, in step S1334, when it is determined that any of the signals is on, the process proceeds to step S1337, and when it is determined that any of the signals is off, the process proceeds to next step S1335.

In step S1335, the main control board 50 acquires the data stored in the input port 4 level data (_PT_IN4_OLD) (FIG. 237) of the address “F006(H)” of the RWM 53. Then, the process proceeds to the next step S1336.
In step S1336, the main control board 50 determines whether the setting/reset switch signal, the settlement switch signal, the 1 bet switch signal, the 2 bet switch signal, the 3 bet switch signal, and the start switch signal are on. ..

Specifically, D1 bit (setting/reset switch signal), D3 bit (settlement switch signal), D4 bit (1 bet switch signal), D5 bit (2 bet switch signal) of the acquired input port 4 level data (_PT_IN4_OLD) ), D6 bit (3 bet switch signal) and D7 bit (start switch signal) are "1".
Then, in step S1336, when it is determined that any of the signals is on, the process proceeds to step S1337, and when it is determined that all of the signals are off, the process according to this flowchart is ended.

In step S1337, the main control board 50 sets a flag indicating that there is input port level data. Specifically, "1" is set to the carry flag bit of the flag register. Here, if a flag (carry flag) indicating that there is input port level data is set, it becomes “Yes” in step S1314 of FIG. 238. On the other hand, if step S1337 is skipped, the flag (carry flag) indicating that there is input port level data is not set, and thus "No" is obtained at step S1314 in FIG. 238. When step S1337 is executed, the process according to this flowchart is ended.

FIG. 241 is a flow chart showing the all reel stop check in step S1316 of FIG. 238.
In step S1341, the main control board 50 sets the address of the #th reel management timer (_WK_RL#_TIME) corresponding to the stop reel number data (_NB_STOP_REEL).
Specifically, in step S1341, the main control board 50 first stores the data stored in the stop reel number data (_NB_STOP_REEL) of the address “F008(H)” of the RWM 53 in the A register.

Here, at the time of proceeding to step S1316, the reel number of the reel 31 corresponding to the third (last) operated stop switch 42 is stored in the stop reel number data (_NB_STOP_REEL) of the address “F008(H)”. Has been done.
For example, when the third (last) operated stop switch 42 is the third (right) stop switch 42, the stop reel number data (_NB_STOP_REEL) of the address “F008(H)” is reached at the time of proceeding to step S1316. Stores "3(D)" indicating the third (right) reel 31.

Next, "F010(H)", which is the result of subtracting "16(D)" from the address "F020(H)" of the first reel management timer (_WK_RL1_TIME), is stored in the HL register. This "F010 (H)" becomes the reference address.
Next, the A register value is multiplied by “16(D)” and the result is stored in the A register.
Next, the A register value is added to the HL register value, and the result is stored in the HL register.
Then, the process proceeds to the next step S1342.

In step S1342, the main control board 50 determines whether or not the data stored in the # reel management timer (_WK_RL#_TIME) is “0”.
Then, the process of step S1342 is repeated until the data stored in the #th reel management timer (_WK_RL#_TIME) becomes “0”, and the data stored in the #reel management timer (_WK_RL#_TIME) When the value becomes "0", the process according to this flowchart ends.
In this way, in this embodiment, when the data of the # reel management timer (_WK_RL#_TIME) for the reel 31 corresponding to the third (last) operated stop switch 42 becomes “0”, this flowchart Ends the process.

Specifically, in step S1342, the main control board 50 determines whether the data stored in the address indicated by the HL register value (the # reel management timer (_WK_RL#_TIME)) is “0”. To do.
Then, when the data stored at the address indicated by the HL register value is not "0"("No"), the process of step S1342 is executed again. That is, the process of step S1342 is repeated.

On the other hand, when the data stored at the address indicated by the HL register value is "0"("Yes"), the process according to this flowchart is ended.
When the data stored in the address indicated by the HL register value (the # reel management timer (_WK_RL#_TIME)) becomes “0”, the process proceeds to the display determination of step S291 of FIG. 238, and then the winning of step S294. Proceed to the medal payout process (M_WIN_PAY).
As a result, after a predetermined period of four-phase excitation output to the motor 32 of the reel 31 corresponding to the third (last) operated stop switch 42 has elapsed, display determination and medal payout processing at the time of winning (M_WIN_PAY) Can be executed.

More specifically, for example, "3(D)" indicating the third (right) reel 31 is stored in the stop reel number data (_NB_STOP_REEL) (Fig. 237) of the address "F008(H)" of the RWM 53. Suppose That is, it is assumed that the third (last) operated stop switch 42 is the third (right) stop switch 42. In this case, by the process of step S1341, first, “3(D)” is stored in the A register.

Next, "F010(H)" which is the result of subtracting "16(D)" from the address "F020(H)" of the first reel management timer (_WK_RL1_TIME) is stored in the HL register. This "F010 (H)" becomes the reference address.
Next, "48(D)" which is the result of multiplying the A register value "3(D)" by "16(D)" is stored in the A register.
Next, "F040(H)" which is the result of adding the A register value "48(D)" to the HL register value "F010(H)" is stored in the HL register.

Then, the processing proceeds to the next step S1342, and is the data stored at the address indicated by the HL register value “F040(H)”, that is, the data stored in the third reel management timer (_WK_RL3_TIME) “0”? Determine whether or not.
If the data stored in the address indicated by the HL register value (third reel management timer (_WK_RL3_TIME)) is not "0"("No"), the process of step S1342 is executed again. That is, the process of step S1342 is repeated. In this case, the process after step S291 in FIG. 238 does not proceed.

On the other hand, when the data stored in the address indicated by the HL register value (third reel management timer (_WK_RL3_TIME)) is "0"("Yes"), the process according to this flowchart is ended.
When the data stored in the address indicated by the HL register value (third reel management timer (_WK_RL3_TIME)) becomes “0”, the process proceeds to step S291 in FIG. 238 and then to step S294.
As a result, after a predetermined period of four-phase excitation output to the motor 32 of the reel 31 corresponding to the third (last) operated stop switch 42 has elapsed, display determination and medal payout processing at the time of winning (M_WIN_PAY) Can be executed.

Here, for example, the winning number “10” is won by the winning combination lottery means 61, the small winning combination A1 condition device (FIG. 124) is activated, and a small winning combination of 15 payouts, or three winnings is paid out. It is assumed that any of the small wins 13 to 17 is ready to win.
Further, the two reels 31 are stopped (under the situation where the excitation output for stopping the reels 31 of the two reels 31 is completed), the stop switch 42 corresponding to the third reel 31 It is assumed that the operation is accepted and the symbol combination (FIG. 119) corresponding to the small winning combination 13 of three payouts can be stopped and displayed.

Under such a circumstance, after the operation of the stop switch 42 corresponding to the third reel 31 is accepted and before the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses. (For example, the timing when the four-phase excitation output for stopping the third reel 31 and the timing before the four-phase excitation output for stopping the third reel 31 are performed) Even if the stop switch 42 corresponding to the reel 31 of the eye is released, the result is “No” in step S1342 of FIG. 241 and the processing after step S291 of FIG. 238 is not proceeded. Do not run.
That is, when the data stored in the # reel management timer (_WK_RL#_TIME) for the third reel 31 is “1” or more, four-phase excitation for stopping the third reel 31 is performed. Since the output continues and step S1342 of FIG. 241 is repeated, the process does not proceed to step S291 and subsequent steps of FIG. 238. Therefore, even if the stop switch 42 corresponding to the third reel 31 is released, the medal payout at the time of winning is won. Do not execute processing (M_WIN_PAY ).

Then, when the data stored in the # reel management timer (_WK_RL#_TIME) for the third reel 31 becomes “0”, the four-phase excitation output for stopping the third reel 31 ends. Then, the result of step S1342 of FIG. 241 is “Yes”, and the process proceeds to step S291 of FIG. 238. Therefore, the medal payout process (M_WIN_PAY) at the time of winning of step S294 can be executed.
In the medal payout process (M_WIN_PAY) at the time of winning, the process of adding the credit number is executed until the credit number reaches the upper limit value "50", and when the credit number reaches the upper limit value "50", the hopper The process of outputting the drive signal of the motor 36 is executed, the hopper motor 36 is driven, and the actual medal is paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

As described above, also in the present embodiment, as in the twenty-ninth embodiment, after the operation of the stop switch 42 corresponding to the third reel 31 is accepted, the fourth reel for stopping the third reel 31 is performed. Before the lapse of a predetermined period for performing the phase excitation output (for example, the timing of performing the four-phase excitation output for stopping the third reel 31 or the four-phase excitation for stopping the third reel 31). Even if the stop switch 42 corresponding to the third reel 31 is released at the timing (before the output), the medal payout process (M_WIN_PAY) at the time of winning is not executed, and after a predetermined period of time, at the time of winning. The medal payout process (M_WIN_PAY) is executed.

Thus, the hopper motor 36 (DC motor) is not driven while the motor 32 (stepping motor) is being four-phase excited, and the hopper motor 36 can be driven after the four-phase excitation of the motor 32 is completed. Therefore, it is possible to secure the electric current required to drive the hopper motor 36. That is, the current required to drive the hopper motor 36 can be reliably ensured, and thus the hopper motor 36 can be reliably driven.

In addition, in the present embodiment, switches for inputting signals to the input ports 3 and 4 (setting/resetting switch 153, settlement switch 43, 1-bed switch 40a, 2-bet switch, 3-bet switch 40b, start switch 41, If any operation of the (left, center, right) stop switch 42) is accepted, “Yes” is determined in step S1314 of FIG. 238, and the process of step S1315 and subsequent steps is not proceeded. The medal payout process (M_WIN_PAY) at the time of winning is not executed regardless of whether or not a predetermined period for performing the four-phase excitation output for stopping the reel 31 has elapsed.

When all the switches for inputting the signals to the input port 3 and the input port 4 are released, the result in step S1314 in FIG. 238 is "No", and the process proceeds to step S1315 and subsequent steps. At this time, the reel 31 that is finally stopped. After a lapse of a predetermined period of performing the four-phase excitation output for stopping the display, the display determination process and the medal payout process (M_WIN_PAY) at the time of winning can be executed.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Further, in the present embodiment, the # reel management timer (_WK_RL#_TIME) for storing data for measuring a predetermined time for performing the four-phase excitation output for stopping the # reel 31 is provided. This #th reel management timer (_WK_RL#_TIME) is a storage area dedicated to data for measuring a predetermined time for performing a four-phase excitation output.
When the data stored in the # reel management timer (_WK_RL#_TIME) is “1” or more (not “0”), the four-phase excitation output of the motor 32 of the # reel 31 is continued, When the data stored in the #th reel management timer (_WK_RL#_TIME) becomes “0”, the 4-phase excitation output of the motor 32 of the #th reel 31 is terminated.

As a result, by checking the data stored in the # reel management timer (_WK_RL#_TIME), it is determined whether or not a predetermined period for performing the 4-phase excitation output to the motor 32 of the # reel 31 has elapsed (4 phase Whether or not the excitation output is being performed) can be easily determined.
Particularly, in the present embodiment, since only the data of the #reel management timer (_WK_RL#_TIME) for the reel 31 corresponding to the third (last) operated stop switch 42 is checked, the 4-phase excitation output ends. It is possible to simplify the process for determining whether or not it is possible to reduce the amount of ROM used by the program.

It should be noted that the two reels 31 are stopped (under the situation where the excitation output for stopping the reels 31 has been completed for the two reels 31), the stop switch 42 corresponding to the third reel 31 Under the situation that the operation is accepted and the symbol combination for paying out (giving) of medals can be stopped and displayed, the state in which the operation of the stop switch 42 corresponding to the third reel 31 is still accepted Suppose that it continued.

In this case, "Yes" is obtained in step S1334 of FIG. 240, and a flag (carry flag) indicating that there is input port level data is set in step S1337. Then, in step S1314 of FIG. 238, the result is “Yes”, the processes of steps S1313 and S1314 are repeated, and the process of step S1315 and subsequent steps is not performed. Therefore, four-phase excitation output for stopping the third reel 31 is performed. Even if the predetermined period has elapsed, the medal payout process (M_WIN_PAY) at the time of winning is not executed.
Then, when the stop switch 42 corresponding to the third reel 31 is released, the result is "No" in step 1314 of FIG. 238, and the processing proceeds to step S1315 and thereafter, so the medal payout processing (M_WIN_PAY) at the time of winning is executed. It will be possible.

Similarly, for example, even if the four-phase excitation output of the motors 32 of all reels 31 including the motor 32 of the reel 31 that stops last (for example, the right reel 31) ends, the reel 31 that stops last (for example, the right reel 31). ), the stop switch 42 corresponding to the reel 31 stopped first (for example, the left reel 31) is operated, and then the stop switch corresponding to the reel 31 stopped first is operated. When the stop switch 42 corresponding to the reel 31 stopped last is released while the switch 42 is being operated, even if the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses, Do not execute the medal payout process (M_WIN_PAY) when winning.
Then, when the stop switch 42 corresponding to the reel 31 that stopped first (for example, the left reel 31) is released (at least when all the stop switches are released), it is possible to execute the medal payout process (M_WIN_PAY) at the time of winning. Become.

In this way, in the game in which the symbol combination for paying out (giving) of medals is stopped and displayed, if the stop switch 42 corresponding to the third reel 31 is continuously operated, the medal payout process at the time of winning (M_WIN_PAY ) Is not executed and the stop switch 42 corresponding to the third reel 31 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
Similarly, in the game in which the symbol combination for paying out (giving) medals is stopped and displayed, when the stop switch 42 corresponding to any reel 31 is continuously operated, the medal payout process (M_WIN_PAY) at the time of winning is When the stop switches 42 corresponding to all the reels 31 are not released and are released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Even if the power switch 11 is unintentionally turned off and the power-off process is executed under the condition that the stop switch 42 corresponding to the third reel 31 is operated, By turning on the power switch 11 while the stop switch 42 corresponding to the eye reel 31 is being operated, the medal payout process (M_WIN_PAY) at the time of winning is not executed and the reel 31 is used. When the stop switch 42 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
Thus, even when the power is cut off at an unintended timing, the player can add the number of credits or pay out medals from the hopper 35 at a desired timing.

Further, in the present embodiment, the main control board 50 first puts the bet number at which the game can be executed, and then first, the input port 2 level data (_PT_IN2_OLD) of the address “F005(H)” of the RWM 53 (FIG. 237). The data stored in is acquired and it is determined whether the acquired data is "0".
Furthermore, when it is determined that the acquired data is “0”, the data stored in the input port 4 level data (_PT_IN4_OLD) (FIG. 237) of the address “F006(H)” of the RWM 53 is next read. The obtained data is subjected to a logical product (AND) operation of the obtained data and "01111111(B)", and it is determined whether or not the result is "0".
Further, when it is determined that the result of the logical product operation is “0”, it is next determined whether or not the rising data of the start switch 41 is on.

Then, when it is determined that the rising data of the start switch 41 is ON, the rotation start control of the reel 31 based on the operation of the start switch 41 is executed.
On the other hand, when it is determined that the data stored in the input port 2 level data (_PT_IN2_OLD) of the address "F005(H)" is not "0", it is determined that the result of the above logical product operation is not "0". If so, the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed.
As a result, after the bet number capable of executing the game has been bet and the operation of the bet switch 40 (1 bet switch 40a, 3 bet switch 40b) is accepted, the start switch 41 is operated. When accepted, the rotation start control of the reel 31 based on the operation of the start switch 41 may not be executed.

The present embodiment also includes the setting key switch 152 as described in the eleventh embodiment and the nineteenth embodiment (A).
Then, as described in the eleventh embodiment and the nineteenth embodiment (A), the front door 12 is opened and the door switch 17 is turned on while the power is on and the bet number is not bet. When the setting key is turned on and the setting key is inserted into the setting key insertion port 151 and rotated 90 degrees clockwise, for example, and the setting key switch 152 is turned on (when the signal of the setting key switch 152 is turned on), the setting confirmation state is displayed. Move to (Setting Confirmation Mode).

Note that when the bet number is bet, the result is “Yes” in step S274 in FIG. 41, and the process does not proceed to the medal insertion waiting process in step S275. Do not move.
In the setting confirmation state, the setting value cannot be changed (though the setting value does not change even if the setting change switch 153 is operated), but the current setting value can be confirmed. The current set value is displayed on the set value display LED 73. When the setting key is rotated counterclockwise and the setting key switch 152 is turned off, the setting confirmation state ends.

Then, as described above, in the present embodiment, when the rotation start control of the reel 31 is executed, the data stored in the input port 2 level data (_PT_IN2_OLD) of the address “F005(H)” and the address “F006 (H)”. The data stored in the input port 4 level data (_PT_IN4_OLD) of "(H)" is checked, but the data of the input port to which the signal of the setting key switch 152 is input is not checked.

For example, do not check the data of the input port where the signal of the setting key switch 152 is input, do not check the level data of the RWM 53 corresponding to the input port where the signal of the setting key switch 152 is input, and do not check the level data of the setting key switch. Of the data of the input port to which the signal of 152 is input, the bit corresponding to the signal of the setting key switch 152 is not checked, and the level data of the RWM 53 corresponding to the input port to which the signal of the setting key switch 152 is input. Among them, the bit corresponding to the signal of the setting key switch 152 is not checked.

Therefore, after the bet number (the bet number corresponding to the specified number) capable of executing the game is bet, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is ON), Further, when the operation of the start switch 41 is accepted under the condition that the front door 12 is closed (the door switch 17 is off), the rotation start control of the reel 31 based on the operation of the start switch 41 can be executed. And

Here, after the bet switch 40 is operated, even if the bet switch 40 is released, the bet switch 40 may deteriorate and the operation of the bet switch 40 may remain accepted.
Then, in a state where the operation of the bet switch 40 is still accepted, in the present embodiment, even if the start switch 41 is operated, the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed.

Similarly, even after the adjustment switch 43 is released after the adjustment switch 43 is operated, the start switch is operated even when the adjustment switch 43 is deteriorated and the operation of the adjustment switch 43 remains accepted. Even if 41 is operated, the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed.
As a result, even if the player operates the start switch 41, the reel 31 does not rotate, so that the player can recognize that some abnormality has occurred in the slot machine 10. Then, the player informs the clerk of the hall to that effect, so that the clerk of the hall can also recognize that something is wrong with the slot machine 10.
Even if the operation of the bet switch 40 or the settlement switch 43 remains accepted, neither the main control board 50 nor the sub control board 80 gives an error notification. This is because if the error notification is given in such a case, the player may be annoyed.

Further, it is not normally considered that the setting key switch 152 is turned on (the signal of the setting key switch 152 is turned on) during the game, and the signal of the setting key switch 152 is temporarily input (setting key switch If the signal of 152 is on), it is likely to be noise. Therefore, in the present embodiment, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on when the bet number capable of executing the game (the bet number corresponding to the specified number) is bet). If the operation of the start switch 41 is accepted under the condition that the front door 12 is closed (the door switch 17 is off), the rotation start control of the reel 31 based on the operation of the start switch 41 is performed. To be executable.
With this, it is possible to prevent the progress of the game from being interrupted by noise.

On the other hand, under the condition that the signal of the setting key switch 152 is ON, a predetermined external signal (for example, the external signal 4 for notifying an error or the like (the eleventh embodiment) is based on the signal of the setting key switch 152 being ON. It is possible to notify the hall computer or the like by outputting the form FIG. 33)). Therefore, a store clerk or the like in the hall can recognize that some error has occurred in the slot machine 10 to which a predetermined external signal is output.
In addition, under the condition that the signal of the setting key switch 152 is on, a predetermined external signal (for example, the external signal X (see FIG. 33 of the eleventh embodiment) that can specify that the signal of the setting key switch 152 is on. External signals 1 to 5)) may be output.

Further, in the present embodiment, the main control board 50 first inputs the input port 2 level data (_PT_IN2_OLD) (_PT_IN2_OLD) of the address “F005(H)” of the RWM 53 at the timing when the time for which the stop acceptance of the reel 31 is impossible has elapsed (FIG. 237). ) Is acquired, and it is determined whether the acquired data is “0”.
Furthermore, when it is determined that the acquired data is “0”, the data stored in the input port 4 level data (_PT_IN4_OLD) (FIG. 237) of the address “F006(H)” of the RWM 53 is next read. The acquired data is subjected to a logical product (AND) operation of the acquired data and “11111111(B)”, and it is determined whether or not the result is “0”.
Furthermore, when it is determined that the result of the logical product operation is "0", it is next determined whether or not the rising data of the #stop switch 42 is on.

When it is determined that the rising data of the #stop switch 42 is ON, the stop control of the #reel 31 based on the operation of the #stop switch 42 is executed.
On the other hand, when it is determined that the data stored in the input port 2 level data (_PT_IN2_OLD) of the address "F005(H)" is not "0", it is determined that the result of the above logical product operation is not "0". If so, the stop control of the #th reel 31 based on the operation of the #stop switch 42 is not executed.
As a result, when the operation of the #th stop switch 42 (for example, the left stop switch 42) is accepted in a situation where the plurality of reels 31 are rotating at a constant speed and the operation of the start switch 41 is accepted. In addition, it is possible not to execute the stop control of the # reel 31 (for example, the left reel 31) based on the operation of the # stop switch 42 (for example, the left stop switch 42).

Further, as described above, in the present embodiment, when the stop control of the # reel 31 is executed, the data stored in the input port 2 level data (_PT_IN2_OLD) of the address “F005(H)” and the address “F005(H)”. The data stored in the input port 4 level data (_PT_IN4_OLD) of "F006 (H)" is checked, but the input port data to which the signal of the setting key switch 152 is input is not checked.

For example, do not check the data of the input port where the signal of the setting key switch 152 is input, do not check the level data of the RWM 53 corresponding to the input port where the signal of the setting key switch 152 is input, and do not check the level data of the setting key switch. Of the data of the input port to which the signal of 152 is input, the bit corresponding to the signal of the setting key switch 152 is not checked, and the level data of the RWM 53 corresponding to the input port to which the signal of the setting key switch 152 is input. Among them, the bit corresponding to the signal of the setting key switch 152 is not checked.

Therefore, the plurality of reels 31 rotate at a constant speed, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on), and the front door 12 is closed (the door switch 17 is off. Under the situation, when the operation of the #stop switch 42 is accepted, the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed.

Here, after the start switch 41 is operated, even if the start switch 41 is released, there is a possibility that the operation of the start switch 41 remains accepted due to deterioration of the start switch 41.
Then, in a state where the operation of the start switch 41 is still accepted, in the present embodiment, even if the #stop switch 42 is operated, the stop control of the #reel 31 based on the operation of the #stop switch 42 is executed. do not do.

Similarly, even after the bet switch 40 (the 1 bet switch 40a and the 3 bet switch 40b) is operated and then the bet switch 40 is released, the operation of the bet switch 40 remains accepted due to deterioration of the bet switch 40. When the adjustment switch 43 is released after the adjustment switch 43 is operated, the operation of the adjustment switch 43 remains accepted due to deterioration of the adjustment switch 43. As for the above, even if the #stop switch 42 is operated, the stop control of the #reel 31 based on the operation of the #stop switch 42 is not executed.

As a result, the player can recognize that some abnormality has occurred in the slot machine 10 because the # reel 31 does not stop even if the # stop switch 42 is operated. Then, the player informs the clerk of the hall to that effect, so that the clerk of the hall can also recognize that something is wrong with the slot machine 10.
Even if the operation of the bet switch 40, the start switch 41, and the adjustment switch 43 remains accepted, neither the main control board 50 nor the sub control board 80 gives an error notification. This is because if the error notification is given in such a case, the player may be annoyed.

Further, it is not normally considered that the setting key switch 152 is turned on (the signal of the setting key switch 152 is turned on) during the game, and the signal of the setting key switch 152 is temporarily input (setting key switch If the signal of 152 is on), it is likely to be noise. Therefore, in the present embodiment, the plurality of reels 31 rotate at a constant speed, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on), and the front door 12 is closed ( When the operation of the #stop switch 42 is accepted under the situation where the door switch 17 is off), the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed.
With this, it is possible to prevent the progress of the game from being interrupted by noise.

On the other hand, under the condition that the signal of the setting key switch 152 is ON, a predetermined external signal (for example, the external signal 4 for notifying an error or the like (the eleventh embodiment) is based on the signal of the setting key switch 152 being ON. It is possible to notify the hall computer or the like by outputting the form FIG. 33)). Therefore, a store clerk or the like in the hall can recognize that some error has occurred in the slot machine 10 to which a predetermined external signal is output.
In addition, under the condition that the signal of the setting key switch 152 is on, a predetermined external signal (for example, the external signal X (see FIG. 33 of the eleventh embodiment) that can specify that the signal of the setting key switch 152 is on. External signals 1 to 5)) may be output.

Although the thirtieth embodiment of the present invention has been described above, the present invention is not limited to the contents described above, and various modifications such as the following are possible.
(1) In the above embodiment, in the all reel stop check, only the data of the # reel management timer (_WK_RL#_TIME) for the reel 31 corresponding to the third (last) operated stop switch 42 is checked. It is not limited to this.
For example, in the all reel stop check, the data of the #th reel management timer (_WK_RL#_TIME) for all reels 31 may be checked.

Specifically, in the all reel stop check, first, the data stored in the first reel management timer (_WK_RL1_TIME) is stored in the A register.
Next, the logical sum (OR) operation of the A register value and the data stored in the second reel management timer (_WK_RL2_TIME) is performed, and the result is stored in the A register value.
Next, the logical sum (OR) operation of the A register value and the data stored in the third reel management timer (_WK_RL3_TIME) is performed, and the result is stored in the A register value.

Then, when it is determined whether or not the A register value is "0", and when it is determined that the A register value is not "0"("No"), it is stored in the first reel management timer (_WK_RL1_TIME). The process returns to the process of storing data in the A register. That is, the processes after the process of storing the data stored in the first reel management timer (_WK_RL1_TIME) in the A register are repeated. In this case, the process after step S291 in FIG. 238 does not proceed.
On the other hand, when it is determined that the A register value is “0” (“Yes”), the all reel stop check is ended, the process proceeds to step S291 in FIG. 238, and then the process proceeds to step S294. Thereby, the display determination and the medal payout process (M_WIN_PAY) at the time of winning the prize are sequentially executed.

Here, when the left reel 31 is stopped and the middle reel 31 and the right reel 31 are rotating at a constant speed, it is assumed that the middle stop switch 42 and the right stop switch 42 are quickly operated in this order. Then, it is assumed that the operation of the middle stop switch 42 is accepted and then the operation of the right stop switch 42 is accepted before the middle reel 31 is stopped. At this time, after the operation of the middle stop switch 42 is accepted, the number of moving symbols (the number of sliding frames) from when the middle reel 31 is stopped is set to "4", and after the operation of the right stop switch 42 is accepted. It is assumed that the number of moving symbols until the right reel 31 is stopped is set to "0". In such a case, the right reel 31 may stop first, and then the middle reel 31 may stop.

That is, the reel 31 corresponding to the stop switch 42 operated third (last) is stopped second (first), and the reel 31 corresponding to the stop switch 42 operated second is third (last). It may stop.
In this case, as in the above embodiment, in the all-reel stop check, only the data of the # reel management timer (_WK_RL#_TIME) for the reel 31 corresponding to the third (last) operated stop switch 42 is checked. However, it cannot be determined that the four-phase excitation output for all reels 31 has ended.

Therefore, as in this modification (1), in the all reel stop check, by checking the data of the #reel management timer (_WK_RL#_TIME) for all reels 31, the operation order of the stop switch 42, Even if the stop order of the reels 31 is changed, it is possible to determine that the four-phase excitation output for all reels 31 has ended, and a predetermined period for performing the four-phase excitation output for all reels 31 has elapsed. After that, the medal payout process (M_WIN_PAY) at the time of winning can be executed.

(2) In the above embodiment, in step S1337 of FIG. 240, the carry flag bit of the flag register is set to "1" as a flag indicating that there is input port level data, but the present invention is not limited to this.
For example, predetermined information may be stored in a predetermined storage area of the RWM 53 as a flag indicating that there is input port level data.
In this case, the predetermined information stored in the predetermined storage area of the RWM 53 is not cleared when some arithmetic processing is executed like the bit data of the flag register, and therefore, for example, the step in the input inspection of FIG. Before S1331, a process of clearing the predetermined information stored in the predetermined storage area of the RWM 53 is executed.

(3) In the above-described embodiment, when the operation of the #stop switch 42 is accepted in a situation where the plurality of reels 31 are rotating at a constant speed and the operation of the start switch 41 is accepted, The stop control of the # reel 31 based on the operation of the stop switch 42 is not executed.
However, the present invention is not limited to this, and for example, when the operation of the #stop switch 42 is accepted under the situation that the plurality of reels 31 are rotating at a constant speed and the operation of the start switch 41 is accepted, The stop control of the # reel 31 based on the operation of the # stop switch 42 may be made executable.

Thus, for example, when the left stop switch 42 is operated first and the middle stop switch 42 is operated second, when the left stop switch 42 is operated, the start switch 41 is deteriorated and the start switch 41 is deteriorated. Since the operation of 41 is still accepted, it can be prevented that the middle stop switch 42 is initially operated.

Particularly, in the AT machine, if it is determined that the middle stop switch 42 is operated first even though the left stop switch 42 is operated first, the pushing order is mistaken, which causes a disadvantage to the player. However, even if the operation of the start switch 41 is accepted, by making it possible to execute the stop control of the #reel 31 based on the operation of the #stop switch 42, it is possible to make a mistake in the pushing order during AT. Occurrence can be prevented.

Specifically, for example, in the game in which the winning number “10” is won by the winning combination lottery means 61 and the small winning combination A1 condition device (FIG. 124) is activated during the general game of the 1BB game (when 1BB is operated), the correct answer is given. The pressing order is left center right, but at this time, if it is determined that the middle stop switch 42 is operated first, even if the left stop switch 42 is operated first, a pressing order error occurs and a small Any one of the winning combinations 13 to 17 (three winning combinations) will be won.
In this case, where the player is disadvantaged, even if the operation of the start switch 41 is accepted, the stop control of the left reel 31 based on the operation of the left stop switch 42 can be executed, so that the correct answer is pressed. Since the small winning combination 01 (15 winning combinations) is won in order, it is possible to prevent the occurrence of a situation in which the pressing order is mistaken during AT.
For example, the same applies when the winning number “16” is won by the winning combination lottery means 61 and the small winning combination B1 condition device (FIG. 125) is activated.

Even if the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed under the condition that the operation of the start switch 41 is accepted as in this modification, the setting key The stop control of the #reel 31 based on the operation of the #stop switch 42 may be executed regardless of whether the signal of the switch 152 is turned on or off. Further, when the signal of the setting key switch 152 is ON, the stop control of the #th reel 31 based on the operation of the #stop switch 42 may not be executed.

(4) For example, in a situation where the operation of the first stop switch 42 is accepted and then the operation of the first stop switch 42 remains accepted, the operation of the second stop switch 42 can be accepted. At the same time, the stop control of the corresponding reel 31 may be executable based on the operation of the second stop switch 42.

Thus, for example, even if the left stop switch 42, the middle stop switch 42, and the right stop switch 42 are operated in this order, when the middle stop switch 42 is operated, the left stop switch 42 is deteriorated due to deterioration of the stop switch 42 or the like. Since the operation of 42 is still accepted, it can be prevented that the right stop switch 42 is secondly operated.

In particular, in the AT machine, when the stop operation is performed in the order of the left stop switch 42, the middle stop switch 42, and the right stop switch 42, even though the middle stop switch 42 is operated second, the right stop switch 42 is operated second. If it is determined that the stop switch 42 has been operated, it will be a mistake in the pushing order, which will be disadvantageous to the player. Even if the operation of any of the stop switches 42 is still accepted, other The operation of the stop switch 42 can be accepted, and the stop control of the corresponding reel 31 can be executed on the basis of the operation of the other stop switch 42, so that a mistake in the pushing order during AT will occur. It is possible to prevent the occurrence of a situation.

Specifically, for example, in the game in which the winning number “10” is won by the winning combination lottery means 61 and the small winning combination A1 condition device (FIG. 124) is activated during the normal game of the 1BB game (when 1BB is operated), the correct answer is given. The pressing order is left, middle, right. At this time, if it is determined that the right stop switch 42 has been operated secondly even though the middle stop switch 42 has been operated secondly, a pressing order error will occur. Any of the small winning combinations 13 to 17 (three winning combinations) will be awarded.
In this case, where the player is disadvantaged, even if the operation of the left stop switch 42 is accepted, it is possible to execute the stop control of the middle reel 31 based on the operation of the middle stop switch 42. Since it is in the push order and the small winning combination 01 (15 winning combinations) is won, it is possible to prevent the occurrence of a situation such as a mistake in the pushing order during AT.
For example, the same applies when the winning number “16” is won by the winning combination lottery means 61 and the small winning combination B1 condition device (FIG. 125) is activated.

Even in the case where the stop control of the reel 31 based on the operation of the second stop switch 42 can be executed under the condition that the operation of the first stop switch 42 is still accepted as in this modification. The stop control of the reel 31 based on the operation of the stop switch 42 may be executable regardless of whether the signal of the setting key switch 152 is turned on or off. Further, when the signal of the setting key switch 152 is ON, the stop control of the reel 31 based on the operation of the stop switch 42 may not be executed.

(5) In the above embodiment, when the reel 31 and the motor 32 are stopped, the four-phase excitation output is performed to the motor 32 (stepping motor) as the excitation output for stopping the reel 31. However, the present invention is not limited to this. Absent.
When the reel 31 and the motor 32 are stopped, the excitation output for stopping the reel 31 may be, for example, one-phase excitation output, two-phase excitation output, or three-phase excitation output. May be. In addition, first, two-phase excitation output is performed to weaken the brake, then the two-phase excitation output is switched to the four-phase excitation output, and the stronger brake is applied to stop the rotation of the reel 31 and the motor 32. It may be allowed to.

(6) The content and arrangement of each bit of the input port 2 to 4 level data shown in FIG. 237 are merely examples, and the present invention is not limited to this content and arrangement. The contents and arrangement of each bit of the input port 2 to 4 level data can be set appropriately.
For example, for the D4 bit of the input port 2 level data (_PT_IN2_OLD) at the address “F005(H)”, the stop release signal ON/OFF may not be stored and may be unused.

Further, for example, for the input port 4 level data (_PT_IN4_OLD) of the address “F006(H)”, the ON/OFF of the setting/reset switch signal may not be stored in the D1 bit, and the D0 to D2 bits may be unused. ..
Furthermore, for example, ON/OFF of the first to third stop switch signals may be stored in the D0 to D2 bits of the input port 4 level data (_PT_IN4_OLD) of "F006(H)", respectively.
Further, the flow chart of the input inspection in FIG. 240 can be appropriately changed according to the content and arrangement of each bit of the input port 2 to 4 level data.

It is preferable that the input port for inputting the signal of the setting key switch 152 and the input port for inputting the signal of the bet switch 40, the start switch 41, and the stop switch 42 are different, but the bet switch 40, the start switch. The signal of the setting key switch 152 may be input to the input port to which the signals of 41 and the stop switch 42 are input.
Further, in the above-described embodiment, the data stored in the storage area of the input port 2 to 4 level data of the RWM 53 is acquired to determine the ON/OFF of each signal, but the data stored in the RWM 53 is acquired. Instead, the signals input to the input ports 2 to 4 may be directly acquired to determine ON/OFF of each signal.

(7) In the input inspection flowchart of FIG. 240, in step S1331, the data of the input port 2 level data (_PT_IN2_OLD) of the address "F005(H)" is acquired, and in step S1332, the input sensor 1 signal and the input sensor 2 are input. Although it is determined whether the signal and the stop cancellation signal are ON, for example, the processes of steps S1331 and S1332 may not be performed.

Further, for example, ON/OFF of the first to third stop switch signals are stored in the D0 to D2 bits of the input port 4 level data (_PT_IN4_OLD) of "F006(H)", and the adjustment switch signal is stored in the D3 bit. The D4 bit stores a 1 bet switch signal, the D5 bit stores a 2 bet switch signal, the D6 bit stores a 3 bet switch signal, and the D7 bit stores ON/OFF of a start switch signal.
Then, for example, in the flowchart of the input inspection of FIG. 240, the processes of steps S1331 to S1334 may not be performed, and only the processes of steps S1335 to S1337 may be performed.
(8) The first to thirtieth embodiments and the various modifications shown in the first to thirtieth embodiments are not limited to be performed alone, but may be appropriately combined and implemented.

<31st Embodiment>
In the thirty-first embodiment, based on the data stored in the # reel motor signal data (_PT_MOTOR#) of the RWM 53 (_PT_MOTOR#) (FIG. 134 ), a predetermined period for performing the four-phase excitation output for stopping the reel 31 has elapsed. Determine whether or not. Also, during the predetermined period of performing the 4-phase excitation output, the medal payout process (M_WIN_PAY) at the time of winning is not executed. When the data stored in the # reel motor signal data (_PT_MOTOR#) becomes the stop pulse data “00000000(B)”, the predetermined period for performing the four-phase excitation output has passed (the four-phase excitation output is It is determined that the process has been completed), and then the medal payout process (M_WIN_PAY) at the time of winning is executed.

The symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
FIG. 242 is a flowchart showing the main processing (M_MAIN) in the 31st embodiment, and is a flowchart corresponding to FIG. 139 of the 23rd embodiment.
In the flowchart of the thirty-first embodiment shown in FIG. 242, steps different from those in FIG. 139 are underlined in step numbers, and steps identical to those in FIG. 139 are identical in step number.

Also, in the main processing (M_MAIN) of the 31st embodiment, the processing of steps S295 to S300 of FIG. 139 is executed, but the illustration of the processing of steps S295 to S300 is omitted in FIG. 242.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 242, in the 31st embodiment, when the start switch acceptance process (M_START_CTL) of step S751 is executed, the process proceeds to step S1351.
When proceeding to step S1351, the main control board 50 executes a reel stop acceptance check. This process is the same as the reel stop acceptance check (M_STOP_CHK) of FIG. 194 of the 25th embodiment.
Specifically, the data corresponding to the input port rising data A (_PT_IN_A_UP) at the address “F017(H)” in FIG. 133 is acquired by the process corresponding to steps S1016 to S1017 in FIG. 194, and the D0 to D2 bits (left, It is determined whether any of the middle and right stop switch signals) is on. Thus, it is determined whether or not the operation of any of the stop switches 42 has been accepted.

If it is determined that the operation of any of the stop switches 42 has been accepted, next, by the processing corresponding to steps S1022 to S1023 of FIG. 194, the result of the lottery of the current game and the operation of the stop switch 42 are accepted. The stop position of the reel 31 is determined based on the position of the reel 31 at the moment, and the symbol number corresponding to the determined stop position is stored in the # reel symbol number (for stop position) (FIGS. 135 to 137). To do.
Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated.
Then, by the interrupt process executed after the process of step S1351 (the process corresponding to the reel stop acceptance check (M_STOP_CHK) of FIG. 194 of the twenty-fifth embodiment), the # reel symbol number (for passing position) (FIG. 135 to FIG. 137) and the # reel symbol number (for stop position) are determined to be the same value, the # reel motor signal data (_PT_MOTOR#) (FIG. 134), deceleration pulse data "00001111 (B)" Set (4 phase on). As a result, four-phase excitation output to the motor 32 of the # reel 31 is started.

The # reel symbol number (for passing position) and the # reel symbol number (for stop position) have the same value, and the step number of one symbol on the # reel 13 is a predetermined value (for example, “ 3)), the deceleration pulse data “00001111(B)” may be set in the # reel motor signal data to start 4-phase excitation output to the motor 32 of the # reel 31. ..
When the reel stop acceptance check in step S1351 is completed, the process advances to step S1352.

In step S1352, the main control board 50 determines whether or not the reel stop acceptance check in step S1351 has been completed for all reels 31. That is, it is determined whether or not all the operations of the stop switches 42 have been accepted.
If it is determined in step S1352 that the reel stop acceptance check has not been completed for all reels 31, the process returns to step S1351. In this case, the processes of steps S1351 and S1352 are repeated.
On the other hand, if it is determined in step S1352 that the reel stop acceptance check has been completed for all reels 31, the process proceeds to the next step S1353.

In step S1353, the main control board 50 stores the data stored in the input port level data A (_PT_IN_A_LV) (FIG. 133) of the address “F012(H)” of the RWM 53 in the A register. Then, the process proceeds to next Step S1354.
In step S1354, the main control board 50 determines whether any stop switch signal is ON (operation of any stop switch 42 is accepted).

Specifically, the main control board 50 performs a logical product (AND) operation of the A register value and "00000111 (B)" and determines whether the result is "0". Thereby, it is determined whether or not any of the stop switch signals is ON, that is, whether or not the operation of any of the stop switches 42 is accepted.
Then, when the result of the logical product operation is not "0", it is determined that any of the stop switch signals is on (operation of any of the stop switches 42 is accepted), and in step S1354, " It becomes "Yes", and returns to step S1353.
On the other hand, when the result of the logical product operation is “0”, it is determined that none of the stop switch signals is off (operation of any of the stop switches 42 is not accepted), and in step S1354. If "No", the process proceeds to step S291.

Here, when at least one operation of the left stop switch 42, the middle stop switch 42, and the right stop switch 42 is accepted, at least one stop switch signal is turned on, and the input port level data A( At least one of D0 to D2 bits of _PT_IN_A_LV) becomes "1".
When at least one of the D0 to D2 bits of the input port level data A (_PT_IN_A_LV) is "1", the result of the above logical product operation is not "0".
Then, when the result of the logical product operation is not "0", "Yes" is obtained in the step S1354, and the process returns to the step S1353. That is, the processes of steps S1353 and S1354 are repeated. In this case, the display determination is not executed and the medal payout process (M_WIN_PAY) at the time of winning is not executed because the process of step S291 and the subsequent steps is not performed.

On the other hand, when the left stop switch 42, the middle stop switch 42, and the right stop switch 42 are all released, the left stop switch signal, the middle stop switch signal, and the right stop switch signal are all turned off. , D0 to D2 bits of the input port level data A (_PT_IN_A_LV) are all "0".
Further, when all the bits D0 to D2 of the input port level data A (_PT_IN_A_LV) are "0", the result of the above logical product operation is "0".
Then, when the result of the logical product operation is "0", the result is "No" in step S1354, and the flow proceeds to step S291.

When the processing proceeds to step S291, the main control board 50 executes display determination.
Specifically, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed on the activated line. Further, when the symbol combination for paying out (giving) of medals is stopped and displayed on the activated line, the payout number of tokens (number of grants) is determined. Then, the process proceeds to step S292.
It should be noted that the determined payout number (awarded number) of medals may be stored (saved) only in a predetermined register and not stored (saved) in the RWM 53, or may be stored (saved) in the RWM 53. Good.

If “No” in the step S292 and the process of the step S293 is executed, the process proceeds to a step S1355.
In step S1355, the main control board 50 determines whether or not the four-phase excitation output is being performed on the motor 32 of the reel 31 corresponding to the third (last) operated stop switch 42.
Specifically, the main control board 50 acquires the # reel motor signal data (_PT_MOTOR#) (FIG. 134) for the reel 31 corresponding to the third (last) operated stop switch 42, and the value thereof is acquired. Is "0".

Then, when the value of the #th reel motor signal data (_PT_MOTOR#) is not "0", it is determined that the four-phase excitation is being output, the result is "Yes" in step S1355, and the process of step S1355 is executed again. ..
On the other hand, when the value of the # reel motor signal data (_PT_MOTOR#) is "0", it is determined that the four-phase excitation output is not being performed, the determination result is "No" in step S1355, and the flow proceeds to step S294.

Here, it is assumed that the third (last) operated stop switch 42 is the right stop switch 42. In this case, in step S1355, the main control board 50 acquires the third reel motor signal data (_PT_MOTOR3) (FIG. 134) corresponding to the right reel 31.
When the right reel 31 starts decelerating, the third reel motor signal data (_PT_MOTOR3) stores the deceleration pulse data “000011111(B)” (four-phase on), and a predetermined period of four-phase excitation output has elapsed. Then, the stop pulse data “00000000(B)” is stored in the third reel motor signal data (_PT_MOTOR3).

Then, when the value of the third reel motor signal data (_PT_MOTOR3) is not "0", "Yes" is obtained in the step S1355, and the process of the step S1355 is executed again. That is, the process of step S1355 is repeated. In this case, since the process does not proceed to step S294, the medal payout process (M_WIN_PAY) at the time of winning is not executed.
On the other hand, when the value of the third reel motor signal data (_PT_MOTOR3) is "0", "No" is obtained in the step S1355, and the process proceeds to the step S294. As a result, the medal payout process (M_WIN_PAY) at the time of winning can be executed.

In step S294, the main control board 50 executes a medal payout process (M_WIN_PAY) at the time of winning. That is, when the number of credits has not reached the upper limit value “50”, the number of credits is added, and when the number of credits has reached the upper limit value “50”, the hopper motor 36 is driven to make the actual value. The medals are paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

Here, for example, the winning number “10” is won by the winning combination lottery means 61, the small winning combination A1 condition device (FIG. 124) is activated, and a small winning combination of 15 payouts, or three winnings is paid out. It is assumed that any of the small wins 13 to 17 is ready to win.
Further, the two reels 31 are stopped, the operation of the stop switch 42 corresponding to the third reel 31 is accepted, and the symbol combination (FIG. 119) corresponding to the small winning combination 13 of three payouts is stopped. Suppose that it can be displayed.

Under such circumstances, even after the stop switch 42 corresponding to the third reel 31 is released after the operation of the stop switch 42 corresponding to the third reel 31 is accepted, The #1 reel motor signal data (_PT_MOTOR#) corresponding to No. 31 is the deceleration pulse data “00001111(B)” (four-phase on, which indicates that the four-phase excitation output for stopping the third reel 31 is performed. ) Is stored, the result of step S1355 in FIG. 242 is “Yes” and the process does not proceed to step S294, so the medal payout process (M_WIN_PAY) at the time of winning is not executed.

That is, when the deceleration pulse data “00001111(B)” is stored in the # reel motor signal data (_PT_MOTOR#) corresponding to the third reel 31, the third reel 31 is stopped. Since the four-phase excitation output for this purpose continues and step S1355 of FIG. 242 is repeated, the process does not proceed to step S294. Therefore, even if the stop switch 42 corresponding to the third reel 31 is released, the medal payout process at the time of winning the prize is performed. (M_WIN_PAY) Do not execute processing.

Then, when the data stored in the # reel motor signal data (_PT_MOTOR#) corresponding to the third reel 31 becomes the stop pulse data “00000000(B)”, the third reel 31 is stopped. The four-phase excitation output for ending the process is ended, the result is “No” in step S1355 of FIG. 242, and the process proceeds to step S294, so that the medal payout process (M_WIN_PAY) at the time of winning can be executed.
In the medal payout process (M_WIN_PAY) at the time of winning, the process of adding the credit number is executed until the credit number reaches the upper limit value "50", and when the credit number reaches the upper limit value "50", the hopper The process of outputting the drive signal of the motor 36 is executed, the hopper motor 36 is driven, and the actual medal is paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

As described above, also in the present embodiment, similarly to the twenty-ninth and thirtieth embodiments, after the operation of the stop switch 42 corresponding to the third reel 31 is accepted, the third reel 31 is switched on. Before a predetermined period for performing the four-phase excitation output for stopping has elapsed (for example, the timing of performing the four-phase excitation output for stopping the third reel 31 or the third reel 31 is stopped). Even if the stop switch 42 corresponding to the third reel 31 is released at the timing before performing the four-phase excitation output, the medal payout process (M_WIN_PAY) at the time of winning is not executed, and After the lapse of time, the medal payout process (M_WIN_PAY) at the time of winning the prize is executed.
Thus, the hopper motor 36 (DC motor) is not driven while the motor 32 (stepping motor) is being four-phase excited, and the hopper motor 36 can be driven after the four-phase excitation of the motor 32 is completed. Therefore, it is possible to secure the current required to drive the hopper motor 36. That is, the current required to drive the hopper motor 36 can be reliably ensured, and thus the hopper motor 36 can be reliably driven.

Further, in the present embodiment, at the start of deceleration of the # reel 31, the deceleration pulse data “00001111(B)” (4 phase on) is stored in the # reel motor signal data (_PT_MOTOR#), and the 4-phase excitation is performed. After the lapse of a predetermined period for performing the output, the stop pulse data “00000000(B)” is stored in the #th reel motor signal data (_PT_MOTOR#).
When the deceleration pulse data “00001111(B)” is stored in the # reel motor signal data (_PT_MOTOR#), the four-phase excitation output of the motor 32 of the # reel 31 is continued, and When the data stored in the motor signal data (_PT_MOTOR#) becomes the stop pulse data “00000000(B)”, the four-phase excitation output of the motor 32 of the # reel 31 is terminated.

As a result, by checking the data stored in the # reel motor signal data (_PT_MOTOR#), it is determined whether or not the predetermined period for performing the 4-phase excitation output to the motor 32 of the # reel 31 has elapsed (4 phase Whether or not the excitation output is being performed) can be easily determined.
In particular, in this embodiment, since only the data of the # reel motor signal data (_PT_MOTOR#) for the reel 31 corresponding to the third (last) operated stop switch 42 is checked, the 4-phase excitation output ends. It is possible to simplify the process for determining whether or not it is possible to reduce the amount of ROM used by the program.

If the stop switch 42 corresponding to the third reel 31 is released after the operation of the stop switch 42 corresponding to the third reel 31 is accepted, “No” is obtained in step S1354 of FIG. 242. Since the process proceeds to step S291, the display determination is executed even in the situation where the 4-phase excitation output for stopping the third reel 31 is being performed. Then, in the display determination, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed on the activated line, and when the symbol combination for which payout (grant) of medals is stopped and displayed on the activated line, the medal Determine the number of payouts (number of grants).

Further, after determining the payout number (the number of grants) of medals in step S291, the process proceeds to step S1355, and the data stored in the # reel motor signal data (_PT_MOTOR#) corresponding to the third reel 31 is checked. By doing so, it is determined whether or not the 4-phase excitation output for stopping the third reel 31 is completed.
Then, when the data stored in the # reel motor signal data (_PT_MOTOR#) corresponding to the third reel 31 becomes the stop pulse data “00000000(B)”, the third reel 31 is stopped. It is determined that the four-phase excitation output for the end has been completed, the result is “No” in step S1355 of FIG. 242, the process proceeds to step S294, and the medal payout process (M_WIN_PAY) at the time of winning can be executed.

As described above, in the present embodiment, when the stop switch 42 corresponding to the third reel 31 is released, the four-phase excitation output for stopping the third reel 31 is being performed. Even if the display determination is executed to determine the payout number (the number of grants) of medals, and then the four-phase excitation output for stopping the third reel 31 is completed, the medal payout process at the time of winning the prize ( M_WIN_PAY).
This makes it possible to determine the payout number (the number of grants) of medals before the completion of the four-phase excitation output for stopping the third reel 31, so that the stop corresponding to the third reel 31 is stopped. It is possible to shorten the time from the release of the switch 42 to the execution of the medal payout process (M_WIN_PAY) at the time of winning.

Under the situation where the two reels 31 are stopped, the operation of the stop switch 42 corresponding to the third reel 31 is accepted, and the symbol combination for paying out (giving) of medals can be stopped and displayed. In the above, it is assumed that the state in which the operation of the stop switch 42 corresponding to the third reel 31 has been accepted continues.

In this case, the result of step S1354 in FIG. 242 is “Yes”, steps S1353 and S1354 are repeated, and the process of step S291 and subsequent steps is not proceeded. Even if the period elapses, the display determination is not executed, therefore the number of payouts is not determined, and the medal payout process (M_WIN_PAY) at the time of winning is not executed.
When the stop switch 42 corresponding to the third reel 31 is released, "No" is obtained in step 1354 of FIG. 242, and the process proceeds to step S291 and thereafter, so the medal payout process (M_WIN_PAY) at the time of winning is executed. It will be possible.

Specifically, for example, the winning number "10" is won by the winning combination lottery means 61, the small winning combination A1 condition device (Fig. 124) is activated, and a small winning combination of 15 payouts 01 or 3 payouts. It is assumed that any one of the small winning roles 13 to 17 is able to win the prize.
Further, the two reels 31 are stopped (the excitation output for stopping the reels 31 is finished), the operation of the stop switch 42 corresponding to the third reel 31 is accepted, and the three reels are paid out. It is assumed that the symbol combination (FIG. 119) corresponding to the small winning combination 13 can be stopped and displayed.

Under such a situation, it is assumed that the operation of any one of the stop switches 42 including the stop switch 42 corresponding to the third reel 31 or the start switch 41 remains accepted.
In this case, the result in step S1354 of FIG. 242 is “Yes”, and steps S1353 and S1354 are repeated, and the process of step S291 and subsequent steps is not performed. Therefore, a predetermined four-phase excitation output for stopping the third reel 31 is performed. Regardless of whether or not the period has passed, the display determination is not executed, and therefore the number of payouts is not determined, and the medal payout process (M_WIN_PAY) at the time of winning is not executed.

When all the stop switches 42 including the stop switch 42 corresponding to the third reel 31 and the start switch 41 are released, the result in step 1354 of FIG. 242 is "No", and the processing proceeds to step S291 and thereafter. When a predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses, "No" is obtained in step S1355 of FIG. 242, and the process proceeds to step S294. Therefore, the medal payout process at the time of winning (M_WIN_PAY) Can be executed.

In this way, in the game in which the symbol combination for paying out (giving) medals is stopped and displayed, if the stop switch 42 corresponding to the third reel 31 is continuously operated, the display determination and the medal at the time of winning the prize are performed. When the payout process (M_WIN_PAY) is not executed and the stop switch 42 corresponding to the third reel 31 is released, the display determination and the medal payout process (M_WIN_PAY) at the time of winning can be executed.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Even if the power switch 11 is unintentionally turned off and the power-off process is executed under the condition that the stop switch 42 corresponding to the third reel 31 is operated, By turning on the power switch 11 while the stop switch 42 corresponding to the eye reel 31 is being operated, the medal payout process (M_WIN_PAY) at the time of winning is not executed and the reel 31 is used. When the stop switch 42 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
Thus, even when the power is cut off at an unintended timing, the player can add the number of credits or pay out medals from the hopper 35 at a desired timing.

Similarly, for example, even if the four-phase excitation output of the motors 32 of all reels 31 including the motor 32 of the reel 31 that stops last (for example, the right reel 31) ends, the reel 31 that stops last (for example, the right reel 31). ), the stop switch 42 corresponding to the reel 31 stopped first (for example, the left reel 31) is operated, and then the stop switch corresponding to the reel 31 stopped first is operated. When the stop switch 42 corresponding to the reel 31 stopped last is released while the switch 42 is being operated, even if the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses, Do not execute the medal payout process (M_WIN_PAY) when winning. Then, when the stop switch 42 corresponding to the reel 31 that stopped first (for example, the left reel 31) is released (at least when all the stop switches are released), it is possible to execute the medal payout process (M_WIN_PAY) at the time of winning. Become.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

The 31st embodiment of the present invention has been described above, but the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the above embodiment, in step S1355, only the data of the # reel motor signal data (_PT_MOTOR#) for the reel 31 corresponding to the third (last) operated stop switch 42 is checked. Not exclusively.
For example, in step S1355, the # reel motor signal data (_PT_MOTOR#) data for all reels 31 may be checked.

Specifically, in step S1355, first, the data stored in the first reel motor signal data (_PT_MOTOR1) is stored in the A register.
Next, the logical sum (OR) operation of the A register value and the data stored in the second reel motor signal data (_PT_MOTOR2) is performed, and the result is stored in the A register value.
Next, the logical sum (OR) operation of the A register value and the data stored in the third reel motor signal data (_PT_MOTOR3) is performed, and the result is stored in the A register value.

Then, it is determined whether or not the A register value is "0", and when the A register value is not "0", it is determined that the motor 32 of one of the reels 31 is in the 4-phase excitation output, and the step The result of S1355 is "Yes", and the process of step S1355 is executed again. In this case, the process does not proceed to step S294.
On the other hand, when the A register value is "0", it is determined that the motor 32 of any reel 31 is not performing the four-phase excitation output, the determination result is "No" in step S1355, and the process proceeds to step S294. Thereby, the medal payout process (M_WIN_PAY) at the time of winning is executed.

Here, as described in the modified example (1) of the thirtieth embodiment, the reel 31 corresponding to the third (last) operated stop switch 42 is stopped second, and the second operated stop is stopped. The reel 31 corresponding to the switch 42 may stop third (last).
In this case, as in the above embodiment, in step S1355, even if only the data of the # reel motor signal data (_PT_MOTOR#) for the reel 31 corresponding to the third (last) operated stop switch 42 is checked. , It is not possible to determine that the four-phase excitation output for all reels 31 has ended.

Therefore, as in this modification (1), in step S1355, by checking the data of the # reel motor signal data (_PT_MOTOR#) for all reels 31, the operation order of the stop switch 42 and the reel 31 Even if the stop order of the reels is changed, it can be determined that the four-phase excitation output for all reels 31 has ended, and after a predetermined period for performing the four-phase excitation output for all reels 31 has elapsed. , It is possible to execute the medal payout process (M_WIN_PAY) at the time of winning.

(2) In the above-described embodiment, when the reel 31 and the motor 32 are stopped, four-phase excitation output is performed to the motor 32 (stepping motor) as the excitation output for stopping the reel 31, but the present invention is not limited to this. Absent.
When the reel 31 and the motor 32 are stopped, the excitation output for stopping the reel 31 may be, for example, one-phase excitation output, two-phase excitation output, or three-phase excitation output. May be. In addition, first, two-phase excitation output is performed to weaken the brake, then the two-phase excitation output is switched to the four-phase excitation output, and the stronger brake is applied to stop the rotation of the reel 31 and the motor 32. It may be allowed to.
(3) The first to thirty-first embodiments and the various modified examples shown in the first to thirty-first embodiments are not limited to being implemented alone, but may be implemented in appropriate combinations.

<Thirty-second embodiment>
In the thirty-second embodiment, even when the operation of the third (last) stop switch 42 is accepted and the operation of the stop switch 42 continues to be accepted, the payout number of tokens (grant Number) can be determined, and after determining the number of payouts of medals, it is determined whether or not any stop switch 42 is operated. If it is determined that neither stop switch 42 is operated, the winning combination The time medal payout process (M_WIN_PAY) is executed.

The symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
FIG. 243 is a diagram showing main data according to the 32nd embodiment among the data stored in the RWM 53 in the 32nd embodiment. The data shown in FIG. 243 is a part of data, and various data other than the illustrated data is stored in the RWM 53.
In FIG. 243, the first reel drive state (_WK_RL1_STS) of the address “F067 (H)” is a storage area that stores data indicating the drive state of the motor 32 of the first (left) reel 31.

Two bits of D0 to D1 indicate the driving state of the motor 32 of the first reel 31. As shown in FIG. 243, “0(D)” indicates that the motor 32 of the first reel 31 is in a constant speed state and the reel sensor 33 of the first reel 31 has detected the index. "1(D)" indicates that the motor 32 of the first reel 31 is in an accelerating or constant speed state and before the reel sensor 33 of the first reel 31 detects the index. “3 (D)” indicates that the motor 32 of the first reel 31 is out of step.

The D2 bit indicates whether or not the standby effect is being executed, "1" indicates that the standby effect is being executed, and "0" indicates that the standby effect is not being executed.
The D3 bit indicates whether or not the deceleration is started, "1" indicates that the deceleration is started, and "0" indicates that the deceleration is not started.

The D5 bit indicates whether or not the step-out preparation is being performed (the state in which the rotation of the reel 31 is abnormal), "1" indicates that the step-out preparation is being performed, and "0" is Indicates that the preparation for step-out is not in progress.
The D6 bit indicates whether or not the reel sensor 33 of the first reel 31 has detected the index, "1" indicates that the index is detected, and "0" indicates that the index is not detected.
The D7 bit indicates whether or not the motor 32 of the first reel 31 is stopped or decelerated, "1" indicates that it is not stopped or decelerated (in acceleration or constant speed state), and "0". "Indicates that the vehicle is stopping or decelerating.

At the start of the standby effect, "1" is set to the D2 bit of the first reel drive state (_WK_RL1_STS).
When the operation of the first stop switch 42 is accepted, the D3 bit of the first reel drive state (_WK_RL1_STS) is set to "1" (the deceleration start state is set).
Furthermore, when the first reel symbol number (for passing position) is updated when the first reel symbol number (for passing position) is less than "0", the D5 bit of the first reel driving state (_WK_RL1_STS) is set to " 1” is set.

Furthermore, the signal of the reel sensor 33 of the first reel 31 is referred to as a first reel sensor signal. The first reel sensor signal is turned on when the reel sensor 33 of the first reel 31 is detecting the index, and is turned off when the reel sensor 33 of the first reel 31 is not detecting the index. Then, when the first reel sensor signal changes from ON to OFF, "1" is set to the D6 bit in the first reel drive state (_WK_RL1_STS).
Further, at the start of rotation of the first reel 31, “81 (H)” (“10000001 (B)”) is set in the first reel drive state (_WK_RL1_STS).

Furthermore, when the motor 32 of the first reel 31 is in the constant speed state and the D6 bit is "1", the first reel drive state (_WK_RL1_STS) becomes "80 (H)"("10000000(B )”) is set.
Furthermore, in the deceleration start state (when the D3 bit is "1"), when the first reel symbol number (for passing position) and the first reel symbol number (for stop position) have the same value, the first "0 (H)"("00000000(B)") is set in the reel drive state (_WK_RL1_STS). That is, at the start of the four-phase excitation output for stopping the motor 32 of the first reel 31, "0 (H)" is set in the first reel drive state (_WK_RL1_STS).
The first reel symbol number (for passing position) and the first reel symbol number (for stop position) have the same value, and the step number of one symbol on the first reel 13 is a predetermined value (for example, " 3”), the first reel drive state may be set to “0 (H)”.

When the D5 bit in the first reel drive state (_WK_RL1_STS) is "1" and the D6 bit is "0", the first reel drive state (_WK_RL1_STS) is "83(H)"(" 10000011(B)”) is set.
Furthermore, when the D6 bit in the first reel driving state (_WK_RL1_STS) is "1", "0" is set in the D5 bit and the D6 bit in the first reel driving state (_WK_RL1_STS).

In FIG. 243, the second reel drive state (_WK_RL2_STS) of the address “F077(H)” is a storage area for storing data indicating the drive state of the motor 32 of the second (middle) reel 31, and the address “F087(H The third reel drive state (_WK_RL3_STS) of "H)" is a storage area for storing data indicating the drive state of the motor 32 of the third (right) reel 31. These contents are the same as the first reel drive state (_WK_RL1_STS) of the address "F067(H)".

In FIG. 243, the input port 2 level data (_PT_IN2_OLD) of the address “F090(H)” is the first stop switch signal (D0 bit) and the second stop switch signal (D1 bit) input to each bit of the input port 2. ), a third stop switch signal (D2 bit), a first reel sensor signal (D4 bit), a second reel sensor signal (D5 bit), and a memory for storing ON/OFF of the third reel sensor signal (D6 bit) Area.

The #stop switch signal is turned on when the #stop switch 42 is operated (the stop button 42a is pushed), and the #stop switch 42 is released (the pushed stop button 42a is released). Return to the position) and turn off.
The #reel sensor signal is turned on when the reel sensor 33 of the #reel 31 detects the index, and is turned off when the index is not detected.
Then, in the interrupt process, the signal input to each bit of the input port 2 is read, and it is determined whether each signal is on or off. If it is on, “1” is stored in the corresponding bit, and it is turned off. At some time, "0" is stored in the corresponding bit.

FIG. 244 is a flowchart showing the main processing (M_MAIN) in the 32nd embodiment, and is a flowchart corresponding to FIG. 139 of the 23rd embodiment.
In the flowchart of the thirty-second embodiment shown in FIG. 244, steps different from those in FIG. 139 are underlined in step numbers, and steps identical to those in FIG. 139 are identical in step number.

Also, in the main process (M_MAIN) of the thirty-second embodiment, the processes of steps S295 to S300 of FIG. 139 are executed, but the processes of steps S295 to S300 are omitted in FIG. 244.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 244, in the thirty-second embodiment, when the start switch acceptance process (M_START_CTL) of step S751 is executed, the process proceeds to step S1361.
In step S1361, the main control board 50 executes a reel stop acceptance check. This process is a process shown in FIG. 245 described later. When the reel stop acceptance check in step S1361 ends, the process proceeds to step S291.

When the processing proceeds to step S291, the main control board 50 executes display determination.
Specifically, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed on the activated line. Further, when the symbol combination for paying out (giving) of medals is stopped and displayed on the activated line, the payout number of tokens (number of grants) is determined. Then, the process proceeds to step S292.
The determined payout number of medals may be stored (saved) only in a predetermined register and not stored in the RWM 53, or may be stored in the RWM 53.

If “No” in the step S292 and the process of the step S293 is executed, the process proceeds to a step S1362.
In step S1362, the main control board 50 determines whether or not any of the stop switch signals is on (operation of any of the stop switches 42 is accepted).

Specifically, in step S1362, the main control board 50 first stores the data stored in the input port 2 level data (_PT_IN2_OLD) (FIG. 243) of the address “F090(H)” of the RWM 53 in the A register. To do.
Next, the main control board 50 performs a logical product (AND) operation of the A register value and "00000111(B)" and determines whether the result is "0" (zero flag is "1"). To judge. Thereby, it is determined whether or not any of the stop switch signals is ON, that is, whether or not the operation of any of the stop switches 42 is accepted.

When the result of the logical product operation is not "0" (the zero flag is not "1"), one of the stop switch signals is on (operation of any of the stop switches 42 is accepted). Then, the result of step S1362 is “Yes”, and the process of step S1362 is executed again. That is, the process of step S1362 is repeated.
On the other hand, when the result of the logical product operation is "0" (the zero flag is "1"), both stop switch signals are off (operation of any stop switch 42 is accepted. No), the determination result is “No” in step S1362, and the process proceeds to step S294.

Here, when at least one operation of the left stop switch 42, the middle stop switch 42, and the right stop switch 42 is accepted, at least one stop switch signal is turned on, and the input port 2 level data ( At least one of the D0 to D2 bits of _PT_IN2_OLD) becomes "1".
Further, when at least one of the D0 to D2 bits of the input port 2 level data (_PT_IN2_OLD) is "1", the result of the above logical product operation does not become "0" (the zero flag does not become "1").
When the result of the logical product operation is not "0" (zero flag is not "1"), "Yes" is obtained in step S1362 and the process of step S1362 is repeated. In this case, since the process does not proceed to step S294, the medal payout process (M_WIN_PAY) at the time of winning is not executed.

On the other hand, when the left stop switch 42, the middle stop switch 42, and the right stop switch 42 are all released, the left stop switch signal, the middle stop switch signal, and the right stop switch signal are all turned off. , D0 to D2 bits of the input port 2 level data (_PT_IN2_OLD) are all "0".
When the D0 to D2 bits of the input port 2 level data (_PT_IN2_OLD) are all "0", the result of the logical product operation is "0" (the zero flag is "1").
When the result of the logical product operation is "0" (the zero flag is "1"), "No" is obtained in step S1362, and the process proceeds to step S294.

In step S294, the main control board 50 executes a medal payout process (M_WIN_PAY) at the time of winning. That is, when the number of credits has not reached the upper limit value “50”, the number of credits is added, and when the number of credits has reached the upper limit value “50”, the hopper motor 36 is driven to make the actual value. The medals are paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

FIG. 245 is a flowchart showing the reel stop acceptance check in step S1361 of FIG. 244.
In step S1371, the main control board 50 executes a reel drive state inspection.
First, the data stored in the first reel drive state (_WK_RL1_STS) (FIG. 243) of the address “F067 (H)” of the RWM 53 is stored in the A register.
Next, the A register value and the data stored in the second reel drive state (_WK_RL2_STS) (FIG. 243) of the address “F077(H)” of the RWM 53 are ORed (OR), and the result is obtained. Store in A register.

Next, the A register value and the data stored in the third reel drive state (_WK_RL3_STS) (FIG. 243) of the address “F087(H)” of the RWM 53 are ORed (OR), and the result is obtained. Store in A register.
Finally, the logical product (AND) operation of the A register value and "83(H)"("10000011(B)") is performed.
Then, the process proceeds to next Step S1372.

When proceeding to step S1372, the main control board 50 determines whether or not all reels 31 are stopped or decelerated.
Specifically, whether or not the result of the logical product operation of the A register value and “83(H)” (“10000011(B)”) in step S1371 is “0” (zero flag is “1”). To judge.

When the result of the logical product operation is "0" (the zero flag is "1"), it is determined that all reels 31 are stopped or decelerating, and "Yes" is obtained in step S1372, The process according to this flowchart ends.
On the other hand, when the result of the logical product operation is not "0" (the zero flag is not "1"), the motor 32 of one of the reels 31 is not stopped or decelerated (acceleration or constant speed state). ), it becomes "No" in step S1372, and the process proceeds to the next step S1373.

Here, it is assumed that the motors 32 of the two reels 31 have already stopped (already stopped). The operation of the stop switch 42 corresponding to the third (last) reel 31 is accepted, but the 4-phase excitation output for stopping the motor 32 of the reel 31 is not yet output (4-phase excitation). Before output). That is, it is assumed that the motor 32 of the third (last) reel 31 is still in the constant speed state.
In this case, the # reel drive state (_WK_RL#_STS) (FIG. 243) of the two reels 31 that have already stopped is “00000000(B)”, but the reel number of the third (last) reel 31 is Since the #th reel drive state (_WK_RL#_STS) (FIG. 243) is “10001000(B)”, the #reel drive state (_WK_RL#_STS) (FIG. 243) of all reels 31 is ORed (OR). ) The calculated result is “10001000(B)”.

Therefore, the result of the logical product (AND) operation of "10001000(B)" and "83(H)"("10000011(B)" is "10000000(B)", which is not "0" (the zero flag is Since it does not become "1"), "No" is obtained in the step S1372, and the process proceeds to the next step S1373.
Therefore, since the process does not proceed to step S291 of FIG. 244, the display determination is not executed and the payout number (the number of grants) of medals is not determined.

Further, it is assumed that the motors 32 of the two reels 31 have already stopped (stopped, four-phase excitation output for stopping the reel 31 has ended). Then, the operation of the stop switch 42 corresponding to the third (last) reel 31 is accepted, and the 4-phase excitation output for stopping the motor 32 of the reel 31 has already been performed (after the 4-phase excitation output). Yes). That is, it is assumed that the motor 32 of the third (last) reel 31 has also stopped.
In this case, since the # reel driving state (_WK_RL#_STS) (FIG. 243) of the three reels 31 is “00000000(B)”, the # reel driving state of the three reels 31 (_WK_RL #_STS) (FIG. 243) is logically ORed, and the result is “00000000(B)”.

Therefore, the result of the logical product (AND) operation of “00000000(B)” and “83(H)” (“10000011(B)” becomes “00000000(B)” and becomes “0” (the zero flag is Since it becomes "1"), the result in step S1372 becomes "Yes", and the processing according to this flowchart ends.
Therefore, the process proceeds to step S291 in FIG. 244, so that the display determination can be executed and the payout number (the number of grants) of medals can be determined.

Further, when proceeding to step S1373 of FIG. 245, the main control board 50 determines whether or not the motors 32 of all the reels 31 are in the constant speed state and the reel sensor 33 has detected the index.
Specifically, the main control board 50 performs a logical product (AND) operation of the A register value and “03(H)” (“00000011(B)”), and the result is “0” ( It is determined whether the zero flag is "1"). Thus, for all reels 31, it is determined whether or not the motor 32 is in the constant speed state and the reel sensor 33 is after the index detection.

When the result of the logical product operation is not “0” (the zero flag is not “1”), it is determined that the motor 32 is at a constant speed and the reel sensor 33 has not detected the index for at least one reel 31. , No in step S1373, the process proceeds to the next step S1374.
On the other hand, when the result of the logical product operation is “0” (the zero flag is “1”), the motors 32 of all the reels 31 are in the constant speed state and the reel sensors 33 detect the indexes. If it is determined that the result is “Yes” in step S1373, step S1374 is skipped and the process proceeds to step S1375.

Here, for all reels 31, when the motor 32 is in a constant speed state and after the reel sensor 33 detects the index, the # reel drive state (_WK_RL#_STS) (FIG. 243) is Is also “80 (H)” (“10000000 (B)”).
In this case, the result of the logical sum (OR) operation of the # reel driving state (_WK_RL#_STS) (FIG. 243) of the three reels 31 is “10000000(B)”.
Therefore, the A register value is “10000000 (B)” at the time of proceeding to step S1373.

Therefore, in step S1373, when the logical product (AND) operation of the A register value and “03(H)” (“00000011(B)”) is performed, the result becomes “0” (the zero flag is “1”). Since the result is "Yes" in step S1373, step S1374 is skipped and the process proceeds to step S1375.
Therefore, the processing of step S1375 (processing at the time of stop acceptance) can be executed, so that the stop control of the reel 31 based on the operation of the stop switch 42 can be executed.

It is also assumed that the motors 32 of all three reels 31 are in a constant speed state, but the reel sensor 33 has not yet detected the index of at least one reel 31 (before the detection).
In this case, since the # reel driving state (_WK_RL#_STS) (FIG. 243) of the reel 31 before the index detection is “81 (H)” (“10000001 (B)”), the three reels 31 The result of the logical sum (OR) operation of the #th reel drive state (_WK_RL#_STS) (FIG. 243) is “10000001 (B)”.
Therefore, the A register value is “10000001 (B)” at the time of proceeding to step S1373.

Therefore, in step S1373, when the logical product (AND) operation of the A register value and "03(H)"("00000011(B)") is performed, the result is "00000001(B)" and "0". "(0) does not occur (the zero flag does not become "1"), the result is "No" in step S1373, and the flow proceeds to step S1374.
Therefore, the processing of step S1374 (step-out inspection preparation) is performed, and the processing of step S1375 (processing at the time of stop acceptance) is not executed, so the stop control of the reel 31 based on the operation of the stop switch 42 is not executed.

When the reel 31 is in the constant speed state, the # reel driving state (_WK_RL#_STS) is “10000000 (B)”, and when the reel 31 is stopped, the # reel driving state ( _WK_RL#_STS) is “00000000(B)”.
Therefore, one reel 31 has already stopped (the four-phase excitation output for stopping the reel 31 has ended) and the remaining two reels 31 are in a constant speed state, or two reels Even when 31 is already stopped (four-phase excitation output for stopping reel 31 is finished) and the remaining one reel 31 is in the constant speed state, the # reel drive state of three reels 31 When the logical sum (OR) operation of (_WK_RL#_STS) is performed and the logical product (AND) operation of the result and "00000011 (B)" is performed, the same result "00000000 (B)" is obtained.
As a result, even if there is a reel 31 that has already stopped, it is possible to determine whether or not stop acceptance is possible by the same process, so that the process can be simplified and the amount of ROM used by the program can be reduced. Can be reduced.

When proceeding to step S1374, the main control board 50 executes a step-out inspection preparation. This process is a process shown in FIG. 246 described later. When the preparation for the step-out inspection in step S1374 is completed, the process proceeds to step S1375.
When the processing proceeds to step S1375, the main control board 50 executes the processing at the time of stop acceptance. In this processing, the stop position of the #reel 31 is determined based on the result of the lottery result of the game this time and the position of the #reel 31 at the moment when the operation of the #stop switch 42 is accepted, and the determined stop is determined. The symbol number corresponding to the position is stored in the # reel symbol number (for stop position). Further, the stop symbol data for determining the symbol combination to be stopped on the activated line is updated. Then, the processing according to this flowchart is ended.

More specifically, in the process at the time of stop acceptance in step S1375 of FIG. 245, processes corresponding to step S1016, step S1017, step 1022, step S1023, and step S1024 in FIG. 194 of the 25th embodiment are executed.
That is, the input port rising data A (_PT_IN_A_UP) of the address “F017(H)” in FIG. 133 is acquired by the process corresponding to step S1016 in FIG. 194.
Next, by a process corresponding to step S1017 in FIG. 194, it is determined whether or not the stop switch 42 has risen (whether or not the rise data of the stop switch 42 is ON).
When it is determined that the stop switch 42 has risen (corresponding to “Yes” in step S1017 of FIG. 194), the reel 31 corresponding to the stop switch 42 that is determined to have risen corresponds to steps S1022 to S1023 of FIG. 194. By the processing, the stop position of the reel 31 is determined based on the result of the game lottery this time and the position of the reel 31 at the moment when the operation of the stop switch 42 is accepted, and the symbol number corresponding to the determined stop position is assigned. , Reel symbol number (for stop position) is stored.
Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated.
Then, the processing according to this flowchart is ended.

By the interrupt process executed after the process of step S1375 (the process corresponding to steps S1016 to S1024 in FIG. 194 of the twenty-fifth embodiment), the # reel symbol number (for passing position) and the # reel symbol number ( When it is determined that the values of (for the stop position) have the same value, the four-phase excitation output for stopping the motor 32 of the # reel 31 is started.
Further, the # reel symbol number (for passing position) and the # reel symbol number (for stop position) have the same value, and the step number of one symbol of the # reel 13 is a predetermined value (for example, “ 3”), the four-phase excitation output for stopping the motor 32 of the # reel 31 may be started.

FIG. 246 is a flowchart showing step-out inspection preparation in step S1374 of FIG. 245 and step S1404 of FIG. 248 described later.
In step S1381, the main control board 50 sets the address “F067 (H)” of the RWM 53 in the first reel drive state (_WK_RL1_STS) (FIG. 243). Then, the process proceeds to next Step S1382.

In step S1382, the main control board 50 refers to the address set in step S1381, and executes the step-out inspection for the first (left) reel 31. This process is a process shown in FIG. 247 described later. When the out-of-step inspection in step S1382 is completed, the process proceeds to step S1383.
In step S1383, the main control substrate 50 sets the address “F077(H)” of the RWM 53 in the second reel drive state (_WK_RL2_STS) (FIG. 243). Then, the process proceeds to next Step S1384.

In step S1384, the main control board 50 refers to the address set in step S1383, and executes the step-out inspection for the second (middle) reel 31. This process is a process shown in FIG. 247 described later and has the same contents as step S1382. Then, when the out-of-step inspection in step S1384 ends, the process proceeds to step S1385.
In step S1385, the main control substrate 50 sets the address “F087 (H)” of the RWM 53 in the third reel drive state (_WK_RL3_STS) (FIG. 243). Then, the process proceeds to next Step S1386.

In step S1386, the main control board 50 refers to the address set in step S1385, and executes the step-out inspection for the third (right) reel 31. This process is a process shown in FIG. 247, which will be described later, and has the same contents as steps S1382 and S1384. Then, when the out-of-step inspection in step S1386 is completed, the process proceeds to step S1387.
When the processing proceeds to step S1387, the main control board 50 waits for acceptance of stop acceptance. This process is a process shown in FIG. 248 described later. Then, when the waiting for acceptance of stop acceptance in step S1387 ends, the process according to this flowchart ends.

FIG. 247 is a flowchart showing the out-of-step inspection in step S1382, step S1384 and step S1386 of FIG. 246.
In step S1391, the main control board 50 determines whether or not it is in the step-out state. When it is determined that the step is out of step, the process proceeds to the next step S1392. When it is determined that the step is not out of step, step S1392 is skipped and the process according to the present flowchart is ended.

When the processing proceeds to step S1392, the main control board 50 sets the parameters for re-acceleration with respect to the reel 31 determined to be out of step. As a result, the motor 32 of the reel 31 which is determined to be in the step-out state is again subjected to the excitation output for acceleration. Then, the processing according to this flowchart is ended.

FIG. 248 is a flowchart showing waiting for acceptance of stop acceptance in step S1387 of FIG. 246.
In step S1401, the main control board 50 executes a reel drive state inspection. This process is similar to step S1371 in FIG. 245.
That is, the data stored in the first reel drive state (_WK_RL1_STS) (FIG. 243) of the address “F067 (H)” of the RWM 53 is stored in the A register.
Next, the A register value and the data stored in the second reel drive state (_WK_RL2_STS) (FIG. 243) of the address “F077(H)” of the RWM 53 are ORed (OR), and the result is obtained. Store in A register.

Next, the A register value and the data stored in the third reel drive state (_WK_RL3_STS) (FIG. 243) of the address “F087(H)” of the RWM 53 are ORed (OR), and the result is obtained. Store in A register.
Finally, the logical product (AND) operation of the A register value and "83(H)"("10000011(B)") is performed.
Then, the process proceeds to the next step S1402.

In step S1402, the main control board 50 determines, for all reels 31, whether or not the motor 32 is in the constant speed state and the reel sensor 33 has detected the index. This process is similar to step S1373 in FIG. 245.
That is, the logical product (AND) operation of the A register value and "03 (H)"("00000011(B)") is performed, and the result is "0" (zero flag is "1"). Determine whether or not. Thus, for all reels 31, it is determined whether or not the motor 32 is in the constant speed state and the reel sensor 33 is after the index detection.

When the result of the logical product operation is not "0" (the zero flag is not "1"), it is determined that the motor 32 is at a constant speed and the reel sensor 33 has not detected the index for at least one reel 31, If “No” in the step S1402, the process advances to the next step S1403.
On the other hand, when the result of the logical product operation is “0” (the zero flag is “1”), the motors 32 of all reels 31 are in the constant speed state and the reel sensors 33 detect the indexes. If it is determined that the result is “Yes” in step S1402, steps S1403 and S1404 are skipped, and the process according to this flowchart ends.

When the processing proceeds to step S1403, the main control board 50 determines whether or not the step out condition is present. If it is determined that the step is out of step, the process proceeds to the next step S1404, and if it is determined that the step is not out, the process returns to step S1401.
In step S1404, the main control board 50 executes a step-out inspection preparation. This process is the process shown in FIG. 246 described above. When the step-out inspection preparation in step S1404 is completed, the process according to this flowchart is completed.

As described above, in the present embodiment, the two reels 31 stop (the four-phase excitation output for stopping the reels 31 ends), and the stop switch 42 corresponding to the third (last) reel 31 operates. When the operation is accepted and the four-phase excitation output for stopping the motor 32 of the reel 31 is performed, the # reel drive state (_WK_RL#_STS) (FIG. 243) of the three reels 31 Also becomes “00000000(B)”, and the result of the logical sum (OR) operation of these is “00000000(B)”.
Then, the result of the logical product (AND) operation of "00000000(B)" and "83(H)"("10000011(B)" is "00000000(B)", and thus in step S1372 of FIG. 245. Since the result is “Yes” and the process proceeds to the display determination of step S291 of FIG. 244, the payout number (number of grants) of medals can be determined.

In addition, in the present embodiment, even if the period for performing the 4-phase excitation output for stopping the motor 32 of the third reel 31 has not elapsed (even during the 4-phase excitation output), the 4-phase excitation is performed. At the time when the output is started, the # reel drive state (_WK_RL#_STS) of the third reel 31 becomes “00000000(B)”, and thus “Yes” in step S1372 of FIG. Since the process proceeds to the display determination in step S291, the number of medals paid out (number of awards) can be determined.

Furthermore, in the present embodiment, even if the operation of the stop switch 42 corresponding to the third reel 31 is accepted (even if the stop switch 42 is not released and is still pressed), When the 4-phase excitation output is started, the # reel drive state (_WK_RL#_STS) of the third reel 31 becomes “00000000(B)”, and thus “Yes” in step S1372 of FIG. 245. The display determination of step S291 of 244 is proceeded to, and it becomes possible to determine the payout number (awarding number) of medals.
Accordingly, it is possible to shorten the time from when the operation of the stop switch 42 corresponding to the third reel 31 is accepted until the number of medals payout (the number of grants) is determined, and the subsequent medal payout ( Can be executed smoothly.

For example, in the game in which the winning number “10” is won by the winning combination lottery means 61 during AT, and the small winning combination A1 condition device (FIG. 124) is operated, the two reels 31 are stopped in the order of the left reel 31 and the middle reel 31. However, the operation of the right stop switch 42 corresponding to the third (last) right reel 31 is accepted, and the symbol combination (FIG. 118) corresponding to the small win 01, which is the payout of 15 sheets, can be stopped and displayed. Suppose
Under such a circumstance, if the four-phase excitation output for stopping the motor 32 of the third reel 31 is started, even if the period for performing the four-phase excitation output does not elapse, three Even when the operation of the stop switch 42 corresponding to the reel 31 of the eye continues to be accepted, the payout number of medals can be determined.

Also, the payout number of medals is determined in step S291 of FIG. 244, and then the process proceeds to step S1362, which is stored in the input port 2 level data (_PT_IN2_OLD) of the address “F090(H)” of the RWM 53 (FIG. 243). Based on the data, it is determined whether or not the operation of any of the stop switches 42 has been accepted.

When it is determined in step S1362 that the operation of any of the stop switches 42 (all the stop switches 42 including the last operated stop switch 42) is not accepted, the process proceeds to step S294, and the medal at the time of winning the prize. The payout process (M_WIN_PAY) is executed. As a result, the medals of the payout number (number of grants) determined in step S291 are paid out (granted). At this time, if the credit number has not reached the upper limit value “50”, the credit number is added, and if the credit number has reached the upper limit value “50”, the hopper motor 36 is driven to generate the actual medal. Is paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Even if the power switch 11 is unintentionally turned off and the power-off process is executed under the condition that the stop switch 42 corresponding to the third reel 31 is operated, By turning on the power switch 11 while the stop switch 42 corresponding to the eye reel 31 is being operated, the medal payout process (M_WIN_PAY) at the time of winning is not executed and the reel 31 is used. When the stop switch 42 is released, the medal payout process (M_WIN_PAY) at the time of winning can be executed.
Thus, even when the power is cut off at an unintended timing, the player can add the number of credits or pay out medals from the hopper 35 at a desired timing.

Similarly, for example, even if the four-phase excitation output of the motors 32 of all reels 31 including the motor 32 of the reel 31 that stops last (for example, the right reel 31) ends, the reel 31 that stops last (for example, the right reel 31). ), the stop switch 42 corresponding to the reel 31 stopped first (for example, the left reel 31) is operated, and then the stop switch corresponding to the reel 31 stopped first is operated. When the stop switch 42 corresponding to the reel 31 stopped last is released while the switch 42 is being operated, even if the predetermined period for performing the four-phase excitation output for stopping the third reel 31 elapses, Do not execute the medal payout process (M_WIN_PAY) when winning. Then, when the stop switch 42 corresponding to the reel 31 that stopped first (for example, the left reel 31) is released (at least when all the stop switches are released), it is possible to execute the medal payout process (M_WIN_PAY) at the time of winning. Become.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

Further, in this embodiment, each reel 31 is provided with a # reel driving state (_WK_RL#_STS) (FIG. 243) capable of storing data indicating the driving state of the motor 32 of the # reel 31.
Then, in step S1373 of FIG. 245, the main control board 50 calculates the logical sum (OR) of the # reel driving states (_WK_RL#_STS) of the three reels 31 and "03 (H)"(" 00000011(B)”) and performs a logical product (AND) operation to determine whether the result is “0” (the zero flag is “1”).
Thus, for all reels 31, it is determined whether or not the motor 32 is in the constant speed state and the reel sensor 33 is after the index detection.

Then, for all reels 31, when the motor 32 is in the constant speed state and the reel sensor 33 is after the index detection, the result of the above logical product calculation is "0" (zero flag is "1"). In this case, "Yes" is obtained in the step S1373, the process proceeds to a step S1375, and the process at the time of stop acceptance can be executed, so that the stop control of the reel 31 based on the operation of the stop switch 42 can be executed.

That is, in the case where all the reels 31 are rotating at a constant speed, when the indexes of all the reels 31 have been detected, the # reel driving state (_WK_RL#_STS) of the three reels 31 is ORed ( When an OR operation is performed and the result is ANDed with "03(H)"("00000011(B)"), the result becomes "0" (the zero flag becomes "1"). At this time, when the stop switch 42 is operated, the stop control of the reel 31 corresponding to the stop switch 42 can be executed.
In other words, in the case where all the reels 31 are rotating at a constant speed, when the indexes of all the reels 31 have been detected, the result in step S1373 is “Yes”, the flow proceeds to step S1375, and the process of FIG. The processing corresponding to step S1016, step S1017, step 1022, and step S1023 in 194 is executed.

On the other hand, when the reel sensor 33 has not yet detected the index (before the detection) for any of the reels 31, the result of the above-mentioned logical product operation is "0" (the zero flag is "1"). It doesn't happen. In this case, “No” is obtained in step S1373, the flow proceeds to step S1374, and the out-of-step inspection preparation is performed. Since the process does not proceed to step S1375, the stop acceptance process is not executed and the reel 31 stop control based on the operation of the stop switch 42 is not executed.

That is, even if all the reels 31 are rotating at a constant speed, if the index is not detected for any of the reels 31, the # reel drive state (_WK_RL#_STS) of the three reels 31 is determined. ) Is subjected to a logical sum (OR) operation, and the result thereof is subjected to a logical product (AND) operation with "03(H)"("00000011(B)"), the result does not become "0" (the zero flag is "1"). "do not become). At this time, even if the stop switch 42 is operated, stop control of the reel 31 corresponding to the stop switch 42 is not executed.
In other words, even if all the reels 31 are rotating at a constant speed, if the index is not yet detected for any of the reels 31, the result in step S1373 is "No", and in this case, the 25th embodiment. The processing corresponding to step S1016, step S1017, step 1022, and step S1023 in FIG.

In this way, for all reels 31, it is possible to determine whether or not the motor 32 is in the constant speed state and the reel sensor 33 is after the index detection, that is, whether or not the stop acceptance is possible, by a simple calculation. The processing can be simplified and the amount of ROM used by the program can be reduced.

The 32nd embodiment of the present invention has been described above, but the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) For example, in step S1373 of FIG. 245, first, the input port rising data A (_PT_IN_A_UP) of the address “F017(H)” of FIG. 133 is acquired, and whether or not the stop switch 42 is rising (stop) If it is determined that the rising data of the switch 42 is ON, and if it is determined that the stop switch 42 is rising, then the A register value and "03 (H)"("00000011(B)") By performing a logical product (AND) operation of each of the reels 31 and determining whether or not the result is “0” (zero flag is “1”), the motors 32 of all the reels 31 are in the constant speed state and the reel sensors 33 are all in the same state. May be determined after the index detection.

That is, it is first determined whether or not the stop switch 42 has been operated, and thereafter, for all reels 31, it is also determined whether or not the motors 32 are in the constant speed state and the reel sensors 33 are after the index detection. Good.
If the result of the logical product operation is not "0" (the zero flag is "1"), the result of the step S1373 is "No", the process proceeds to step S1374, and the result of the logical product operation is "0" (the zero flag). Is "1"), it becomes "Yes" in step S1373, skips step S1374, and proceeds to step S1375.

Also, as in this modification (1), in step S1373 of FIG. 245, it is first determined whether or not the stop switch 42 has been operated, and then, for all reels 31, the motors 32 are in the constant speed state. When it is determined whether or not the reel sensor 33 has detected the index, in the processing at the time of stop acceptance in step S1375 of FIG. 245, the processing corresponding to step 1022 and step S1023 in FIG. 194 of the twenty-fifth embodiment is executed. To do. That is, based on the result of the lottery result of the game this time and the position of the reel 31 at the moment when the operation of the stop switch 42 is accepted, the stop position of the reel 31 is determined, and the symbol number according to the determined stop position, Store in reel symbol number (for stop position).

(2) In the above embodiment, when it is determined in step S1362 of FIG. 244 whether the operation of any of the stop switches 42 has been accepted, and it is determined that the operation of any of the stop switches 42 has not been accepted. 24, the process proceeds to the medal payout process (M_WIN_PAY) at the time of winning in step S294 of FIG. 244, but it is not limited to this.

For example, the start switch signal is input to the input port 2, and the ON/OFF of the start switch signal is stored in any bit of the input port 2 level data (_PT_IN2_OLD) (Fig. 243) of the address "F090(H)" of the RWM 53. It is possible.
Further, in step S1362 of FIG. 244, based on the data stored in the input port 2 level data (_PT_IN2_OLD), it is determined whether or not the operation of the start switch 41 or the three stop switches 42 is accepted. to decide.

When it is determined that the operation of any switch has been accepted, the processing of step S1362 is repeated, and when it is determined that the operation of any switch has not been accepted, at the time of winning in step S294 of FIG. 244. The medal payout process (M_WIN_PAY) may be performed.
Thereby, it is possible to prevent the medal payout process (M_WIN_PAY) at the time of winning from being executed even when the operation of the start switch 41 is accepted in addition to the operation of the stop switch 42.
Then, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

(3) In step S1362 of FIG. 244, it is determined whether or not the operation of the stop switch 42 (the last operated stop switch 42) corresponding to the third reel 31 is accepted, and the stop switch 42 ( If it is determined that the last operated stop switch 42) has not been accepted, the process may proceed to the medal payout process (M_WIN_PAY) at the time of winning in step S294 of FIG. 244.

For example, in the game in which the winning number “10” is won by the winning combination lottery means 61 during AT, and the small winning combination A1 condition device (FIG. 124) is operated, the two reels 31 are stopped in the order of the left reel 31 and the middle reel 31. However, the operation of the right stop switch 42 corresponding to the third (last) right reel 31 is accepted, and the symbol combination (FIG. 118) corresponding to the small win 01, which is the payout of 15 sheets, can be stopped and displayed. Suppose
Under such a circumstance, if the four-phase excitation output for stopping the motor 32 of the third reel 31 is started, even if the period for performing the four-phase excitation output has not elapsed, three Even when the operation of the stop switch 42 (the last operated stop switch 42) corresponding to the reel 31 of the eye continues to be accepted, the payout number of medals can be determined.

Further, in step S291 of FIG. 244, the payout number of medals is determined, and then the process proceeds to step S1362, and the operation of the stop switch 42 (the last operated stop switch 42) corresponding to the third reel 31 is accepted. Determine whether or not
When it is determined in step S1362 that the operation of the stop switch 42 (the last operated stop switch 42) corresponding to the third reel 31 is not accepted, the process proceeds to step S294, and the medal at the time of winning the prize. The payout process (M_WIN_PAY) is executed. As a result, the medals of the payout number (number of grants) determined in step S291 are paid out (granted).

At this time, if the credit number has not reached the upper limit value “50”, the credit number is added, and if the credit number has reached the upper limit value “50”, the hopper motor 36 is driven to generate the actual medal. Is paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

(4) In the above embodiment, when the reel 31 and the motor 32 are stopped, the four-phase excitation output is performed to the motor 32 (stepping motor) as the excitation output for stopping the reel 31. However, the present invention is not limited to this. Absent.
When the reel 31 and the motor 32 are stopped, the excitation output for stopping the reel 31 may be, for example, one-phase excitation output, two-phase excitation output, or three-phase excitation output. May be. In addition, first, two-phase excitation output is performed to weaken the brake, then the two-phase excitation output is switched to the four-phase excitation output, and the stronger brake is applied to stop the rotation of the reel 31 and the motor 32. It may be allowed to.

(5) In the above-described embodiment, the # reel drive state (_WK_RL#_STS) is set to “0 (H)” at the start of the four-phase excitation output for stopping the motor 32 of the reel 31. Not limited to this, for example, “0 (H)” may be set in the # reel driving state (_WK_RL#_STS) at the end of the four-phase excitation output for stopping the motor 32 of the reel 31.
(6) The first to thirty-second embodiments and the various modifications shown in the first to thirty-second embodiments are not limited to be performed alone, but may be appropriately combined and performed.

<33rd Embodiment>
In the 33rd embodiment, the two reels 31 are stopped (the excitation output for stopping the reels 31 is finished), the operation of the stop switch 42 corresponding to the third reel 31 is accepted, and the medal Even when the state in which the operation of the stop switch 42 corresponding to the third reel 31 is accepted when the symbol combination for paying out (giving) is stopped and displayed is three, After the 4-phase excitation output for stopping the reel 31 of the eye is finished, the medal payout process (M_WIN_PAY) at the time of winning is executed. Then, after the stop switch 42 corresponding to the third reel 31 is released, there is a case where an effect regarding the game result is output.

Further, in the 33rd embodiment, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, and the activated line are different from those in the 23rd embodiment.
Specifically, in the 33rd embodiment, the winning combination is roughly classified into a special winning combination (feature), a replay (replaying winning combination), and a small winning combination. In addition, it has 1BB (first type accessory continuous operation device; first type big bonus) as a special role, and has a bell, watermelon, and cherry as a small role.

The symbol combination corresponding to 1BB is set to "red 7"-"red 7"-"red 7", and the symbol combination corresponding to replay is set to "replay"-"replay"-"replay". , The symbol combination corresponding to bell is set to "bell"-"bell"-"bell", and the symbol combination corresponding to watermelon is set to "watermelon"-"watermelon"-"watermelon", corresponding to cherry The symbol combination to be set is set to “cherry”-“ANY”-“ANY”.
In addition, "ANY" means that any symbol may be used (arbitrary symbol).

The effective lines include five lines: an upper line, a middle line, a lower line, an upward right line, and a downward right line.
When the symbol combination corresponding to 1BB is stopped and displayed on the activated line, the medal is not paid out in the game this time, but the 1BB game is started from the next game.
Also, if 1BB is won, but the symbol combination corresponding to 1BB is not stopped and displayed on the activated line, the winning information of 1BB is carried over to the next game until the symbol combination corresponding to 1BB is stopped and displayed on the activated line. A game state in which the winning information of 1BB is carried over is referred to as "inside 1BB".

Furthermore, when the symbol combination corresponding to the replay is stopped and displayed on the activated line, the medals are automatically inserted and the replay can be executed.
Further, the payout number of bells is set to 15, the payout number of watermelons is set to 7, and the payout number of cherries is set to 1.
In addition, both Replay and Bell win independently, and do not win multiple wins with other roles.
Furthermore, the watermelon has a single win and a double win with 1BB, and the cherry has a single win and a double win with 1BB.
Further, 1BB has a case of single win and a case of double win with watermelon or cherry.

In addition, in the 33rd embodiment, any one of the winning numbers “0” to “7” is determined by the lottery by the combination lottery means 61. When the winning number is determined, the condition device corresponding to the determined winning number operates.
The winning number "0" corresponds to non-winning, the winning number "1" corresponds to individual replay winning, the winning number "2" corresponds to Bell's single winning, and the winning number "3" corresponds to Corresponding to the individual winning of watermelon, the winning number "4" corresponds to the single winning of cherry.
The winning number "5" corresponds to a single winning of 1BB, the winning number "6" corresponds to a double winning of "1BB + watermelon", and the winning number "7" corresponds to a double winning of "1BB + cherry". Correspond.

For example, when the winning number “1” is determined by the lottery by the winning combination lottery means 61, the replay condition device corresponding to the winning number “1” is activated, and the symbol combination corresponding to the replay can be stopped and displayed.
Further, when the winning number “7” is determined by the lottery by the combination lottery means 61, the “1BB+cherry” condition device corresponding to the winning number “7” is activated to correspond to the symbol combination corresponding to 1BB or cherry. The symbol combination can be stopped and displayed.
In the game in which the winning number "7" is determined by the lottery by the combination lottery means 61, the symbol combination corresponding to cherry can be stopped and displayed, but the symbol combination corresponding to 1BB is not stopped and displayed. Good.

FIG. 249 is a diagram showing main data according to the 33rd embodiment among the data stored in the RWM 53 in the 33rd embodiment.
In FIG. 249, the reel stop flag (_FL_STOP_LP) of the address “F0AD(H)” is a storage area that stores data indicating whether or not the operation (stop operation) of the stop switch 42 corresponding to each reel 31 is accepted. is there.

The D0 bit indicates whether or not the stop operation of the first (left) reel 31 has been accepted, "0" indicates that the stop operation has not been accepted, and "1" indicates that the stop operation has been accepted. Indicates that (accepted).
Further, the D1 bit indicates whether or not the stop operation of the second (middle) reel 31 has been accepted, and the D2 bit indicates whether or not the stop operation of the third (right) reel 31 has been accepted. These contents are similar to the D0 bit.

The reel stop flag (_FL_STOP_LP) at the address “F0AD(H)” in FIG. 249 is the same as the reel stop flag (_FL_STOP_LP) at the address “F0AD(H)” in FIG. And are reversed. That is, in FIG. 173, “1” indicates that the stop operation has not been accepted, and “0” indicates that the stop operation has been accepted (accepted), but in FIG. 249, “1” indicates that the stop operation has been accepted. , Indicates that the stop operation has been received (accepted), and “0” indicates that the stop operation has not been received.

When the operation of the left stop switch 42 is accepted, "1" is set to the D0 bit of the reel stop flag (_FL_STOP_LP). Similarly, when the operation of the middle stop switch 42 is accepted, the D1 bit is set to "1", and when the operation of the right stop switch 42 is accepted, the D2 bit is set to "1".
Also, at a predetermined timing (for example, every time the game ends or every time the game starts), the reel stop flag (_FL_STOP_LP) is initialized (cleared, the initial value “00000000(B)” is set).

FIG. 250 is a diagram showing each signal input to the input port 0 in the thirty-third embodiment.
Note that the types and arrangements of signals input to the input port 0 shown in FIG. 250 are merely examples, and the types and arrangements of signals input to the input port 0 can be set as appropriate.
Further, the RWM 53 may be provided with a storage area for the level data corresponding to the input port 0, and the data stored in the storage area for the level data may be acquired and used for processing.
FIG. 251 is a flowchart showing the main processing (M_MAIN) in the 33rd embodiment, and is a flowchart corresponding to FIG. 139 of the 23rd embodiment.
In the flowchart of the thirty-third embodiment shown in FIG. 251, steps different from FIG. 139 are underlined in step numbers, and steps identical to FIG. 139 are given identical step numbers.

Also, in the main process (M_MAIN) of the thirty-third embodiment, the processes of steps S295 to S300 of FIG. 139 are executed, but in FIG. 251, the processes of steps S295 to S300 are omitted.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 251, in the thirty-third embodiment, after the start switch acceptance process (M_START_CTL) of step S751 is executed, the process proceeds to step S1411.
When the processing proceeds to step S1411, the main control board 50 determines whether or not there is stop acceptance. That is, it is determined whether the operation of any of the first stop switch 42 to the third stop switch 42 has been accepted.
Specifically, the main control board 50 acquires the data of the input port 0, and includes the D0 bit (first stop switch signal), the D1 bit (second stop switch signal), and the D2 bit (third stop switch signal). It is determined whether or not any one is on. Then, step S1411 is repeated until there is stop acceptance, and if there is stop acceptance, the process proceeds to the next step S1412.

When the processing proceeds to step S1412, the main control board 50 executes the processing at the time of stop acceptance. In this processing, the stop position of the #reel 31 is determined based on the winning combination lottery result and the position of the #reel 31 at the moment when the operation of the #stop switch 42 is accepted, and according to the determined stop position. The symbol number is set to the # reel symbol number (for stop position) (FIGS. 135 to 137). Further, the stop symbol data for determining the symbol combination to be stopped on the activated line is updated.

More specifically, in the process at the time of stop acceptance in step S1412 of FIG. 251, the process corresponding to steps S1022 to S1024 in FIG. 194 of the 25th embodiment is executed. That is, with respect to the reel 31 corresponding to the stop switch 42 determined to be ON in step S1411, by the process corresponding to steps S1022 to S1023 in FIG. 194, the winning combination lottery result of this game and the operation of the stop switch 42 are accepted. The stop position of the reel 31 is determined based on the position of the reel 31 at the moment, and the symbol number corresponding to the determined stop position is stored in the reel symbol number (for the stop position). Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated.

By the interrupt process executed after the process of step S1412 (the process corresponding to steps S1022 to S1024 in FIG. 194 of the twenty-fifth embodiment), the # reel symbol number (for passing position) and the # reel symbol number ( When it is determined that the same value as that for the stop position) is reached, the # reel drive pulse output counter (_CT_RL#_PLSOUT) (FIGS. 135 to 137) displays the deceleration pulse output counter “90(D)” (FIG. 156). Set the # reel motor signal data (_PT_MOTOR#) (Fig. 134) to the pulse data "00001111 (B)" during deceleration (4 phase ON), and drive the # reel drive state (_WK_RL#_STS) ( 135 to 137), "1(D)" indicating "deceleration" is set.

Further, the # reel symbol number (for passing position) and the # reel symbol number (for stop position) have the same value, and the step number of one symbol of the # reel 13 is a predetermined value (for example, " 3)), the deceleration pulse output counter "90(D)" is set in the # reel drive pulse output counter, and the deceleration pulse data "00001111(B)" is set in the # reel motor signal data. May be set, and “1(D)” indicating “deceleration” may be set in the # reel drive state.

Then, the four-phase excitation output to the motor 32 of the # reel 31 is started.
In the present embodiment, the interrupt processing cycle is set to "1.117 ms", and the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) is decremented by "1" every two interrupts.
When the value of the #th reel drive pulse output counter (_CT_RL#_PLSOUT) becomes “0”, the #reel motor signal data (_PT_MOTOR#) (FIG. 134) contains the pulse data “00000000(B)” at the time of stop. Is set, and the #0 reel drive state (_WK_RL#_STS) is set to “0 (D)” indicating “stop”. As a result, the 4-phase excitation output ends.

When the stop acceptance process in step S1412 is executed, the process advances to step S1413, and the main control board 50 determines whether the four-phase excitation output is being performed.
Specifically, when it is determined that the operation of the first (left) stop switch 42 has been accepted in step S1411, and the processing for stopping the motor 32 of the first (left) reel 31 is executed in step S1412, In step S1413, it is determined whether the motor 32 of the first reel 31 is in the 4-phase excitation output.

When it is determined that the 4-phase excitation output is being performed, the process of step S1413 is executed again, and when it is determined that the 4-phase excitation output is not being performed (the 4-phase excitation output has ended), the next step S1414 is performed. Proceed to.
If it is determined in step S1411 that the operation of the first (left) stop switch 42 has been accepted, the value of the first reel drive pulse output counter (_CT_RL#_PLSOUT) (FIG. 135) is "0" in step S1413. It is possible to determine whether or not the four-phase excitation output of the motor 32 of the first (left) reel 31 is completed.

Further, in step S1413, by determining whether or not the first reel motor signal data (_PT_MOTOR#) (FIG. 134) is “00000000 (B)” (pulse data at stop), the first (left) reel 31 It is also possible to determine whether or not the four-phase excitation output of the motor 32 has ended.
Furthermore, in step S1413, by determining whether the first reel drive state (_WK_RL#_STS) (FIG. 135) is “0 (D)” (stop), the motor 32 of the first (left) reel 31 is determined. It is also possible to determine whether or not the four-phase excitation output of is finished.

In the present embodiment, the process of step S1413 is repeated until it is determined in step S1413 that the four-phase excitation output of the motor 32 of the # reel 31 has ended, and the process does not proceed to the next step S1414.
For this reason, while the four-phase excitation output is being performed to the motor 32 of one of the reels 31, the operation of the stop switch 42 corresponding to the other reel 31 is not accepted and the stop control of the other reel 31 is not executed. ..
For example, during the period in which the four-phase excitation output is performed to the first (left) reel 31, the operation of the second (middle) stop switch 42 and the third (right) stop switch 42 is not accepted, and therefore the second ( The stop control of the middle) reel 31 and the third (right) reel 31 is also not executed.

In step S1414, the main control board 50 determines whether or not the operation (stop operation) of the stop switch 42 has been accepted for all reels 31.
When it is determined in step S1414 that the stop operation has not been accepted for at least one reel 31, the process returns to step S1411. In this case, the processes of steps S1411 to S1414 are repeated.
On the other hand, when it is determined in step S1414 that the stop operation has been accepted for all reels 31, the process proceeds to step S291.

Here, in step S1414, the main control board 50 stores the data stored in the reel stop flag (_FL_STOP_LP) of the address “F0AD(H)” of FIG. Compare.
When the two values are not the same, it is determined that the stop operation has not been accepted for at least one reel 31, the result of step S1414 is "No", and the process returns to step S1411.
On the other hand, when the two values are the same, it is determined that the stop operation has been accepted for all reels 31, the result of step S1414 is "Yes", and the process proceeds to step S291.

Further, in the present embodiment, every time the operation of stopping one reel 31 is accepted, it is determined in step S1413 whether or not the four-phase excitation output is being performed, and when it is determined that the four-phase excitation output is completed. , So that the next stop operation of the reel 31 can be accepted.
As a result, while the motor 32 of one of the reels 31 is performing the four-phase excitation output, the stop operation of the other reel 31 cannot be accepted.

When the processing proceeds to step S291, the main control board 50 executes display determination.
Specifically, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed on the activated line. Further, when the symbol combination for paying out (giving) of medals is stopped and displayed on the activated line, the payout number of tokens (number of grants) is determined. Then, the process proceeds to step S292.

If “No” in the step S292 and the process of the step S293 is executed, the process proceeds to a step S294.
In step S294, the main control board 50 executes a medal payout process (M_WIN_PAY) at the time of winning. That is, when the number of credits has not reached the upper limit value “50”, the number of credits is added, and when the number of credits has reached the upper limit value “50”, the hopper motor 36 is driven to make the actual value. The medals are paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG. Then, the process proceeds to step S1415.

In step S1415, the main control board 50 determines whether the signal of the input port 0 is off.
Specifically, the main control board 50 acquires the data of the input port 0 and determines whether or not it is “00000000(B)”.
Then, when the data of the input port 0 is not "00000000(B)", it is determined that one of the signals is on (operation of any switch including the stop switch 42 is accepted), and step S1415. Then, the result is “No”, and the process of step S1415 is executed again.

On the other hand, when the data of the input port 0 is "00000000(B)", it is determined that all the signals are off (operation of any switch including the stop switch 42 is not accepted), and the step The result of S1415 is “Yes”, and the flow proceeds to the next step S1416.
When proceeding to step S1416, the main control board 50 sets a command regarding the end of the game (game end command) in the command buffer. Further, when the game end command is set in the command buffer, it is transmitted to the sub-control board 80 by an interrupt process executed thereafter.

In addition, the sub control board 80 may execute an effect related to the game result when the game end command is received.
Specifically, for example, it is assumed that the winning number “5” is won by a lottery by the winning role lottery means 61, and the 1BB condition device corresponding to the winning number “5” is activated. In this case, when the start switch 41 is operated, the lottery means 61 performs the lottery, and the 1BB condition device operates, a command (1BB operation command) related to the operation of the 1BB condition device is issued from the main control board 50 to the sub control board. Sent to 80. As a result, it can be determined that the 1BB condition device has operated on the sub-control board 80 side.

In addition, it is assumed that the winning number “7” is won by the lottery means 61 and the “1BB+cherry” condition device corresponding to the winning number “7” is activated. In this case, the symbol combination corresponding to 1BB or the symbol combination corresponding to cherry can be stopped and displayed.
As described above, in the game in which the winning number “7” is won in the lottery by the combination lottery means 61, the symbol combination corresponding to cherry can be stopped and displayed, but the symbol combination corresponding to 1BB is not stopped and displayed. You may comprise.
Then, the start switch 41 is operated, the lottery means 61 performs the lottery, and when the “1BB+cherry” condition device is activated, the 1BB operation command and the cherry operation command are transferred from the main control board 50 to the sub control board 80. Sent. As a result, it can be determined that the 1BB condition device has operated on the sub-control board 80 side.

Further, the sub-control board 80, in the game in which the 1BB operation command and the cherry operation command are received, performs the effect lottery regarding the notification of the winning of the 1BB condition device. In this production lottery, whether or not to notify the winning of the 1BB condition device, the notification timing, the notification mode, and the like are determined.
Here, it is assumed that, for example, it is determined by the production lottery that the production lamp is turned on at the timing of ending the game to notify the winning of the 1BB condition device. In this case, when the sub control board 80 receives a predetermined command (for example, a game end command), the effect lamp is turned on and the winning of the 1BB condition device is notified.

As described above, in the present embodiment, the two reels 31 are stopped, the operation of the stop switch 42 corresponding to the third (last) reel 31 is accepted, and the payout of tokens (assignment) is performed. When the combination is displayed as a stop, a four-phase excitation output for stopping the third reel 31 even if the operation of the stop switch 42 corresponding to the third reel 31 is continued. When step S1413 ends, step S1413 becomes "No", step S1414 becomes "Yes", and processing proceeds to step S291 and subsequent steps. Therefore, the number of payouts (the number of grants) of medals is determined, and the payout (grant) is made in the medal payout process (M_WIN_PAY) at the time of winning.
As a result, even if the operation of the stop switch 42 corresponding to the third reel 31 continues to be accepted, the number of medals to be paid out (number of grants) and the payout (addition) of medals are smoothly performed. Can be executed.

For example, in the game in which the winning number “7” is won by the lottery means 61 and the “1BB+cherry” condition device corresponding to the winning number “7” is operated, two reels 31 (for example, the left reel 31, In a situation where the middle reel 31) is stopped, the operation of the stop switch 42 (right stop switch 42) corresponding to the third reel 31 (for example, the right reel 31) is accepted, and " It is assumed that the symbol combination "cherry"-"ANY"-"ANY" is stopped and displayed on the middle line of the activated line.

In this case, even when the operation of the stop switch 42 corresponding to the third reel 31 is continued, the four-phase excitation output for stopping the third reel 31 is output. After the end, the number of medals to be paid out “1” is determined, and one medal is paid out. At this time, if the credit number has not reached the upper limit value “50”, the credit number is incremented by “1”, and if the credit number has reached the upper limit value “50”, the hopper motor 36 is driven, One medal is paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

Further, in the present embodiment, even when the operation of the stop switch 42 corresponding to the third reel 31 is accepted, determination of the payout number of tokens (number of grants) and payout of tokens (granting). ) Can be executed, but if the state in which the operation of the stop switch 42 corresponding to the third reel 31 is accepted continues, “Yes” in step S1415 and the process does not proceed to step S1416. The predetermined command (for example, the game end command) is not transmitted to the sub control board 80. Therefore, the sub-control board 80 side does not execute an effect based on the reception of a predetermined command (for example, a game end command).

Then, when the stop switch 42 corresponding to the third reel 31 is released (at least when all the stop switches 42 are not operated), “No” is determined in the step S1415, and the step S1416 is performed. Then, it becomes possible to transmit a predetermined command (for example, a game end command) to the sub control board 80. Therefore, the sub-control board 80 side can execute an effect based on the reception of a predetermined command (for example, a game end command).

In particular, in the game in which the winning number “7” is won by the role lottery means 61 and the “1BB+cherry” condition device corresponding to the winning number “7” is activated, “cherry”-“ANY”-“ANY” corresponding to cherry. The symbol combination of “” is stopped and displayed on the middle line of the activated line, and even after the payout (granting) of one medal corresponding to the cherry winning is performed, the stop switch corresponding to the third reel 31. After 42 is released, the effect lamp may be turned on to notify the winning of the 1BB condition device.
As a result, the effect regarding the game result can be executed at the timing desired by the player.

In the game in which the winning number “7” is won and the “1BB+cherry” condition device corresponding to the winning number “7” is activated, 1BB is generated at the timing when the stop switch 42 corresponding to the third reel 31 is released. There may be a case where the operation of the condition device is not notified.
Further, the 1BB condition device has operated, but if the symbol combination corresponding to 1BB is not stopped and displayed on the activated line, the winning information of 1BB is carried over to the next game until the symbol combination corresponding to 1BB is stopped and displayed on the activated line.

For example, in the game in which the winning number “7” is won by the lottery means 61 and the “1BB+cherry” condition device corresponding to the winning number “7” is operated, the start switch 41 is operated and the winning lottery means 61 is used. When the lottery is performed and the “1BB+cherry” condition device is activated, the 1BB activation command is transmitted from the main control board 50 to the sub control board 80.
Further, the situation in which the operation of the stop switch 42 (for example, the right stop switch 42) corresponding to the third reel 31 (for example, the right reel 31) is accepted continues after the medal payout process is executed. If so, a game end command is transmitted from the main control board 50 to the sub control board 80 after the stop switch 42 corresponding to the third reel 31 is released.

Further, when the sub control board 80 receives the 1BB operation command and the cherry operation command, the sub control board 80 performs an effect lottery regarding the notification of the operation of the 1BB condition device. At this time, it is assumed that it is decided to turn on the effect lamp at the timing of the end of the game and notify the winning of the 1BB condition device.
Then, when the sub-control board 80 receives a predetermined command (for example, a game end command), the sub-control board 80 lights the effect lamp to notify that the 1BB condition device is won.

Further, for example, in the game in which the winning number “7” is won by the winning combination lottery means 61 and the “1BB+cherry” condition device corresponding to the winning number “7” is operated, the third reel 31 (for example, the right reel 31 ), the other stop switch 42 (for example, the left stop switch 42) is operated (pushed) while the stop switch 42 (for example, the right stop switch 42) corresponding to It is assumed that the stop switch 42 corresponding to the third reel 31 is released while the switch 42 is operated (pressed).
In this case, in the state where the other stop switch 42 is operated (pressed), the game end command is not transmitted to the sub control board 80 (the effect related to the game result is not executed), and all the other stop switches 42 are included. When the stop switch 42 is released, the game end command can be transmitted to the sub control board 80 (the effect related to the game result can be executed).

Further, when the hopper motor 36 is driven and the actual medals are paid out from the hopper 35, the medals collide with each other to make a loud sound, and a payout effect sound accompanying the payout is output, so that the operation of the 1BB condition device is shown. Although it is difficult to hear the sound of the effect (effect related to the game result), in the present embodiment, if the stop switch 42 corresponding to the third reel 31 is continuously operated, the game is paid out even if the medals are paid out. The effect regarding the result is not executed. Then, when the stop switch 42 corresponding to the third reel 31 is released, the effect regarding the game result is executed.
Therefore, after the payout of the medals, the effect regarding the game result can be executed, so that the sound of the effect can be easily heard.

Further, in the present embodiment, during four-phase excitation output, “Yes” is obtained in step S1413, and the process does not proceed to step S294. Therefore, during the 4-phase excitation output, the medal payout process (M_WIN_PAY) at the time of winning is not executed, but after the 4-phase excitation output is completed, the medal payout process at the time of winning (M_WIN_PAY) is executed.
As a result, the hopper motor 36 is not driven during the four-phase excitation output, and the hopper motor 36 is driven after the end of the four-phase excitation output, so that the current necessary for driving the hopper motor 36 can be secured. it can.

Further, in the present embodiment, the main control board 50 first acquires the data of the input port 0 after the bet number capable of executing the game is bet, and whether the acquired data is “10000000(B)”. Determine whether or not.
Then, when the acquired data is “10000000(B)”, it is determined that only the start switch signal is on, and the rotation start control of the reel 31 based on the operation of the start switch 41 is executed.

On the other hand, for example, when the operation of the start switch 41 is accepted while the operation of the 3-bet switch 40b is accepted, the data of the input port 0 becomes "11000000(B)". In this case, it is determined that the start switch signal and the signal other than the start switch signal (3-bet switch signal) are on, and the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed.

As a result, the operation of the start switch 41 is performed under the situation that the operation of the bet switch 40 (1 bet switch 40a, 3 bet switch 40b) is accepted after the bet number capable of executing the game is bet. When accepted, the rotation start control of the reel 31 based on the operation of the start switch 41 may not be executed.

The present embodiment also includes the setting key switch 152 as described in the eleventh embodiment and the nineteenth embodiment (A).
Then, as described in the eleventh embodiment and the nineteenth embodiment (A), the front door 12 is opened and the door switch 17 is turned on while the power is on and the bet number is not bet. When the setting key is turned on and the setting key is inserted into the setting key insertion port 151 and rotated 90 degrees clockwise, for example, and the setting key switch 152 is turned on (when the signal of the setting key switch 152 is turned on), the setting confirmation state is displayed. Move to (Setting Confirmation Mode).

Note that when the bet number is bet, the result is “Yes” in step S274 in FIG. 41, and the process does not proceed to the medal insertion waiting process in step S275. Do not move.
In the setting confirmation state, the setting value cannot be changed (though the setting value does not change even if the setting change switch 153 is operated), but the current setting value can be confirmed. The current set value is displayed on the set value display LED 73. When the setting key is rotated counterclockwise and the setting key switch 152 is turned off, the setting confirmation state ends.

Further, in the present embodiment, the signal of the setting key switch 152 is not input to the input port 0.
Furthermore, in the present embodiment, when the rotation start control of the reel 31 is executed, the data of the input port to which the signal of the setting key switch 152 is input is not checked.

For example, do not check the data of the input port where the signal of the setting key switch 152 is input, do not check the level data of the RWM 53 corresponding to the input port where the signal of the setting key switch 152 is input, and do not check the level data of the setting key switch. Of the data of the input port to which the signal of 152 is input, the bit corresponding to the signal of the setting key switch 152 is not checked, and the level data of the RWM 53 corresponding to the input port to which the signal of the setting key switch 152 is input. Among them, the bit corresponding to the signal of the setting key switch 152 is not checked.

Therefore, after the bet number (the bet number corresponding to the specified number) capable of executing the game is bet, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is ON), Further, when the operation of the start switch 41 is accepted under the condition that the front door 12 is closed (the door switch 17 is off), the rotation start control of the reel 31 based on the operation of the start switch 41 can be executed. And

Here, after the bet switch 40 is operated, even if the bet switch 40 is released, the bet switch 40 may deteriorate and the operation of the bet switch 40 may remain accepted.
Then, in a state where the operation of the bet switch 40 is still accepted, in the present embodiment, even if the start switch 41 is operated, the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed.

As a result, even if the player operates the start switch 41, the reel 31 does not rotate, so that the player can recognize that some abnormality has occurred in the slot machine 10. Then, the player informs the clerk of the hall to that effect, so that the clerk of the hall can also recognize that something is wrong with the slot machine 10.
Even if the operation of the bet switch 40 remains accepted, neither the main control board 50 nor the sub control board 80 gives an error notification. This is because if the error notification is given in such a case, the player may be annoyed.

Further, it is not normally considered that the setting key switch 152 is turned on (the signal of the setting key switch 152 is turned on) during the game, and the signal of the setting key switch 152 is temporarily input (setting key switch If the signal of 152 is on), it is likely to be noise. Therefore, in the present embodiment, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on when the bet number capable of executing the game (the bet number corresponding to the specified number) is bet). If the operation of the start switch 41 is accepted under the condition that the front door 12 is closed (the door switch 17 is off), the rotation start control of the reel 31 based on the operation of the start switch 41 is performed. To be executable.
With this, it is possible to prevent the progress of the game from being interrupted by noise.

On the other hand, under the condition that the signal of the setting key switch 152 is ON, a predetermined external signal (for example, the external signal 4 for notifying an error or the like (the eleventh embodiment) is based on the signal of the setting key switch 152 being ON. It is possible to notify the hall computer or the like by outputting the form FIG. 33)). Therefore, a store clerk or the like in the hall can recognize that some error has occurred in the slot machine 10 to which a predetermined external signal is output.
In addition, under the condition that the signal of the setting key switch 152 is on, a predetermined external signal (for example, the external signal X (see FIG. 33 of the eleventh embodiment) that can specify that the signal of the setting key switch 152 is on. External signals 1 to 5)) may be output.

Further, in the present embodiment, the main control board 50 acquires the data of the input port 0 in step S1411 of FIG. 251, and outputs the D0 bit (first stop switch signal), D1 bit (second stop switch signal), D2 It is determined whether or not any of the bits (third stop switch signal) is on.
When only one of the D0 to D2 bits is “1”, the stop control of the #reel 31 based on the operation of the #stop switch 42 is executed.

In contrast, when two or more of the D0 to D2 bits are "1", or in addition to one of the D0 to D2 bits, one or more of the D3 to D7 bits is "1". At this time, the stop control of the #th reel 31 based on the operation of the #stop switch 42 is not executed.
Particularly, when one or more of the D5 to D7 bits is “1” in addition to one of the D0 to D2 bits, the stop control of the # reel 31 based on the operation of the # stop switch 42 is performed. Do not execute.

As a result, the plurality of reels 31 are rotated at a constant speed, and the operations of the bet switch 40 (1 bet switch 40a, 3 bet switch 40b) and the start switch 41 are accepted under the condition that the #stop switch 42 is operated. When the operation is accepted, the stop control of the #reel 31 based on the operation of the #stop switch 42 may not be executed.

Similarly, when the plurality of reels 31 rotate at a constant speed and the operation of the left stop switch 42 is accepted, when the operation of the middle stop switch 42 is accepted, the operation of the middle stop switch 42 is performed. It is possible not to execute the stop control of the middle reel 31 based on this.

Further, in the present embodiment, the signal of the setting key switch 152 is not input to the input port 0.
Furthermore, in this embodiment, when the stop control of the #th reel 31 is executed, the data of the input port to which the signal of the setting key switch 152 is input is not checked.
For example, do not check the data of the input port where the signal of the setting key switch 152 is input, do not check the level data of the RWM 53 that corresponds to the input port where the signal of the setting key switch 152 is input, and do not check the level data of the setting key switch. Of the data of the input port to which the signal of 152 is input, the bit corresponding to the signal of the setting key switch 152 is not checked, and the level data of the RWM 53 corresponding to the input port to which the signal of the setting key switch 152 is input. Among them, the bit corresponding to the signal of the setting key switch 152 is not checked.

Therefore, the plurality of reels 31 rotate at a constant speed, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on), and the front door 12 is closed (the door switch 17 is off. Under the situation, when the operation of the #stop switch 42 is accepted, the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed.

Here, after the start switch 41 is operated, even if the start switch 41 is released, there is a possibility that the operation of the start switch 41 remains accepted due to deterioration of the start switch 41.
Then, in a state where the operation of the start switch 41 is still accepted, in the present embodiment, even if the #stop switch 42 is operated, the stop control of the #reel 31 based on the operation of the #stop switch 42 is executed. do not do.

Similarly, even after the bet switch 40 (the 1 bet switch 40a and the 3 bet switch 40b) is operated and then the bet switch 40 is released, the operation of the bet switch 40 remains accepted due to deterioration of the bet switch 40. Even when the #stop switch 42 is operated, the stop control of the #reel 31 based on the operation of the #stop switch 42 is not executed.

As a result, the player can recognize that some abnormality has occurred in the slot machine 10 because the # reel 31 does not stop even if the # stop switch 42 is operated. Then, the player informs the clerk of the hall to that effect, so that the clerk of the hall can also recognize that something is wrong with the slot machine 10.
Even if the operation of the bet switch 40 or the start switch 41 remains accepted, neither the main control board 50 nor the sub control board 80 issues an error notification. This is because if the error notification is given in such a case, the player may be annoyed.

Further, it is not normally considered that the setting key switch 152 is turned on (the signal of the setting key switch 152 is turned on) during the game, and the signal of the setting key switch 152 is temporarily input (setting key switch If the signal of 152 is on), it is likely to be noise. Therefore, in the present embodiment, the plurality of reels 31 rotate at a constant speed, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on), and the front door 12 is closed ( When the operation of the #stop switch 42 is accepted under the situation where the door switch 17 is off), the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed.
With this, it is possible to prevent the progress of the game from being interrupted by noise.

On the other hand, under the condition that the signal of the setting key switch 152 is ON, a predetermined external signal (for example, the external signal 4 for notifying an error or the like (the eleventh embodiment) is based on the signal of the setting key switch 152 being ON. It is possible to notify the hall computer or the like by outputting the form FIG. 33)). Therefore, a store clerk or the like in the hall can recognize that some error has occurred in the slot machine 10 to which a predetermined external signal is output.
In addition, under the condition that the signal of the setting key switch 152 is on, a predetermined external signal (for example, the external signal X (see FIG. 33 of the eleventh embodiment) that can specify that the signal of the setting key switch 152 is on. External signals 1 to 5)) may be output.

The 33rd embodiment of the present invention has been described above, but the present invention is not limited to the above-described contents, and various modifications such as the following are possible.
(1) FIG. 252 is a flowchart showing a modified example of the main processing (M_MAIN) by the main control board 50 in the thirty-third embodiment.
In the flowchart of the modified example of the thirty-third embodiment shown in FIG. 252, steps different from those in FIG. 251 are underlined in step numbers, and steps identical to those in FIG. 251 are given the same step numbers. ..
Hereinafter, differences from FIG. 251 will be mainly described.

In the modified example of the thirty-third embodiment shown in FIG. 252, the display determination of step S291 is executed, “No” is obtained in step S292, and when the process of step S293 is executed, the process proceeds to step S1417, and the main control board 50 determines Condition Determine if the device is working.
Here, as a state in which the specific condition device is operating, for example, a state in which the winning number “6” is won by the combination lottery means 61 and the “1BB+watermelon” condition device corresponding to the winning number “6” is operating , And the winning lottery means 61 wins the winning number “7” and the “1BB+cherry” condition device corresponding to the winning number “7” is operating.

When the specific condition device is operating (the winning number “6” or “7” is won), “Yes” is determined in step S1417, the process proceeds to step S1415, and the specific condition device is not operating. If the predetermined condition device different from the specific condition device is operating, the determination result in step S1417 is "No", step S1415 is skipped, and the process proceeds to step S294.
As a state in which the predetermined condition device is operating, for example, the winning number “3” is won by the winning lottery means 61, and the watermelon condition device corresponding to the winning number “3” is operating, and the winning lottery. The state in which the winning number “4” is won by the means 61 and the cherry condition device corresponding to the winning number “4” is operating can be mentioned.

In step S1415, the main control board 50 determines whether the signal of the input port 0 is off. That is, it is determined whether or not the operation of any switch including the stop switch 42 is accepted.
When it is determined that the operation of any switch has been accepted, the process of step S1415 is executed again, and when it is determined that the operation of any switch has not been accepted, the process proceeds to step S294.

In step S294, the main control board 50 executes a medal payout process (M_WIN_PAY) at the time of winning. That is, payout (grant) of medals is executed. At this time, if the credit number has not reached the upper limit value “50”, the credit number is added, and if the credit number has reached the upper limit value “50”, the hopper motor 36 is driven to generate the actual medal. Is paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG. Then, the process proceeds to step S1416.
When proceeding to step S1416, the main control board 50 sets the game end command in the command buffer. As described above, when the game end command is set in the command buffer, the game end command is transmitted to the sub control board 80 by an interrupt process executed thereafter.

As described above, in the modified example of the thirty-third embodiment shown in FIG. 252, after the display determination process of step S291 is executed and before the medal payout (M_WIN_PAY) process at the time of winning in step S294 is executed, the specific condition is satisfied. If it is determined that the device is operating, and if it is determined that the specific condition device is operating, then it is determined whether the operation of any switch is accepted. When it is determined that the operation of any switch has not been accepted, the process proceeds to step S294.
Therefore, in the game in which the specific condition device is operating, if the stop switch 42 corresponding to the third reel 31 is continuously operated, the medal is not paid out, and the stop switch corresponding to the third reel 31 is not performed. When 42 is released, medals are paid out.

On the other hand, in a game in which the specific condition device is not operating, medals are paid out even if the stop switch 42 corresponding to the third reel 31 is continuously operated.
Thereby, even if the stop switch 42 corresponding to the third reel 31 is continuously operated, the medal is paid out, or if the stop switch 42 corresponding to the third reel 31 is continuously operated, the medal is displayed. If the stop switch 42 corresponding to the third reel 31 is not paid out and the medal is paid out, it is possible to determine whether or not the specific condition device is operating.

For example, in the game in which the winning number “4” is won by the role lottery means 61 and the cherry condition device corresponding to the winning number “4” is operated, the symbol “cherry”-“ANY”-“ANY” corresponding to cherry. When the combination is stopped and displayed on the activated line, the medals are paid out even if the stop switch 42 (for example, the right stop switch 42) corresponding to the third reel 31 (for example, the right reel 31) is continuously operated. ..

On the other hand, in the game in which the winning number “7” is won by the winning combination lottery means 61 and the “1BB+cherry” condition device corresponding to the winning number “7” is activated, “cherry” corresponding to cherry—“ANY”— When the symbol combination of "ANY" is stopped and displayed on the activated line, the stop switch 42 (for example, the right stop switch 42) corresponding to the third reel 31 (for example, the right reel 31) is continuously operated. And the medal is not paid out. Then, when the stop switch 42 corresponding to the third reel 31 is released, the medals are paid out.

Thereby, even if the stop switch 42 corresponding to the third reel 31 is continuously operated when the symbol combination of “cherry”-“ANY”-“ANY” corresponding to cherry is stopped and displayed on the activated line. It is possible to determine whether or not the 1BB condition device has operated depending on whether or not the medals have been paid out.

(2) In the above embodiment, in step S1415, any operation of the first stop switch 42, the second stop switch 42, the third stop switch 42, the first bet switch 40a, the third bet switch 40b, and the start switch 41 is accepted. It is determined whether or not it is, but it is not limited to this.
For example, in step S1415, it may be determined whether or not the operation is accepted only for the first stop switch 42, the second stop switch 42, and the third stop switch 42.

(3) In the above embodiment, the game end command is set in the command buffer in step S1416. Then, the game end command is transmitted to the sub-control board 80, and the sub-control board 80 side controls the effect regarding the game result. However, it is not limited to this.
For example, the effect regarding the game result may be controlled on the main control board 50 side. Then, in step 1418, the main control board 50 may execute an effect related to the game result.

(4) In the above-mentioned embodiment, when the reel 31 and the motor 32 are stopped, the motor 32 (stepping motor) is supposed to perform the four-phase excitation output, but the invention is not limited to this.
When the reel 31 and the motor 32 are stopped, for example, one-phase excitation output may be performed, two-phase excitation output may be performed, or three-phase excitation output may be performed. In addition, first, two-phase excitation output is performed to weaken the brake, then the two-phase excitation output is switched to the four-phase excitation output, and the stronger brake is applied to stop the rotation of the reel 31 and the motor 32. It may be allowed to.
(5) The various modifications shown in the first to thirty-third embodiments and the first to thirty-third embodiments are not limited to being carried out alone, but may be carried out in an appropriate combination.

<34th Embodiment>
In the 34th embodiment, each reel 31 is provided with a # reel driving state (_WK_RL#_STS) capable of storing data indicating the driving state of the reel 31, and is stored in the # reel driving state (_WK_RL#_STS ). When the logical product (AND) operation of the existing data and “40 (H)” is executed and the result becomes “0”, it is judged that the index is detected and the result does not become “0”. If it does, it is determined that the index is not detected.

Then, when the logical product operation of the data stored in the #th reel drive state (_WK_RL#_STS) and “40 (H)” is executed and the result is not “0”, the stop switch 42 is operated. Even if it is done, the stop control of the reel 31 corresponding to the stop switch 42 is not executed.

The symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
253 and 254 are diagrams showing main data according to the 34th embodiment among data stored in the RWM 53 in the 34th embodiment. The data shown in FIGS. 253 and 254 is a part of data, and various data other than the illustrated data is stored in the RWM 53.
Note that, in FIG. 254, “D0” to “D15” indicate the D0 bit to the D15 bit of 16-bit data, respectively.

In FIG. 253, the first reel drive state (_WK_RL1_STS) of the address “F067 (H)” is a storage area that stores data indicating the drive state of the motor 32 of the first (left) reel 31.
The D0 bit indicates whether or not deceleration by 4-phase excitation is in progress, "1" indicates that deceleration by 4-phase excitation is in progress, and "0" indicates that deceleration by 4-phase excitation is not in progress. ..
The D1 bit indicates whether or not deceleration by 2-phase excitation is in progress, "1" indicates that deceleration by 4-phase excitation is in progress, and "0" indicates that deceleration by 4-phase excitation is not in progress. ..
The D5 bit indicates whether or not deceleration is in progress, "1" indicates that deceleration is in progress, and "0" indicates that deceleration is not in progress.

The D1 bit remains "1" even during deceleration due to 4-phase excitation.
Further, the D5 bit is "1" during both deceleration by two-phase excitation and deceleration by four-phase excitation.
As a result, during deceleration due to the two-phase excitation, the D0 bit becomes "0" and the D1 bit and D5 bit become "1".
Further, during deceleration by four-phase excitation, all of the D0 bit, the D1 bit and the D5 bit are “1”.

In the present embodiment, when the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stop position) (_NB_RL#_STPPIC) become the same value, first, two-phase excitation output I do. This applies a weaker brake to the motor 32. Then, the 2-phase excitation output is switched to the 4-phase excitation output. As a result, a strong brake is applied to the motor 32 to stop the rotation of the reel 31 and the motor 32.
In this way, in this embodiment, the load on the motor 32 is reduced.

When the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stop position) (_NB_RL#_STPPIC) have the same value, the D5 bit becomes "1".
Further, when the D5 bit is "1" and the step number (_NB_RL#_STEP) of one symbol of the # reel 13 is less than "16", the two-phase excitation output is performed. At this time, the D1 bit becomes "1". That is, the deceleration is being performed by the two-phase excitation, and the D0 bit becomes "0", and the D1 bit and the D5 bit become "1".

When the D5 bit is "1" and the step number (_NB_RL#_STEP) of one symbol on the # reel 13 becomes "16" or more, the 2-phase excitation output is switched to the 4-phase excitation output (2-phase excitation). Deceleration is completed by). At this time, the D1 bit and the D5 bit remain "1" and the D0 bit becomes "1". That is, deceleration is being performed by four-phase excitation, and all of the D0 bit, D1 bit, and D5 bit become "1".

The two-phase excitation deceleration period during deceleration by the two-phase excitation may be timed (counted), and the deceleration by the four-phase excitation may be started after the two-phase excitation deceleration period has elapsed.
Also, not only when the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stop position) (_NB_RL#_STPPIC) become the same value, for example, # reel The symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stop position) (_NB_RL#_STPPIC) are the same value, and the step number of one symbol on the # reel 13 (_NB_RL#_STEP) 2) becomes a predetermined value (for example, “3”), two-phase excitation output may be performed to weakly brake the motor 32 and the D5 bit may be set to “1”.

The D2 bit indicates whether or not the constant speed is in progress, "1" indicates that the constant speed is in progress, and "0" indicates that the constant speed is not in progress.
When the acceleration process ends, the D2 bit becomes "1".
Start deceleration (after the operation of the stop switch 42 corresponding to the # reel 31 is accepted, # reel symbol number (for passing position) (_NB_RL#_PASPIC) and # reel symbol number (for stop position) (_NB_RL (#_STPPIC) becomes the same value), during deceleration, during deceleration by 2-phase excitation, and during deceleration by 4-phase excitation, D2 bit is "1".

In addition, after the operation of the stop switch 42 corresponding to the # reel 31 is accepted, the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stopping position) (_NB_RL# _STPPIC) becomes the same value, and until the step number (_NB_RL#_STEP) of one symbol of the # reel 13 reaches a predetermined value (for example, “3”), deceleration is started, during that time, The D2 bit may be set to "1".

The D3 bit indicates whether or not the vehicle is accelerating, "1" indicates that the vehicle is accelerating, and "0" indicates that the vehicle is not accelerating.
The D4 bit indicates whether or not the rotation is ready, "1" indicates that the rotation is ready, and "0" indicates that the rotation is not ready.
The D6 bit indicates whether or not the index has been detected, "1" indicates that the index has been detected, and "0" indicates that the index has not been detected (after the index has been detected).

When the operation of the start switch 41 is accepted, "50 (H)"("01010000(B)") is set in the # reel driving state (_WK_RL#_STS).
After that, when the motor 32 of the #th reel 31 starts to accelerate, “48 (H)” (“01001000 (B)”) is set in the #th reel drive state (_WK_RL#_STS).
From the acceptance of the operation of the start switch 41 until the acceleration of the motor 32 of the # reel 31 is started, the rotation preparation state is set. During this period, the D4 bit becomes "1". Then, when the acceleration of the motor 32 of the # reel 31 is started, the D3 bit becomes "1" and the D4 bit becomes "0".
After that, when the reel sensor 33 of the # reel 31 detects the index, the D6 bit changes from “1” to “0” at the rising edge of the # reel sensor signal.

The D7 bit indicates whether or not the deceleration is started, "1" indicates that the deceleration is started, and "0" indicates that the deceleration is not started.
When the operation of the stop switch 42 corresponding to the #th reel 31 is accepted, the D7 bit becomes "1".
After the operation of the stop switch 42 corresponding to the # reel 31 is accepted, the # reel symbol number (for passing position) (_NB_RL#_PASPIC) and the # reel symbol number (for stopping position) (_NB_RL#_STPPIC) The deceleration starts until and become the same value.
Further, during deceleration, during deceleration by two-phase excitation and during deceleration by four-phase excitation, the D7 bit is "1".

In FIG. 253, the second reel drive state (_WK_RL2_STS) of the address “F068 (H)” is a storage area for storing data indicating the drive state of the motor 32 of the second (middle) reel 31, and the address “F069(H The third reel drive state (_WK_RL3_STS) of "H)" is a storage area for storing data indicating the drive state of the motor 32 of the third (right) reel 31. These contents are the same as the first reel drive state (_WK_RL1_STS) of the address "F067(H)".

In FIG. 254, the input port 0 level data (_PT_IN0_OLD) of the address “F090(H)” is the first stop switch signal (D0 bit) and the second stop switch signal (D1 bit) input to each bit of the input port 0. ), 3rd stop switch signal (D2 bit), 1 bet switch signal (D3 bit), 3 bet switch signal (D4 bit), start switch signal (D5 bit), settlement switch signal (D6 bit) ON/OFF This is a storage area for storage.

The #stop switch signal is turned on when the #stop switch 42 is operated (the stop button 42a is pushed), and the #stop switch 42 is released (the pushed stop button 42a is released). Return to the position) and turn off.
The 1-bet switch signal, 3-bet switch signal, start switch signal, and settlement switch signal also turn on when the corresponding switch is operated and turn off when the corresponding switch is released, as with the #stop switch signal. Become.
Then, in the interrupt processing, the signal input to each bit of the input port 0 is read to determine whether each signal is on/off. At some time, "0" is stored in the corresponding bit.

In FIG. 254, the reel stop flag (_FL_STOP_LP) of the address “F095 (H)” is a storage area that stores data indicating whether or not the operation (stop operation) of the stop switch 42 corresponding to each reel 31 is accepted. is there.
The D0 bit indicates whether or not the stop operation of the first (left) reel 31 has been accepted, "1" indicates that the stop operation has not been accepted, and "0" indicates that the stop operation has been accepted. Indicates that (accepted).
Further, the D1 bit indicates whether or not the stop operation of the second (middle) reel 31 has been accepted, and the D2 bit indicates whether or not the stop operation of the third (right) reel 31 has been accepted. These contents are similar to the D0 bit.

Each time the game is started, the reel stop flag (_FL_STOP_LP) is set to the initial value “00000111 (B)”.
When the operation of the first (left) stop switch 42 is accepted, "0" is set to the D0 bit of the reel stop flag (_FL_STOP_LP). Similarly, when the operation of the second (middle) stop switch 42 is accepted, the D1 bit is set to “0”, and when the operation of the third (right) stop switch 42 is accepted, the D2 bit is set to “0”. Set.

FIG. 255(a) is a diagram showing a stop switch determination table (TBL_STPBTN_CHK). The data stored in the stop switch determination table (TBL_STPBTN_CHK) is compared with the data stored in the input port 0 level data (_PT_IN0_OLD), and the stop switch 42 depends on whether the two data match. This is used when determining whether or not the operation is effective.
FIG. 255( b) is a diagram showing a stop acceptance determination table. The data stored in the stop acceptance determination table is used when each reel 31 is inspected before or after the detection of the index, and whether the reel 31 can be stopped by this inspection. It is used when determining whether or not.

FIG. 256 is a flowchart showing main processing (M_MAIN) in the 34th embodiment, and is a flowchart corresponding to FIG. 139 of the 23rd embodiment.
In the flowchart of the thirty-fourth embodiment shown in FIG. 256, steps different from those in FIG. 139 are underlined in step numbers, and steps identical to those in FIG. 139 are identical in step number.

Also, in the main processing (M_MAIN) of the 34th embodiment, the processing of steps S295 to S300 of FIG. 139 is executed, but the illustration of the processing of steps S295 to S300 is omitted in FIG. 256.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 256, in the 34th embodiment, when the start switch acceptance process (M_START_CTL) of step S751 is executed, the process proceeds to step S1421.
When proceeding to step S1421, the main control board 50 executes a reel stop acceptance check. This process is a process shown in FIG. 257 described later. When the reel stop acceptance check in step S1421 ends, the process proceeds to step S291.

When the processing proceeds to step S291, the main control board 50 executes display determination.
Specifically, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed on the activated line. Further, when the symbol combination for paying out (giving) of medals is stopped and displayed on the activated line, the payout number of tokens (number of grants) is determined. Then, the process proceeds to step S292.
The determined payout number of medals may be stored (saved) only in a predetermined register and not stored in the RWM 53, or may be stored in the RWM 53.

If “No” in the step S292 and the process of the step S293 is executed, the process advances to a step S1422.
In step S1422, the main control board 50 determines whether or not any of the stop switch signals is on (operation of any of the stop switches 42 is accepted).
Specifically, in step S1422, the main control board 50 first stores the data stored in the input port 0 level data (_PT_IN0_OLD) (FIG. 254) of the address “F090(H)” of the RWM 53 in the A register. To do.
Next, the main control board 50 performs a logical product (AND) operation of the A register value and "00000111(B)" and determines whether the result is "0" (zero flag is "1"). To judge. Thereby, it is determined whether or not any of the stop switch signals is ON, that is, whether or not the operation of any of the stop switches 42 is accepted.

When the result of the logical product operation is not "0" (the zero flag is not "1"), one of the stop switch signals is on (operation of any of the stop switches 42 is accepted). Then, the result of step S1422 is “Yes”, and the process of step S1422 is executed again. That is, the process of step S1422 is repeated.
On the other hand, when the result of the logical product operation is "0" (the zero flag is "1"), both stop switch signals are off (operation of any stop switch 42 is accepted. No), the determination result is “No” in step S1422, and the process proceeds to step S294.

Here, when at least one operation of the left stop switch 42, the middle stop switch 42, and the right stop switch 42 is accepted, at least one stop switch signal is turned on, and the input port 0 level data ( At least one of the D0 to D2 bits of _PT_IN0_OLD) becomes "1".
When at least one of the D0 to D2 bits of the input port 0 level data (_PT_IN0_OLD) is "1", the result of the above logical product operation does not become "0" (zero flag does not become "1").
When the result of the logical product operation is not "0" (the zero flag is not "1"), "Yes" is obtained in step S1422 and the process of step S1422 is repeated. In this case, the process after step S294 does not proceed, so the medal payout process (M_WIN_PAY) at the time of winning is not executed.

On the other hand, when the left stop switch 42, the middle stop switch 42, and the right stop switch 42 are all released, the left stop switch signal, the middle stop switch signal, and the right stop switch signal are all turned off. , D0 to D2 bits of the input port 0 level data (_PT_IN0_OLD) are all "0".
Further, when the D0 to D2 bits of the input port 0 level data (_PT_IN0_OLD) are all "0", the result of the above logical product operation is "0" (the zero flag becomes "1").
When the result of the logical product operation is "0" (the zero flag is "1"), "No" is obtained in the step S1422, and the process proceeds to the step S294.

In step S294, the main control board 50 executes a medal payout process (M_WIN_PAY) at the time of winning. That is, when the number of credits has not reached the upper limit value “50”, the number of credits is added, and when the number of credits has reached the upper limit value “50”, the hopper motor 36 is driven to make the actual value. The medals are paid out from the hopper 35. The determination as to whether or not the number of credits has reached the upper limit value “50” is made, for example, in step S394 of FIG.

Here, in the present embodiment, display determination is performed in step S291, and then, in step S1422, it is determined whether or not any stop switch signal is ON, and when any stop switch signal is OFF, In step S294, the medal payout process (M_WIN_PAY) at the time of winning is executed.
Therefore, even if the operation of the third (last) stop switch 42 continues to be accepted, it is possible to determine the number of payouts (the number of grants) of medals. Is accepted, the result of step S1422 is “Yes” and the process does not proceed to step S294. Therefore, the medal payout process (M_WIN_PAY) at the time of winning is not executed. When all the stop switches 42 have been released, the result of step S1422 is "No", and the process proceeds to step S294 to enable the medal payout process (M_WIN_PAY) at the time of winning.

Further, for example, in a situation where the operation of the third (last) stop switch 42 (for example, the right stop switch 42) has been accepted, another stop switch 42 (for example, the left stop switch 42) is operated, and then another It is assumed that the third (last) stop switch 42 (for example, right stop switch 42) is released while the stop switch 42 (for example, left stop switch 42) is operated.
In this case, even if the operation of the other stop switch 42 (for example, the left stop switch 42) continues to be accepted, it is possible to determine the payout number (the number of grants) of the medals. Since the operation of 42 (for example, the left stop switch 42) has been accepted, the result of step S1422 is “Yes” and the process does not proceed to step S294. Therefore, the medal payout process (M_WIN_PAY) at the time of winning is not executed.

As described above, under the condition that the operation of any of the stop switches 42 is accepted, the result of step S1422 is “Yes” and the process does not proceed to step S294, so the medal payout process (M_WIN_PAY) at the time of winning is not executed.
When all the stop switches 42 are released, the result of step S1422 is "No", and the process proceeds to step S294 to enable the medal payout process (M_WIN_PAY) at the time of winning the prize.
As a result, it is possible to add the number of credits or pay out medals from the hopper 35 at a timing desired by the player.

FIG. 257 is a flowchart showing the reel stop acceptance check in step S1421 of FIG. 256.
In step S1431, the main control board 50 determines whether or not the input port 0 level data (_PT_IN0_OLD) (FIG. 254) at the address “F090(H)” of the RWM 53 is “0”.
Specifically, the data stored in the input port 0 level data (_PT_IN0_OLD) (Fig. 254) of the address "F090(H)" of the RWM 53 is stored in the A register, and whether the A register value is "0". Determine whether or not.

When it is determined that the value is not "0", the result of step S1431 is "No", and the process of step S1431 is executed again. That is, the process of step S1431 is repeated until “Yes”.
On the other hand, when it is determined to be "0", "Yes" is determined in the step S1431, and the process proceeds to the next step S1432.

As described above, in this embodiment, it is determined in step S1431 whether the data of the input port 0 level data (_PT_IN0_OLD) is "0", and when it is determined that the data is "0", the process proceeds to step S1432. ..
As a result, the stop control of the reel 31 is not executed under the condition that the signal of any switch input to the input port 0 is on (the operation of any switch is accepted). ..
In step S1431, the data stored in the input port 0 level data (_PT_IN0_OLD) of the RWM 53 may not be acquired, but the data of the signal input to the input port 0 may be directly acquired.

When the processing proceeds to step S1432, the main control board 50 executes a stop acceptability inspection. This process is a process shown in FIG. 258 described later. When the stop acceptance check in step S1432 ends, the process advances to step S1433.
In step S1433, the main control board 50 determines whether or not there is inspection data.
Specifically, in step S1433, it is determined whether the zero flag is "1". That is, it is determined whether or not the result of the logical product (AND) operation in step S1454 of FIG. 258 described later is “0”.

Then, when the zero flag is not "1", it is determined that there is inspection data, the result is "Yes" in step S1433, and the process proceeds to the stop acceptance possible inspection in step S1439.
On the other hand, when the zero flag is "1", it is determined that there is no inspection data, the determination result is "No" in step S1433, and the flow proceeds to step S1434.
In step S1434, the main control board 50 determines whether or not the input port 0 level data (_PT_IN0_OLD) (FIG. 254) of the address “F090(H)” of the RWM 53 is “0”.

Specifically, the data stored in the input port 0 level data (_PT_IN0_OLD) (Fig. 254) of the address "F090(H)" of the RWM 53 is stored in the A register, and whether the A register value is "0". Determine whether or not.
When it is determined to be "0", the result of step S1434 is "Yes", and the process returns to step S1432. As a result, the processing from step S1432 to step S1434 is repeated.
On the other hand, when it is determined that the value is not "0", "No" is obtained in the step S1434, and the process proceeds to the next step S1435.

When the processing proceeds to step S1435, the main control board 50 matches the data stored in the input port 0 level data (_PT_IN0_OLD) with one of the data stored in the stop switch determination table (there is matching data). Determine whether or not.
Specifically, first, it is determined whether or not the data stored in the A register in step S1434 and "00000100(B)" stored in the head (first row) of the stop switch determination table match. ..
When it is determined that they match, it is determined that the operation of the third (right) stop switch 42 has been accepted, and the process proceeds to the next step S1436.

On the other hand, if it is determined that they do not match, then whether the data stored in the A register in step S1434 and "00000010(B)" stored in the second row of the stop switch determination table match. Determine whether or not.
When it is determined that they match, it is determined that the operation of the second (middle) stop switch 42 has been accepted, and the process proceeds to the next step S1436.
On the other hand, if it is determined that they do not match, then whether the data stored in the A register in step S1434 and "00000001(B)" stored in the third row of the stop switch determination table match. Determine whether or not.

When it is determined that they match, it is determined that the operation of the first (left) stop switch 42 has been accepted, and the process proceeds to the next step S1436.
On the other hand, when it is determined that they do not match, it is determined that they do not match any of the data stored in the stop switch determination table (no matching data), and the process returns to step S1431. As a result, the processing from step S1431 to step S1435 is repeated.

For example, when the operation of the first (left) stop switch 42 is accepted, the data of the input port 0 level data (_PT_IN0_OLD) becomes “00000001(B)”.
In this case, since it matches “00000001(B)” stored in the third line of the stop switch determination table, it is determined that the operation of the first (left) stop switch 42 is accepted, and the process proceeds to step S1436. ..

Further, for example, when the operations of the first (left) stop switch 42 and the second (middle) stop switch 42 are simultaneously accepted, the data of the input port 0 level data (_PT_IN0_OLD) becomes “00000011 (B)”.
In this case, since it does not match any data stored in the stop switch determination table, it is determined that there is no matching data, and the process returns to step S1431.

As described above, in the present embodiment, when the operations of the plurality of stop switches 42 are simultaneously accepted, the stop switch 42 and other switches (1 bet switch 40a, 3 bet switch 40b, start switch 41, settlement switch 43). If both operations are simultaneously accepted, it is determined in step S1435 that there is no matching data, and the process returns to step S1431.
Thus, in the present embodiment, the stop control of the reel 31 is not executed when the plurality of stop switches 42 are simultaneously operated, or when the stop switch 42 and another switch are simultaneously operated.

That is, even if all the reels 31 are rotated at a constant speed and the indexes are detected to allow the operation of the stop switches 42 to be acceptable, when the plurality of stop switches 42 are simultaneously operated, When the stop switch 42 and another switch are simultaneously operated, it is determined in step S1435 that there is no matching data, the process returns to step S1431, and the stop control of the reel 31 is not executed.

In step S1436, the main control board 50 determines whether or not the stop switch signal for the reel 31 that has been stop-accepted is turned on (operation of the stop switch 42 is accepted).
Specifically, the logical product (AND) operation of the data stored in the A register in step S1434 and the data of the reel stop flag (_FL_STOP_LP) of the address “F095 (H)” of the RWM 53 is performed, and the result is “0”. “(The zero flag is “1”)” is determined.

Then, when the result of the logical product operation is "0" (the zero flag is "1"), it is determined that the stop switch signal for the reel 31 which has been stop-accepted has been turned on, and in step S1436 " "Yes," and the process returns to step S1431. As a result, the processing from step S1431 to step S1436 is repeated. In this case, since the process does not proceed to step S1437, the stop control of the reel 31 is not executed.

On the other hand, when the result of the logical product operation is not "0" (zero flag is not "1"), it is determined that the stop switch signal for the reel 31 that has not been stop-accepted (stop-acceptable) has been turned on. Then, “No” is obtained in the step S1436, and the process proceeds to a step S1437. In this case, the stop control of the reel 31 can be executed.
In this way, in the present embodiment, the stop control is not executed for the reel 31 corresponding to the stop switch 42 for which the stop operation has already been accepted, and the reel 31 corresponding to the stop switch 42 for which the stop operation has not yet been accepted. About stop control is executed.

When the processing proceeds to step S1437, the main control board 50 executes the processing at the time of stop acceptance. In this process, the stop position of the #reel 31 is determined based on the result of the lottery of the current game and the position of the #reel 31 at the moment when the operation of the #stop switch 42 is accepted, and the determined stop is determined. The symbol number corresponding to the position is stored in the # reel symbol number (for stop position). Further, the stop symbol data for determining the symbol combination to be stopped on the activated line is updated.

More specifically, in the process at the time of stop acceptance in step S1437 of FIG. 257, the process corresponding to steps S1022 to S1024 in FIG. 194 of the 25th embodiment is executed. That is, with respect to the reel 31 corresponding to the stop switch 42 determined to be on in steps S1434 to S1436, by the process corresponding to steps S1022 to S1023 in FIG. 194, the winning combination lottery result of this game and the operation of the stop switch 42 are accepted. The stop position of the reel 31 is determined based on the position of the reel 31 at the moment when it is given, and the symbol number corresponding to the determined stop position is stored in the reel symbol number (for the stop position). Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated.

By the interrupt processing executed after the processing of step S1437 (processing corresponding to steps S1022 to S1024 in FIG. 194 of the twenty-fifth embodiment), the # reel symbol number (for passing position) and the # reel symbol number ( (For stop position) has the same value, the motor 32 of the # reel 31 is decelerated by two-phase excitation and then switched to deceleration by four-phase excitation.

Further, the # reel symbol number (for passing position) and the # reel symbol number (for stop position) are the same value, and the step number (_NB_RL#_STEP) of one symbol of the # reel 13 is predetermined. When the value (for example, “3”) is reached, the motor 32 of the # reel 31 may be decelerated by two-phase excitation and then switched to deceleration by four-phase excitation.

When the stop acceptance process of step S1437 is executed, the process proceeds to step S1438, and the main control board 50 determines whether or not all reels 31 have stopped.
Specifically, it is determined whether or not the data of the reel stop flag (_FL_STOP_LP) at the address “F095(H)” of the RWM 53 is “0”.
Here, when the data of the reel stop flag (_FL_STOP_LP) is not "0", it is determined that one of the reels 31 is not stopped, the result is "No" in step S1438, and the process returns to step S1431. As a result, the processing from step S1431 is repeated.

On the other hand, when the data of the reel stop flag (_FL_STOP_LP) is “0”, it is determined that all the reels 31 have stopped, the result in step S1438 is “Yes”, and the processing according to this flowchart ends.
When the process according to this flowchart ends, the process proceeds to step S291 in FIG. 256, and display determination is executed. Then, in the display determination in step S291 of FIG. 256, it is determined whether or not the symbol combination corresponding to the winning combination is stopped and displayed on the activated line, and the symbol combination for paying out (giving) of medals is stopped and displayed on the activated line. In this case, the number of medals to be paid out (number of grants) is determined.

As described above, even if the state in which the operation of the third (last) stop switch 42 is accepted continues, the process proceeds to step S291 in FIG. 256, so that the number of payouts (number of grants) of medals can be determined. is there.
However, if the state in which the operation of the third (last) stop switch 42 is accepted continues, “Yes” is obtained in step S1422 of FIG. 256, and the process does not proceed to step S294 of FIG. 256. Do not execute the medal payout process (M_WIN_PAY).
When all the stop switches 42 are released, the result of step S1422 in FIG. 256 is "No", and the flow proceeds to step S294 in FIG. 256 to enable the medal payout process (M_WIN_PAY) at the time of winning the prize.

Further, when proceeding to step S1439 in FIG. 257, the main control board 50 executes a stop acceptance possible inspection. This process is a process shown in FIG. 258 described later. Then, when the stop acceptance inspection in step S1439 ends, the process proceeds to step S1440.
In step S1440, the main control board 50 determines whether there is inspection data.
Specifically, in step S1440, it is determined whether the zero flag is "1". That is, it is determined whether or not the result of the logical product (AND) operation in step S1454 of FIG. 258 described later is “0”.

Then, when the zero flag is not "1", it is determined that there is inspection data, the result is "Yes" in step S1440, and the process returns to the stop acceptance inspection in step S1439. As a result, the processes of steps S1439 and S1440 are repeated.
On the other hand, when the zero flag is "1", it is determined that there is no inspection data, the determination result is "No" in step S1440, and the process returns to step S1431. As a result, the processing from step S1431 is repeated.

FIG. 258 is a flowchart showing the stop acceptance test in steps S1432 and S1439 of FIG. 257.
In step S1451, the main control board 50 sets the stop acceptance determination table (FIG. 255(b)). Then, the process proceeds to next Step S1452.
When the processing proceeds to step S1452, the main control board 50 acquires the number of inspections from the stop acceptance determination table. Specifically, the inspection count “3” stored at the head (first row) of the stop acceptance determination table is acquired and stored in the B register. Then, the process proceeds to next Step S1453.

In step S1453, the main control board 50 acquires the mask data and the lower address of the inspection RWM address from the stop acceptance determination table. Specifically, the mask data “40(H)” stored in the second to fourth lines of the stop acceptance determination table is acquired and stored in the C register, and the lower address “LOW_WK_RL1_STS” of the inspection RWM address is acquired. -"LOW_WK_RL1_STS" ("67(H)"-"69(H)") are acquired and stored in the A register. Then, the process proceeds to next Step S1454.

Here, in the first inspection, the mask data “40(H)” and the lower address “LOW_WK_RL1_STS” (“67(H)”) of the inspection RWM address stored in the second row are acquired, and the second inspection is performed. In the inspection, the mask data “40(H)” stored in the third row and the lower address “LOW_WK_RL2_STS” (“68(H)”) of the inspection RWM address are acquired, and in the third inspection, the fourth row is acquired. The mask data “40 (H)” and the lower address “LOW_WK_RL3_STS” (“69 (H)”) of the inspection RWM address stored in the memory are acquired.
After performing the first inspection, if the result of step S1456 described later is “No”, the second inspection is performed next, and if the result of step S1456 is “No” again, the third inspection is performed next. To do. In this way, each reel 31 is inspected (whether it is before or after detection of the index).

In step S1454, the main control board 50 acquires the data of the storage area indicated by the inspection RWM address. Specifically, the data stored in the storage area of the RWM 53 whose lower address is the A register value is stored in the A register. Then, the process proceeds to next Step S1455.
Here, in the first inspection, the data of the first reel drive state (WK_RL1_STS) is stored in the A register. Further, in the second inspection, the data of the second reel driving state (WK_RL2_STS) is stored in the A register, and in the third inspection, the data of the third reel driving state (WK_RL3_STS) is stored in the A register.

When proceeding to step S1455, the main control board 50 performs a logical product (AND) operation of the data acquired at step S1454 and the mask data. Specifically, in step S1455, the #reel drive state (WK_RL#_STS) data stored in the A register in step S1454 and the mask data “40(H)” (“01000000” stored in the C register in step S1453). (B)”). Then, the process proceeds to next Step S1456.

Here, when the rotation of the # reel 31 reaches the constant speed but before the reel sensor 33 of the # reel 31 detects the index, the D6 bit of the # reel drive state (WK_RL#_STS) is It is "1". Therefore, the result of the above logical product operation does not become "0" (the zero flag does not become "1").
When the motor 32 of the #reel 31 loses step after the rotation of the #reel 31 reaches a constant speed, re-acceleration processing is performed. At this time, the D6 bit in the #th reel drive state (WK_RL#_STS) is set to “1”, and the re-acceleration process is performed. In this case as well, the result of the above logical product operation does not become "0" (the zero flag does not become "1").

On the other hand, when the rotation of the # reel 31 reaches the constant speed and the reel sensor 33 of the # reel 31 detects the index, the D6 bit of the # reel drive state (WK_RL#_STS) is It is "0". Therefore, the result of the above logical product operation becomes "0" (the zero flag becomes "1").
In step S1456, the main control board 50 determines whether or not there is inspection data. Specifically, it is determined whether or not the result of the AND operation executed in step S1455 is "0", and when it is "0" (the zero flag is "1"), it is determined that there is no inspection data. Then, “No” is obtained in the step S1456, and the process proceeds to the next step S1457.

Here, when the rotation of the reel 31 reaches a constant speed and after the reel sensor 33 detects the index, when the four-phase excitation output for stopping the reel 31 is being performed, and when the reel 31 is stopped. When it has been completed, the D6 bit of the # reel drive state (WK_RL#_STS) is “0”, so the result of the above logical product operation is “0” (zero flag is “1”). In this case, “No” is obtained in the step S1456, and the process proceeds to the next step S1457.
On the other hand, when the result of the logical product operation is not "0" (zero flag is not "1"), it is determined that there is inspection data, the result is "Yes" in step S1456, and the processing according to this flowchart ends.

In step S1457, the main control board 50 determines whether or not the number of inspections has been completed. Specifically, "1" is subtracted from the B register value, and the result is stored in the B register. Then, it is determined whether or not the B register value is "0". When the B register value is "0", it is determined that the number of inspections has ended, "Yes" is determined in the step S1457, and the processing according to this flowchart is ended. ..
On the other hand, when the B register value is not "0", it is determined that the number of inspections has not been completed, the result is "No" in step S1457, and the process returns to step S1453. In this case, the processing after step S1453 will be repeated.

Further, when “Yes” (inspection data exists) in step S1456 and the process according to this flowchart is finished, “Yes” is obtained in step S1433 of FIG. 257, and “Yes” is also obtained in step S1440 of FIG. 257. For this reason, since the process does not proceed to step 1437 of FIG. 257, the stop control of the reel 31 is not executed. That is, the stop control of the reel 31 is not executed before the reel sensor 33 detects the index.

Further, for example, the first (left) reel 31 is stopped, the second (middle) reel 31 is rotating at a constant speed and after the index is detected, and the third (right) reel 31 is also rotating at a constant speed. It is assumed that it is in the middle and after the index is detected.
In this case, since the D6 bit of the first reel drive state (WK_RL1_STS) is “0”, the data of the first reel drive state (WK_RL1_STS) and “40(H)” (“01000000(B )") results in "0" (zero flag is "1").

Further, since the D6 bit of the second reel drive state (WK_RL2_STS) is also “0”, the logical product operation of the data of the second reel drive state (WK_RL2_STS) and “40(H)” is performed in the second inspection. The result is "0".
Further, since the D6 bit of the third reel drive state (WK_RL3_STS) is also “0”, the AND operation of the data of the third reel drive state (WK_RL3_STS) and “40(H)” is performed in the third inspection. The result is "0".
Then, in the third inspection, “No” is obtained in step S1456, “Yes” is obtained in step S1457, and the processing according to this flowchart is ended.

Further, for example, the first (left) reel 31 is stopped, the second (middle) reel 31 is rotating at a constant speed and before index detection, and the third (right) reel 31 is also rotating at a constant speed. It is assumed that it is in the middle and after the index is detected.
In this case, as described above, the result of the AND operation between the data of the first reel drive state (WK_RL1_STS) and "40(H)" becomes "0" in the first inspection.

However, since the D6 bit of the second reel drive state (WK_RL2_STS) is "1", the logical product operation of the data of the second reel drive state (WK_RL2_STS) and "40(H)" is performed in the second inspection. The result is "01000000(B)" (not "0").
Then, in the second inspection, the result of step S1456 is “Yes”, and the process of this flowchart ends.

In this way, in the stop acceptance inspection shown in FIG. 258, it is inspected (checked) for each reel 31 whether the index is detected or not. Since each reel 31 can be inspected by a common process, the process can be simplified and the amount of ROM used by the program can be reduced.

As described above, in the present embodiment, each reel 31 is provided with the #th reel drive state (_WK_RL#_STS) (FIG. 253) capable of storing data indicating the drive state of the reel 31. In step S1455 of FIG. 258, the logical product (AND) operation of the data stored in the #th reel drive state (_WK_RL#_STS) and the mask data “40(H)” is executed.
Here, when the rotation of the #reel 31 reaches the constant speed and the reel sensor 33 of the #reel 31 detects the index, the D6 bit of the #reel drive state (WK_RL#_STS) is “ It is "0". Therefore, the result of the above logical product operation is "0" (zero flag is "1"). At this time, it is determined that the index has been detected, and the result of step S1456 in FIG. 258 is “No”.

On the other hand, when the rotation of the #reel 31 reaches the constant speed but before the reel sensor 33 of the #reel 31 detects the index, the D6 bit of the #reel drive state (WK_RL#_STS) Is "1". Therefore, the result of the above logical product operation does not become "0" (zero flag is "1"). At this time, it is determined that the index has not been detected, and the result of step S1456 in FIG. 258 is “Yes”.
When the result of the logical product operation is not "0" (the zero flag is "1"), "Yes" is obtained in step S1433 and step S1440 in FIG. 257, and the process does not proceed to step S1437. Even if 42 is operated, stop control of the reel 31 corresponding to the stop switch 42 is not executed.

That is, in the #th reel drive state (WK_RL#_STS), as information regarding the drive state of the reel 31, information is stored that can identify whether the index has been detected or not, even in the constant speed state. When the predetermined calculation is performed using the data of the #th reel drive state (WK_RL#_STS), the result of the predetermined calculation is different before and after the detection of the index.
Then, the stop control of the reel 31 is performed by a simple calculation process by determining whether the index is detected before or after the detection, and whether or not the stop control of the reel 31 can be executed, based on the result of the predetermined calculation. It can be possible to determine whether or not it is feasible.

Further, in the present embodiment, the main control board 50, after the bet number (the bet number corresponding to the specified number) capable of executing the game is bet, first, the input port 0 of the address “F090 (H)” of the RWM 53 The data stored in the level data (_PT_IN0_OLD) (FIG. 254) is acquired, and it is determined whether the acquired data is “0”.
Furthermore, when it is determined that the acquired data is not "0", then the logical product (AND) operation of the data of the input port 0 level data (_PT_IN0_OLD) and "11011111(B)" is performed, and the result is obtained. Is determined to be "0".

When it is determined that the result of the AND operation is "0", it is determined that only the start switch signal is on, and the rotation start control of the reel 31 based on the operation of the start switch 41 is executed.
On the other hand, when it is determined that the data of the input port 0 level data (_PT_IN0_OLD) is "0", and when the result of the logical product operation is not "0", it is based on the operation of the start switch 41. The rotation start control of the reel 31 is not executed.

As a result, the bet switch 40 (1 bet switch 40a, 3 bet switch 40b), (left, middle, right) after the bet number capable of executing the game (the bet number corresponding to the specified number) is bet When the operation of the start switch 41 is accepted while the operations of the stop switch 42 and the settlement switch 43 are accepted, the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed. You can

The present embodiment also includes the setting key switch 152 as described in the eleventh embodiment and the nineteenth embodiment (A).
Then, as described in the eleventh embodiment and the nineteenth embodiment (A), the front door 12 is opened and the door switch 17 is turned on while the power is on and the bet number is not bet. When the setting key is turned on and the setting key is inserted into the setting key insertion port 151 and rotated 90 degrees clockwise, for example, and the setting key switch 152 is turned on (when the signal of the setting key switch 152 is turned on), the setting confirmation state is displayed. Move to (Setting Confirmation Mode).

Note that when the bet number is bet, the result is “Yes” in step S274 in FIG. 41, and the process does not proceed to the medal insertion waiting process in step S275. Do not move.
In the setting confirmation state, the setting value cannot be changed (though the setting value does not change even if the setting change switch 153 is operated), but the current setting value can be confirmed. The current set value is displayed on the set value display LED 73. When the setting key is rotated counterclockwise and the setting key switch 152 is turned off, the setting confirmation state ends.

Then, as described above, when the rotation start control of the reel 31 is executed, the data stored in the input port 0 level data (_PT_IN0_OLD) is checked, but the signal of the setting key switch 152 is input to the input port. Data is not checked.
For example, do not check the data of the input port where the signal of the setting key switch 152 is input, do not check the level data of the RWM 53 that corresponds to the input port where the signal of the setting key switch 152 is input, and do not check the level data of the setting key switch. Of the data of the input port to which the signal of 152 is input, the bit corresponding to the signal of the setting key switch 152 is not checked, and the level data of the RWM 53 corresponding to the input port to which the signal of the setting key switch 152 is input. Among them, the bit corresponding to the signal of the setting key switch 152 is not checked.

Therefore, after the bet number (the bet number corresponding to the specified number) capable of executing the game is bet, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is ON), When the operation of the start switch 41 is accepted under the condition that the front door 12 is closed (the door switch 17 is off), the rotation start control of the reel 31 based on the operation of the start switch 41 can be executed. To do.

Here, after the bet switch 40 is operated, even if the bet switch 40 is released, the bet switch 40 may deteriorate and the operation of the bet switch 40 may remain accepted.
Then, in a state where the operation of the bet switch 40 is still accepted, in the present embodiment, even if the start switch 41 is operated, the rotation start control of the reel 31 based on the operation of the start switch 41 is not executed.

Similarly, even if the start switch 41 is operated when the left (middle, right) stop switch 42 and the settlement switch 43 are deteriorated and the operations are still accepted, even if the start switch 41 is operated. The rotation start control of the reel 31 based on the operation is not executed.
As a result, even if the player operates the start switch 41, the reel 31 does not rotate, so that the player can recognize that some abnormality has occurred in the slot machine 10. Then, the player informs the clerk of the hall to that effect, so that the clerk of the hall can also recognize that something is wrong with the slot machine 10.
Even if the operation of the bet switch 40, the (left, middle, right) stop switch 42 or the settlement switch 43 remains accepted, both the main control board 50 and the sub-control board 80 report an error. Does not. This is because if the error notification is given in such a case, the player may be annoyed.

Further, it is not normally considered that the setting key switch 152 is turned on (the signal of the setting key switch 152 is turned on) during the game, and the signal of the setting key switch 152 is temporarily input (setting key switch If the signal of 152 is on), it is likely to be noise. Therefore, in the present embodiment, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on when the bet number capable of executing the game (the bet number corresponding to the specified number) is bet). If the operation of the start switch 41 is accepted under the condition that the front door 12 is closed (the door switch 17 is off), the rotation start control of the reel 31 based on the operation of the start switch 41 is performed. To be executable.
With this, it is possible to prevent the progress of the game from being interrupted by noise.

On the other hand, under the condition that the signal of the setting key switch 152 is ON, a predetermined external signal (for example, the external signal 4 for notifying an error or the like (the eleventh embodiment) is based on the signal of the setting key switch 152 being ON. It is possible to notify the hall computer or the like by outputting the form FIG. 33)). Therefore, a store clerk or the like in the hall can recognize that some error has occurred in the slot machine 10 to which a predetermined external signal is output.
In addition, under the condition that the signal of the setting key switch 152 is on, a predetermined external signal (for example, the external signal X (see FIG. 33 of the eleventh embodiment) that can specify that the signal of the setting key switch 152 is on. External signals 1 to 5)) may be output.

In addition, in the present embodiment, the main control board 50 stores the data stored in the input port 0 level data (_PT_IN0_OLD) and the stop switch determination table in step S1435 of the reel stop acceptance check in FIG. 257. It is determined whether or not any data matches (there is matching data).
When it is determined that the data stored in the input port 0 level data (_PT_IN0_OLD) and the “00000100(B)” stored in the head (first line) of the stop switch determination table match, It is determined that the operation of the 3 (right) stop switch 42 is accepted, and the process proceeds to step S1436.

When it is determined that the data stored in the input port 0 level data (_PT_IN0_OLD) and "00000010(B)" stored in the second row of the stop switch determination table match, the second (medium) ) It is determined that the operation of the stop switch 42 is accepted, and the process proceeds to step S1436.
Further, when it is determined that the data stored in the input port 0 level data (_PT_IN0_OLD) and "00000001(B)" stored in the third line of the stop switch determination table match, the first (left) ) It is determined that the operation of the stop switch 42 is accepted, and the process proceeds to step S1436.

On the other hand, when it is determined that the data does not match any of the data stored in the stop switch determination table (no matching data), the process returns to step S1431.
Accordingly, when the operation of the #stop switch 42 is accepted in a situation in which the plurality of reels 31 are rotating at a constant speed and the operation of the start switch 41 is accepted, the operation of the #stop switch 42 is operated. The stop control of the #th reel 31 based on is not executed.

Further, as described above, when the stop control of the # reel 31 is executed, the data stored in the input port 0 level data (_PT_IN0_OLD) is checked, but the signal of the setting key switch 152 is input. Do not check port data.
For example, do not check the data of the input port where the signal of the setting key switch 152 is input, do not check the level data of the RWM 53 that corresponds to the input port where the signal of the setting key switch 152 is input, and do not check the level data of the setting key switch. Of the data of the input port to which the signal of 152 is input, the bit corresponding to the signal of the setting key switch 152 is not checked, and the level data of the RWM 53 corresponding to the input port to which the signal of the setting key switch 152 is input. Among them, the bit corresponding to the signal of the setting key switch 152 is not checked.

Therefore, the plurality of reels 31 rotate at a constant speed, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on), and the front door 12 is closed (the door switch 17 is off. Under the situation, when the operation of the #stop switch 42 is accepted, the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed.

Here, after the start switch 41 is operated, even if the start switch 41 is released, there is a possibility that the operation of the start switch 41 remains accepted due to deterioration of the start switch 41.
Then, in a state where the operation of the start switch 41 is still accepted, in the present embodiment, even if the #stop switch 42 is operated, the stop control of the #reel 31 based on the operation of the #stop switch 42 is executed. do not do.

Similarly, even after the bet switch 40 (the 1 bet switch 40a and the 3 bet switch 40b) is operated and then the bet switch 40 is released, the operation of the bet switch 40 remains accepted due to deterioration of the bet switch 40. When the adjustment switch 43 is released after the adjustment switch 43 is operated, the operation of the adjustment switch 43 remains accepted due to deterioration of the adjustment switch 43. As for the above, even if the #stop switch 42 is operated, the stop control of the #reel 31 based on the operation of the #stop switch 42 is not executed.

As a result, the player can recognize that some abnormality has occurred in the slot machine 10 because the # reel 31 does not stop even if the # stop switch 42 is operated. Then, the player informs the clerk of the hall to that effect, so that the clerk of the hall can also recognize that something is wrong with the slot machine 10.
Even if the operation of the bet switch 40, the start switch 41, and the adjustment switch 43 remains accepted, neither the main control board 50 nor the sub control board 80 gives an error notification. This is because if the error notification is given in such a case, the player may be annoyed.

Further, it is not normally considered that the setting key switch 152 is turned on (the signal of the setting key switch 152 is turned on) during the game, and the signal of the setting key switch 152 is temporarily input (setting key switch If the signal of 152 is on), it is likely to be noise. Therefore, in the present embodiment, the plurality of reels 31 rotate at a constant speed, the signal of the setting key switch 152 is input (the signal of the setting key switch 152 is on), and the front door 12 is closed ( When the operation of the #stop switch 42 is accepted under the situation where the door switch 17 is off), the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed.
With this, it is possible to prevent the progress of the game from being interrupted by noise.

On the other hand, under the condition that the signal of the setting key switch 152 is ON, a predetermined external signal (for example, the external signal 4 for notifying an error or the like (the eleventh embodiment) is based on the signal of the setting key switch 152 being ON. It is possible to notify the hall computer or the like by outputting the form FIG. 33)). Therefore, a store clerk or the like in the hall can recognize that some error has occurred in the slot machine 10 to which a predetermined external signal is output.
In addition, under the condition that the signal of the setting key switch 152 is on, a predetermined external signal (for example, the external signal X (see FIG. 33 of the eleventh embodiment) that can specify that the signal of the setting key switch 152 is on. External signals 1 to 5)) may be output.

The 34th embodiment of the present invention has been described above, but the present invention is not limited to the contents described above, and various modifications such as the following are possible.
(1) In the above-described embodiment, when the operation of the #stop switch 42 is accepted in a situation where the plurality of reels 31 are rotating at a constant speed and the operation of the start switch 41 is accepted, The stop control of the # reel 31 based on the operation of the stop switch 42 is not executed.
However, the present invention is not limited to this, and for example, when the operation of the #stop switch 42 is accepted under the situation that the plurality of reels 31 are rotating at a constant speed and the operation of the start switch 41 is accepted, The stop control of the # reel 31 based on the operation of the # stop switch 42 may be made executable.

Thus, for example, when the left stop switch 42 is operated first and the middle stop switch 42 is operated second, when the left stop switch 42 is operated, the start switch 41 is deteriorated and the start switch 41 is deteriorated. Since the operation of 41 is still accepted, it can be prevented that the middle stop switch 42 is initially operated.

Particularly, in the AT machine, if it is determined that the middle stop switch 42 is operated first even though the left stop switch 42 is operated first, the pushing order is mistaken, which causes a disadvantage to the player. However, even if the operation of the start switch 41 is accepted, by making it possible to execute the stop control of the #reel 31 based on the operation of the #stop switch 42, it is possible to make a mistake in the pushing order during AT. Occurrence can be prevented.

Even if the stop control of the #reel 31 based on the operation of the #stop switch 42 can be executed under the condition that the operation of the start switch 41 is accepted as in this modification, the setting key The stop control of the #reel 31 based on the operation of the #stop switch 42 may be executed regardless of whether the signal of the switch 152 is turned on or off. Further, when the signal of the setting key switch 152 is ON, the stop control of the #th reel 31 based on the operation of the #stop switch 42 may not be executed.

(2) In the above embodiment, the stop control of the reel 31 is not executed when the operation of the plurality of stop switches 42 is accepted.
However, the operation of the first stop switch 42 is not limited to this, and the operation of the second stop switch 42 is then performed under the situation where the operation of the first stop switch 42 is still accepted. The acceptance control may be performed, and the stop control of the corresponding reel 31 may be executable based on the operation of the second stop switch 42.

Thus, for example, even if the left stop switch 42, the middle stop switch 42, and the right stop switch 42 are operated in this order, when the middle stop switch 42 is operated, the left stop switch 42 is deteriorated due to deterioration of the stop switch 42 or the like. Since the operation of 42 is still accepted, it can be prevented that the right stop switch 42 is secondly operated.

In particular, in the AT machine, when the stop operation is performed in the order of the left stop switch 42, the middle stop switch 42, and the right stop switch 42, even though the middle stop switch 42 is operated second, the right stop switch 42 is operated second. If it is determined that the stop switch 42 has been operated, it will be a mistake in the pushing order, which will be disadvantageous to the player. Even if the operation of any of the stop switches 42 is still accepted, other The operation of the stop switch 42 can be accepted, and the stop control of the corresponding reel 31 can be executed on the basis of the operation of the other stop switch 42, so that a mistake in the pushing order during AT will occur. It is possible to prevent the occurrence of a situation.

Even in the case where the stop control of the reel 31 based on the operation of the second stop switch 42 can be executed under the condition that the operation of the first stop switch 42 is still accepted as in this modification. The stop control of the reel 31 based on the operation of the stop switch 42 may be executable regardless of whether the signal of the setting key switch 152 is turned on or off. Further, when the signal of the setting key switch 152 is ON, the stop control of the reel 31 based on the operation of the stop switch 42 may not be executed.

(3) In the above embodiment, when the reel 31 and the motor 32 (stepping motor) are stopped, first, two-phase excitation output is performed to weaken the brake, and then two-phase excitation output to four-phase excitation output. Switch to and apply a strong brake, but it is not limited to this.
When the reel 31 and the motor 32 are stopped, for example, one-phase excitation output may be performed, two-phase excitation output may be performed, three-phase excitation output may be performed, or four-phase excitation output may be performed. Good.
(4) The first to thirty-fourth embodiments and the various modifications shown in the first to thirty-fourth embodiments are not limited to being performed alone, but may be appropriately combined and performed.

<35th Embodiment>
The thirty-fifth embodiment stores information for determining which stop switch 42 corresponding to which stop control of the reel 31 can be executed when operations of a plurality of stop switches 42 are simultaneously accepted. The stop switch reception table (TBL_STOP_BTN) (FIG. 259) is provided.

Then, under the condition that the plurality of reels 31 are rotating at a constant speed, the operation of the first (any one) stop switch 42 and the operation of the second (one other different from the first) stop switch 42 are performed. When the operation and the operation are simultaneously received, the stop control of the reel 31 corresponding to the first stop switch 42 can be executed based on the information acquired using the stop switch reception table (TBL_STOP_BTN).

Further, the reel 31 corresponding to the first (any one) stop switch 42 is stopped, and the reel 31 corresponding to the second (one different from the first) stop switch 42 is rotated at a constant speed. Under the situation where the operation of the first stop switch 42 and the operation of the second stop switch 42 are simultaneously accepted, based on the information acquired using the stop switch acceptance table (TBL_STOP_BTN), The stop control of the reel 31 corresponding to the second stop switch 42 can be executed.

The symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
In the thirty-fifth embodiment as well, similar to FIG. 173 of the twenty-fifth embodiment, the reel stop flag (_FL_STOP_LP) of the address “F0AD(H)” of the RWM 53 is provided.
The reel stop flag (_FL_STOP_LP) is a storage area that stores data indicating whether or not the operation (stop operation) of the stop switch 42 corresponding to each reel 31 is accepted.
The content of each bit is the same as in FIG. 173 of the twenty-fifth embodiment.

Each time the game is started, the reel stop flag (_FL_STOP_LP) is set to the initial value “00000111 (B)”.
When the operation of the first (left) stop switch 42 is accepted, "0" is set to the D0 bit of the reel stop flag (_FL_STOP_LP). Similarly, when the operation of the second (middle) stop switch 42 is accepted, the D1 bit is set to “0”, and when the operation of the third (right) stop switch 42 is accepted, the D2 bit is set to “0”. Set.

FIG. 259 is a diagram showing a stop switch acceptance table (TBL_STOP_BTN).
The data stored in the stop switch acceptance table (TBL_STOP_BTN) indicates which stop switch 42 corresponding to which stop control can be executed when operations of a plurality of stop switches 42 are simultaneously accepted. It is used when making a decision.
Further, in FIG. 259, “00000001(B)” is data indicating that the stop control of the first (left) reel 31 is executed, and “00000010(B)” is the data of the second (middle) reel 31. "00000100(B)" is data indicating that the stop control is executed, and "00000100(B)" is data indicating that the stop control of the third (right) reel 31 is executed.

Subsequently, the control process in the thirty-fifth embodiment will be described using a flowchart.
FIG. 260 is a flow chart showing a reel stop acceptance check in the thirty-fifth embodiment. In the 35th embodiment, the reel stop acceptance check of step S1460 of FIG. 260 is executed instead of the reel stop acceptance check of step S752 of FIG. 139.
In step S1461, the main control board 50 acquires the data stored in the reel stop flag (_FL_STOP_LP) of the address “F0AD(H)” in FIG. 173 and stores it in the B register. Then, the process proceeds to next Step S1462.

In step S1462, the main control board 50 determines whether or not the operation of the stop switch 42 corresponding to the spinning reel 31 has been accepted.
Specifically, first, the data stored in the input port rising data A (_PT_IN_A_UP) of the address “F017(H)” in FIG. 133 is stored in the A register.
Next, the logical product (AND) operation of the A register value and the B register value is performed, and the result is stored in the A register. That is, the logical product (AND) operation of the data stored in the input port rising data A (_PT_IN_A_UP) and the data stored in the reel stop flag (_FL_STOP_LP) is performed, and the result is stored in the A register.

Then, when the result of the logical product operation is not "0" (the zero flag is "1"), it is determined that the operation of the stop switch 42 corresponding to the spinning reel 31 is accepted, and "Yes" in step S1462. Therefore, the process advances to the next step S1463.
On the other hand, when the result of the AND operation is "0" (zero flag is "1"), it is determined that the operation of the stop switch 42 corresponding to the spinning reel 31 is not accepted, and the step The result of S1462 is "No", and the processing according to this flowchart ends.
In step S1463, the main control board 50 sets the stop switch reception table (TBL_STOP_BTN). Specifically, "1100 (H)" (reference address) obtained by subtracting "1" from the start address "1101 (H)" of the stop switch acceptance table (TBL_STOP_BTN) is set in the HL register. Then, the process proceeds to next Step S1464.

In step S1464, the main control board 50 sets designated address data. Here, the HL register value (“1100 (H)”) at the time of proceeding to step S1464 is used as the reference address, and the A register value is used as the offset value. The address obtained by adding the offset value to the reference address is set as the designated address. Then, in step S1464, first, the A register value (offset value) is added to the HL register value (reference address), and the result (designated address) is stored in the HL register. Next, the data stored at the address indicated by the HL register value (specified address) is acquired and stored in the A register. The A register value at this time indicates the reel 31 for which stop control is performed. Then, the process proceeds to next Step S1465.

When the processing proceeds to step S1465, the main control board 50 executes the processing at the time of stop acceptance. Here, the A register value at the time of proceeding to step S1465 indicates the reel 31 for which stop control is performed. Then, in step S1465, for the reel 31 indicated by the A register value, the stop position of the reel 31 is determined based on the winning combination lottery result and the position of the reel 31 at the moment when the corresponding operation of the stop switch 42 is accepted. The symbol number corresponding to the determined stop position is stored in the reel symbol number (for the stop position). Then, the process proceeds to next Step S1466. Further, the stop symbol data for determining the symbol combination to be stopped on the activated line is updated.

More specifically, in the process at the time of stop acceptance in step S1465 of FIG. 260, the process corresponding to steps S1022 to S1024 in FIG. 194 of the 25th embodiment is executed. That is, with respect to the reel 31 corresponding to the stop switch 42 determined to be on in step S1462, the role lottery result of this game and the operation of the stop switch 42 are accepted by the process corresponding to steps S1022 to S1023 of FIG. 194. The stop position of the reel 31 is determined based on the position of the reel 31 at the moment, and the symbol number corresponding to the determined stop position is stored in the reel symbol number (for the stop position). Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated.

By the interrupt process executed after the process of step S1465 (the process corresponding to steps S1022 to S1024 in FIG. 194 of the twenty-fifth embodiment), the reel symbol number (for the passing position) and the reel symbol number (for the stop position). When it is determined that and have the same value, the four-phase excitation output for stopping the motor 32 of the reel 31 is started.
When the reel symbol number (for passing position) and the reel symbol number (for stop position) have the same value, and the step number of one symbol on the reel 13 has a predetermined value (for example, "3") The four-phase excitation output for stopping the motor 32 of the reel 31 may be started.
In the step S1466, the main control board 50 updates the reel stop flag. Specifically, the bit of the reel stop flag (_FL_STOP_LP) corresponding to the reel 31 indicated by the A register value is updated (rewritten) to “0”. Then, the processing according to this flowchart is ended.

Here, it is assumed that all the reels 31 are rotating at a constant speed and that the operation of all the stop switches 42 can be accepted. At this time, the reel stop flag (_FL_STOP_LP) is “00000111 (B)”.
Under such a situation, it is assumed that the operations of the first (left) stop switch 42 and the second (middle) stop switch 42 are simultaneously accepted.

Here, both the D0 bit and the D1 bit of the input port level data A (_PT_IN_A_LV) (FIG. 133) at the time of the previous interrupt processing are “0”, and the input port level data A (_PT_IN_A_LV) at the time of the current interrupt processing. When both the D0 bit and the D1 bit of "1" are "1", "1" is stored in both the D0 bit and the D1 bit of the input port rising data A (_PT_IN_A_UP). Thereby, it is determined that the two operations of the first stop switch 42 and the second stop switch 42 are simultaneously accepted.
In this case, since the input port level data A (_PT_IN_A_LV) is "00000011 (B)", the A register value (input port rising data A (_PT_IN_A_UP)) and the B register value (reel stop flag (_FL_STOP_LP) are determined in step S1462. )) and the logical product (AND) operation is performed, the result becomes "00000011 (B)".

Further, when this "00000011 (B)" is added as an offset value to the reference address ("1100 (H)"), the result (specified address) becomes "1103 (H)".
The data corresponding to the address "1103(H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000001(B)", as shown in FIG. Since "00000001(B)" is data indicating that the stop control of the first (left) reel 31 is executed as described above, when the process proceeds to step S1465, the stop control of the first reel 31 is executed. To be done.

In this way, when the operations of the first stop switch 42 and the second stop switch 42 are simultaneously accepted under the condition that all reels 31 are rotating at a constant speed, the stop switch acceptance table (TBL_STOP_BTN) is used. Based on the information acquired as described above, the stop control of the first reel 31 corresponding to the first stop switch 42 is executed.

The first reel (left reel 31) stops, the second (middle) reel 31 and the third (right) reel 31 rotate at a constant speed, the second (middle) stop switch 42, and the third (right) reel switch 31. It is assumed that the operation of the stop switch 42 is acceptable. At this time, the reel stop flag (_FL_STOP_LP) is "00000110 (B)".

Under such circumstances, it is assumed that the operations of the first stop switch 42 and the second stop switch 42 are simultaneously accepted. In this case, since the input port rising data A (_PT_IN_A_UP) is "00000011 (B)", the A register value (input port rising data A (_PT_IN_A_UP)) and the B register value (reel stop flag (_FL_STOP_LP) are determined in step S1462. )) is performed, the result becomes "00000010 (B)".
Furthermore, when this "00000010 (B)" is added as an offset value to the reference address ("1100 (H)"), the result (specified address) becomes "1102 (H)".

The data corresponding to the address "1102(H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000010(B)" as shown in FIG. 259. As described above, "00000010(B)" is data indicating that the stop control of the second reel 31 is executed. Therefore, when the process proceeds to step S1465, the stop control of the second reel 31 is executed.
In this way, under the situation where the first reel 31 is stopped and the second reel 31 and the third reel 31 are rotating at a constant speed, the operations of the first stop switch 42 and the second stop switch 42 are simultaneously accepted. In this case, the stop control of the second reel 31 corresponding to the second stop switch 42 is executed based on the information acquired using the stop switch reception table (TBL_STOP_BTN).

Further, it is assumed that all the reels 31 are rotating at a constant speed and the operations of all the stop switches 42 can be accepted, and the operations of the first stop switch 42 and the third stop switch 42 are simultaneously accepted.
In this case, since the reel stop flag (_FL_STOP_LP) is "00000111 (B)" and the input port rising data A (_PT_IN_A_UP) is "00000101 (B)", the A register value (input port) is determined in step S1462. When the logical product (AND) operation of the rising data A (_PT_IN_A_UP) and the B register value (reel stop flag (_FL_STOP_LP)) is performed, the result is “00000101 (B)”.

Furthermore, when this “00000101 (B)” is added to the reference address (“1100 (H)”) as an offset value, the result (specified address) becomes “1105 (H)”.
Then, the data corresponding to the address "1105 (H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000001 (B)" as shown in FIG. 259, and the stop control of the first reel 31 is executed. Data indicating that the stop control of the first reel 31 is executed in step S1465.

Further, it is assumed that all the reels 31 are rotating at a constant speed and the operations of all the stop switches 42 can be accepted, and the operations of the second stop switch 42 and the third stop switch 42 are simultaneously accepted.
In this case, since the reel stop flag (_FL_STOP_LP) is “00000111 (B)” and the input port rising data A (_PT_IN_A_UP) is “00000110 (B)”, the A register value (input port) is determined in step S1462. When the logical product (AND) operation of the rising data A (_PT_IN_A_UP) and the B register value (reel stop flag (_FL_STOP_LP)) is performed, the result is “00000110 (B)”.

Further, when this "00000110 (B)" is added to the reference address ("1100 (H)") as an offset value, the result (specified address) becomes "1106 (H)".
Then, the data corresponding to the address "1106 (H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000010 (B)" as shown in FIG. 259, and the stop control of the second reel 31 should be executed. Data indicating that the stop control of the second reel 31 is executed in step S1465.

Further, it is assumed that all the reels 31 are rotating at a constant speed and the operations of all the stop switches 42 can be accepted, and the operations of all the stop switches 42 are simultaneously accepted.
In this case, since the reel stop flag (_FL_STOP_LP) is "00000111 (B)" and the input port rising data A (_PT_IN_A_UP) is also "00000111 (B)", the A register value (input port) is determined in step S1462. When the logical product (AND) operation of the rising data A (_PT_IN_A_UP) and the B register value (reel stop flag (_FL_STOP_LP)) is performed, the result is “00000111 (B)”.

Furthermore, when this "00000111 (B)" is added to the reference address ("1100 (H)") as an offset value, the result (specified address) becomes "1107 (H)".
Then, the data corresponding to the address "1107 (H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000001 (B)" as shown in FIG. 259, and the stop control of the first reel 31 is executed. Data indicating that the stop control of the first reel 31 is executed in step S1465.

In addition, the first reel stops, the second reel 31 and the third reel 31 rotate at a constant speed, and the first stop switch 42 is in a state in which the operation of the second stop switch 42 and the third stop switch 42 can be received. Also, it is assumed that the operations of the third stop switch 42 are simultaneously accepted.
In this case, since the reel stop flag (_FL_STOP_LP) is “00000110 (B)” and the input port rising data A (_PT_IN_A_UP) is “00000101 (B)”, the A register value (input port) in step S1462. When the logical product (AND) operation of the rising data A (_PT_IN_A_UP) and the B register value (reel stop flag (_FL_STOP_LP)) is performed, the result is “00000100(B)”.

Furthermore, when this "00000100(B)" is added to the reference address ("1100(H)") as an offset value, the result (specified address) becomes "1104(H)".
Then, the data corresponding to the address "1104 (H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000100 (B)" as shown in FIG. 259, and the stop control of the third reel 31 is executed. Data indicating that the stop control of the third reel 31 is executed in step S1465.

In addition, the first reel stops, the second reel 31 and the third reel 31 rotate at a constant speed, and the second stop switch 42 is in a state in which the operation of the second stop switch 42 and the third stop switch 42 can be accepted. Also, it is assumed that the operations of the third stop switch 42 are simultaneously accepted.
In this case, the reel stop flag (_FL_STOP_LP) is “00000110 (B)” and the input port rising data A (_PT_IN_A_UP) is also “00000110 (B)”. Therefore, in step S1462, the A register value (input port) When the logical product (AND) operation of the rising data A (_PT_IN_A_UP) and the B register value (reel stop flag (_FL_STOP_LP)) is performed, the result is “0000110 (B)”.

Further, when this "00000110 (B)" is added to the reference address ("1100 (H)") as an offset value, the result (specified address) becomes "1106 (H)".
Then, the data corresponding to the address "1106 (H)" in the stop switch acceptance table (TBL_STOP_BTN) is "00000010 (B)" as shown in FIG. 259, and the stop control of the second reel 31 should be executed. Data indicating that the stop control of the second reel 31 is executed in step S1465.

Here, the reel stop flag (_FL_STOP_LP) is "00000000(B)", "00000001(B)", "00000010(B)", "00000100(B)", "00000011(B)", "00000101(B)". )”, “00000110 (B)”, and “00000111 (B)”.
Also, regarding the input port rising data A (_PT_IN_A_UP), focusing on only the signals of the three stop switches 42, “00000000 (B)”, “00000001 (B)”, “00000010 (B)”, and “00000100 (B) )”, “00000011 (B)”, “00000101 (B)”, “00000110 (B)”, and “00000111 (B)”.

Therefore, the result of the logical product (AND) operation of the input port rising data A (_PT_IN_A_UP) and the reel stop flag (_FL_STOP_LP) is also “00000000(B)”, “00000001(B)”, “00000010(B)”. , "00000100 (B)", "00000011 (B)", "00000101 (B)", "00000110 (B)", and "00000111 (B)".

Then, when the result of the logical product operation is “00000000(B)”, the result is “No” in step S1462, and the processing in step S1463 and subsequent steps is not performed, so that the reference address (“1100(H)”) is set. The offset value to be added is any one of “1(D)” to “7(D)”.
Therefore, no matter what the driving state of each reel 31 is and what combination of the plurality of stop switches 42 is simultaneously operated, based on the information acquired by using the stop switch reception table (TBL_STOP_BTN), The stop control of any one reel 31 can be appropriately executed.

<36th Embodiment>
In the 36th embodiment, the stop switch 42 corresponding to the first (any one) reel 31 is operated at the first timing, and then at the second timing before the first reel 31 is stopped. When the stop switch 42 corresponding to the second (other than the first) reel 31 is operated, the first reel 31 may be stopped after the second reel 31 is stopped. ..

Further, the symbol array of the reel 31, the effective line, the type of winning combination, the symbol combination of winning combinations, the number of payouts, the condition device, the winning combination, the RT, and the main game state are the same as in the 23rd embodiment.
Then, as a result of the first reel 31 stopping after the second reel 31 stops, the symbols constituting a specific symbol combination (for example, "blue BAR"-"blue BAR"-"blue BAR") are on a straight line. When it is stopped and displayed, a predetermined effect (for example, a tempo sound) can be output according to the timing when the first reel 31 stops.

261 to 263 are schematic diagrams showing the relationship between the operation sequence of the stop switch 42, the reel 31 stop sequence, the symbol stop display, and the tempo sound output in the thirty-sixth embodiment.
In the present embodiment, after the operation of any one of the stop switches 42 is accepted, before a predetermined period of performing the four-phase excitation output to the motor 32 of the reel 31 corresponding to the stop switch 42 elapses (for example, four-phase excitation). At the output timing or before the 4-phase excitation output), the operation of the other stop switch 42 is accepted and the 4-phase excitation output is supplied to the motor 32 of the reel 31 corresponding to the other stop switch 42. It is configured to be executable.
Therefore, in this embodiment, the operation order of the stop switch 42 and the stop order of the reel 31 may be interchanged.

For example, the winning lottery means 61 wins the winning number "25", the 1BB condition device corresponding to the winning number "25" is activated, and the "blue BAR"-"blue BAR"-"blue BAR" corresponding to 1BB. In the game in which the symbol combination can be stopped and displayed on the activated line, as shown in FIGS. 261(a) to 261(c), when the three reels 31 are rotating at a constant speed, the left stop switch 42, It is assumed that these are quickly operated in the order of the middle stop switch 42. It is also assumed that the operation of the left stop switch 42 is first accepted, and then the operation of the middle stop switch 42 is accepted before the left reel 31 is stopped. At this time, the number of moving symbols (number of sliding frames) from when the operation of the left stop switch 42 is received until the left reel 31 is stopped is set to “4”, and after the operation of the middle stop switch 42 is received It is assumed that the number of moving symbols until the reel 31 stops is set to "0". In such a case, the middle reel 31 may stop first, and then the left reel 31 may stop.

Further, when the middle reel 31 is stopped first, as shown in FIG. 261(b), “blue BAR” is stopped and displayed in the middle stage, and when the left reel 31 is stopped thereafter, FIG. 261(c) is displayed. As shown in, it is assumed that "blue BAR" is stopped and displayed on the upper stage. That is, it is assumed that the symbols forming the symbol combination of "blue BAR"-"blue BAR"-"blue BAR" are stopped and displayed on the straight line of the straight line descending to the right.

Here, when the two reels 31 are stopped and the remaining one reel 31 is rotating, the symbols constituting the symbol combination corresponding to the winning combination are stopped and displayed on the activated line, and the remaining one reel 31 When the symbols that form the symbol combination corresponding to the winning combination are stopped and displayed on the activated line when is stopped, the situation in which the symbol combination corresponding to the winning combination is stopped and displayed is called "tempai". .. That is, when two reels 31 are stopped, a part of the symbol combination corresponding to the winning combination is stopped and displayed on the activated line, which is called a tempai.
In the case of having four reels 31, when three reels 31 are stopped, a part of the symbol combination corresponding to the winning combination is stopped and displayed on the activated line, which is called a tempai. That is, in the case of having N reels 31, when N-1 reels 31 are stopped, a part of the symbol combination corresponding to the winning combination is stopped and displayed on the activated line, which is called a tempai.

Then, as shown in FIG. 261(c), as a result of the left reel 31 stopping after the middle reel 31 stops, the symbols constituting the symbol combination of "blue BAR"-"blue BAR"-"blue BAR" are right. When it is stopped and displayed on the downward effective line, the middle reel 31 is not stopped, but according to the timing when the left reel 31 is stopped. A tempai sound, which is a sound effect peculiar to tempai, is output. That is, the tempo sound is output based on the stop order of the reels 31 instead of the operation order of the stop switch 42.

For example, the winning lottery means 61 wins the winning number "25", the 1BB condition device corresponding to the winning number "25" is activated, and the "blue BAR"-"blue BAR"-"blue BAR" corresponding to 1BB. In the game in which the symbol combination can be stopped and displayed on the activated line, only when the left stop switch 42 is first operated, it is assumed that "blue BAR" is set to be stopped and displayed on the upper stage of the left reel 31. ..
In this case, when the "blue BAR" is stopped and displayed on the upper stage of the left reel 31 when the left reel 31 is first stopped, the player selects "blue BAR"-"blue BAR"-"blue BAR". It can be recognized that the condition device corresponding to the symbol combination is operating.

Furthermore, in the present embodiment, when "blue BAR" is stopped and displayed on the upper stage of the left reel 31 when the left reel 31 is first stopped, "blue BAR"-"blue BAR"-"blue BAR". The definite production indicating that the condition device corresponding to the symbol combination is operating (for example, production for outputting a voice such as "Ichikuu~" or "Congratulations") is executed.
However, in the game in which the condition device corresponding to the symbol combination of “blue BAR”-“blue BAR”-“blue BAR” is operating, as shown in FIGS. 261(a) to 261(c), the left stop switch 42 When the middle reel 31 and the left reel 31 are stopped in this order even though the middle stop switch 42 is operated in this order, even if "blue BAR" is stopped and displayed on the upper stage of the left reel 31, the final effect is displayed. Do not execute.

Further, in the present embodiment, when the symbols constituting the specific symbol combination are stopped and displayed on the straight line invalid line, the same effect sound as that at the time of tempo is output.
For example, in the game in which the winning number “2” is won by the role lottery means 61, the replay B condition device corresponding to the winning number “2” is activated, and either the replay 01 or 02 becomes a winning prize, FIG. 262 As shown in (a) to (c), when the three reels 31 are rotating at a constant speed, it is assumed that the left stop switch 42 and the middle stop switch 42 are quickly operated in this order. Then, the left stop switch 42 is operated at the first timing (the number of moving symbols of the left reel 31 is set to "4"), and the middle stop switch 42 is operated at the second timing (movement of the middle reel 31. The number of symbols is set to "1").

Further, when the middle reel 31 is stopped first, as shown in FIG. 262(b), “replay” is stopped and displayed in the middle stage, and “blue BAR” is stopped and displayed in the lower stage, and then the left reel is stopped. When 31 is stopped, as shown in FIG. 262(c), "replay" is stopped and displayed on the upper stage, and "blue BAR" is stopped and displayed on the lower stage. That is, it is assumed that the symbols forming the symbol combination of “blue BAR”-“blue BAR”-“blue BAR” are stopped and displayed on the straight line invalid line in the lower stage. In such a case, the same sound effect as that at the time of tempo is output according to the timing when the left reel 31 stops instead of the timing when the middle reel 31 stops.

For example, in the game in which the winning number “2” is won by the role lottery means 61, the replay B condition device corresponding to the winning number “2” is activated, and either the replay 01 or 02 becomes a winning prize, FIG. 263 As shown in (a) to (d), when the three reels 31 are rotating at a constant speed, the left stop switch 42, the middle stop switch 42, and the right stop switch 42 are quickly operated in this order. Suppose Then, the left stop switch 42 is operated at the first timing (the number of moving symbols of the left reel 31 is set to "4"), and the middle stop switch 42 is operated at the second timing (moving symbol of the middle reel 31). It is assumed that the number is set to "1" and the right stop switch 42 is operated at the third timing (the number of moving symbols on the right reel 31 is set to "0"). In such a case, the middle reel 31 may stop first, the right reel 31 may stop second, and the left reel 31 may stop finally.

Further, when the middle reel 31 is stopped for the first time, as shown in FIG. 263(b), “replay” is stopped and displayed in the middle stage, and “blue BAR” is stopped and displayed in the lower stage, and the second right is displayed. When the reel 31 is stopped, as shown in FIG. 263(c), "replay" is stopped and displayed in the lower stage, "blue BAR" is stopped and displayed in the middle stage, and the left reel 31 is stopped finally. In addition, as shown in FIG. 263(d), it is assumed that "replay" is stopped and displayed on the upper stage and "blue BAR" is stopped and displayed on the lower stage.

In the example shown in FIGS. 263(a) to 263(d), since "blue BAR" is stopped and displayed on the lower stage of the left reel 31 and the lower stage of the middle reel 31, the left reel is the same as the operation order of the stop switch 42. If the middle reel 31, the middle reel 31, and the right reel 31 are stopped in this order, at the time when the middle reel 31 is stopped, the same sound effect as that at the time of tempo is output.
However, unlike the operation order of the stop switch 42, when the reels 31 stop in the order of the middle reel 31, the right reel 31, and the left reel 31, the "blue BAR"-"blue BAR" is reached when the right reel 31 stops second. Since the symbols constituting the symbol combination of "-"blue BAR" are not stopped and displayed on the straight invalid line, the same effect sound as that at the time of tempo is not output.

FIG. 264 is a flowchart showing the main processing (M_MAIN) in the 36th embodiment, and is a flowchart corresponding to FIG. 139 of the 23rd embodiment.
In the flowchart of the 36th embodiment shown in FIG. 264, steps different from those in FIG. 139 are underlined in step numbers, and steps identical to those in FIG. 139 are identical in step number.

Also, in the main process (M_MAIN) of the 36th embodiment, the processes of steps S295 to S300 of FIG. 139 are executed, but in FIG. 264, the processes of steps S295 to S300 are omitted.
Hereinafter, differences from FIG. 139 will be mainly described.

As shown in FIG. 264, in the thirty-sixth embodiment, after the start switch acceptance process (M_START_CTL) of step S751 is executed, the process proceeds to step S1471.
In step S1471, the main control board 50 determines whether or not there is stop acceptance. That is, it is determined whether the operation of any of the first stop switch 42 to the third stop switch 42 has been accepted.

Specifically, the main control board 50 uses the D0 bit (left stop switch signal), D1 bit (middle stop switch signal), D2 of the input port rising data A (_PT_IN_A_UP) of the address “F017(H)” in FIG. 133. It is determined whether any of the bits (right stop switch signal) is on. If it is determined that the operation of any of the stop switches 42 has been accepted, the process advances to step S1472. On the other hand, when it is determined that the operation of any of the stop switches 42 has not been accepted, steps S1472 and S1473 are skipped and the process proceeds to step S1474.

When the processing proceeds to step S1472, the main control board 50 executes the processing at the time of stop acceptance. In this processing, the stop position of the reel 31 is determined based on the winning combination lottery result and the position of the reel 31 at the moment when the operation of the stop switch 42 is accepted, and the symbol number corresponding to the determined stop position is set to the reel. Set to the symbol number (for stop position) (FIGS. 135 to 137). Further, the stop symbol data for determining the symbol combination to be stopped on the activated line is updated.

More specifically, in the process at the time of stop acceptance in step S1472 of FIG. 264, the process corresponding to steps S1022 to S1024 in FIG. 194 of the 25th embodiment is executed. That is, with respect to the reel 31 corresponding to the stop switch 42 determined to be ON in step S1471, the winning lottery result of this game and the operation of the stop switch 42 are accepted by the process corresponding to steps S1022 to S1023 of FIG. 194. The stop position of the reel 31 is determined based on the position of the reel 31 at the moment, and the symbol number corresponding to the determined stop position is stored in the reel symbol number (for the stop position). Further, by the process corresponding to the stop symbol set (M_STOPPIC_SET) in step S1024 of FIG. 194, the stop symbol data (_WK_STOP_PIC1 to 9) for determining the symbol combination to be stopped on the activated line is updated.

By the interrupt processing executed after the processing of step S1472 (processing corresponding to steps S1022 to S1024 of FIG. 194), the reel symbol number (for the passing position) and the reel symbol number (for the stop position) become the same value. If it is determined that the four-phase excitation output for stopping the motor 32 of the reel 31 is started.
Further, the reel symbol number (for passing position) and the reel symbol number (for stop position) have the same value, and the step number of one symbol on the reel 13 has a predetermined value (for example, "3"). At some times, four-phase excitation output for stopping the motor 32 of the reel 31 may be started.

Then, when the process at the time of stop acceptance in step S1472 is executed, the process proceeds to step S1473, and the main control board 50 sets a stop accept command indicating that the operation of the stop switch 42 is accepted in the command buffer.
Here, the stop acceptance command may include, for example, information indicating which operation of the stop switch 42 is accepted and information indicating the position of the reel 31 at the moment when the operation of the stop switch 42 is accepted. The information includes information indicating which operation of the stop switch 42 has been accepted, and information capable of determining the stop position of the reel 31 at which the operation of the stop switch 42 has been accepted.
The stop acceptance command set in the command buffer is transmitted to the sub-control board 80 by the interrupt process executed after the process of step S1472.

When the stop acceptance command setting process of step S1473 is executed, the process proceeds to step S1474, and the main control board 50 determines whether or not the four-phase excitation output for stopping the motor 32 of the reel 31 is started. .. Here, when it is determined that the four-phase excitation output has been started for the motor 32 of any one of the reels 31, the process proceeds to the next step S1475. On the other hand, when it is determined that the four-phase excitation output has not been started for any of the motors 32 of the reels 31, step S1475 is skipped and the process proceeds to step S1476.

In step S1475, the main control board 50 sets, in the command buffer, a stop command indicating that the four-phase excitation output for stopping the motor 32 of the reel 31 has started.
Here, the stop command includes information indicating which of the motors 32 of the reel 31 the four-phase excitation output has started.
The stop command set in the command buffer is transmitted to the sub-control board 80 by the interrupt process executed after the process of step S1475.

In step S1476, the main control board 50 determines whether all reels 31 have stopped.
When it is determined in step S1476 that at least one reel 31 is not stopped, the process returns to step S1471. In this case, the processing from step S1471 onward is repeated.
On the other hand, if it is determined in step S1476 that all reels 31 have stopped, the process proceeds to the display determination in step S291.

Here, when the winning number is selected by the winning lottery means 61 and the condition device corresponding to the determined winning number operates, the main control board 50 sends a condition device command corresponding to the operated condition device to the sub control board 80. Send to. Accordingly, the sub control board 80 can determine which condition device has operated.
Further, in the example shown in FIGS. 261(a) to 261(c), the main control board 50 first transmits to the sub control board 80 a stop acceptance command indicating that the operation of the left stop switch 42 has been accepted. Then, a stop acceptance command indicating that the operation of the middle stop switch 42 is accepted is transmitted, then a stop command indicating that the middle reel 31 is stopped is transmitted, and finally, the left reel 31 is stopped. A stop command indicating that the operation is to be performed is transmitted.

Furthermore, when the sub control board 80 receives the stop acceptance command from the main control board 50, it can determine which reel 31 will stop at which position based on the condition device command and the stop acceptance command. .. Thereby, for example, it is determined that the "blue BAR" of the left reel 31 is stopped and displayed in the upper stage, and that the symbols constituting the symbol combination of "blue BAR"-"blue BAR"-"blue BAR" are tempted. can do.

Further, upon receiving the stop command from the main control board 50, the sub control board 80 can determine the stop order and stop timing of each reel 31.
Then, the sub-control board 80 outputs the tempo sound based on the stop position of each reel 31 determined from the condition device command and the stop acceptance command, and the stop order and stop timing of each reel 31 determined from the stop command. , It is possible to output the same sound effect as in tempai.

In the example illustrated in FIGS. 261(a) to 261(c), the sub control board 80 determines the stop timing of the left reel 31 based on a stop command indicating that the left reel 31 is stopped, A tempai sound is output at the stop timing.
Thereby, even if the operation order of the stop switch 42 and the stop order of the reels 31 are different, it is possible to output a tempai sound or a sound effect similar to the tempo sound at an appropriate timing that does not give the player a feeling of strangeness.

Further, in the example shown in FIGS. 263(a) to 263(c), a stop acceptance command indicating that the operation of the left stop switch 42 has been accepted is first transmitted from the main control board 50 to the sub control board 80. Then, a stop acceptance command indicating that the operation of the middle stop switch 42 has been accepted is transmitted, and then a stop acceptance command indicating that the operation of the right stop switch 42 has been accepted is transmitted. Next, a stop command indicating that the middle reel 31 is stopped is transmitted, then a stop command indicating that the right reel 31 is stopped is transmitted, and finally, a stop command indicating that the left reel 31 is stopped. Will be sent.

Further, the sub control board 80 determines that "blue BAR" of the right reel 31 is stopped and displayed in the middle stage based on the stop acceptance command indicating that the operation of the right stop switch 42 has been accepted, and then the right control Based on the stop command indicating that the reel 31 will stop, it is determined that the right reel 31 will stop second.
Then, the sub-control board 80 determines that the two “blue BARs” are not aligned in a straight invalid line at the time when the right reel 31 is stopped, and does not output the same sound effect as in the tempo. You can

Here, in the example illustrated in FIGS. 263(a) to 263(d), “blue BAR” is stopped and displayed on the lower stage of the left reel 31 and the lower stage of the middle reel 31.
Therefore, if the reels 31 are stopped in the same order as the operation sequence of the stop switch 42, that is, the left reel 31, the middle reel 31, and the right reel 31, when the middle reel 31 is stopped, "blue BAR" is in the lower stage. It will be stopped and displayed on a straight invalid line.
However, in the example shown in FIGS. 263(a) to 263(d), since the middle reel 31 is stopped first, if the same sound effect as that at the time of tempo is output at this point, the player feels strange.

Further, in the example shown in FIGS. 263(a) to 263(d), the second reel is stopped at the right reel 31, and it is determined that two "blue BARs" are not aligned in a straight invalid line at this time. Therefore, outputting a sound effect similar to that at the time of tempai makes the player feel uncomfortable.
Then, in the present embodiment, the sub-control board 80 determines that the reels 31 stop in the order of the middle reel 31, the right reel 31, and the left reel 31 based on the stop command of each reel 31, and determines the middle reel 31 first. At the time of stopping, or at the time of the second right reel 31 stopping, it is judged that two "blue BARs" are not aligned on a straight invalid line, and the same sound effect as at the time of tempai is not output. , It is possible to prevent the player from feeling uncomfortable.

Further, as described in the first embodiment, in the slot machine 10 that controls and manages the AT on the main control board 50 side, the main control board 50 sends the winning number and the condition device command to the sub control board 80. Send the production group number without sending.
In this case, the stop position of the reel 31 cannot be determined from the effect group number and the information indicating the position of the reel 31 at the moment when the operation of the stop switch 42 is accepted.

Therefore, in the slot machine 10 that controls and manages the AT on the main control board 50 side, the main control board 50 informs the sub control board 80 of information indicating which stop switch 42 operation has been accepted, and the stop control. A stop acceptance command including information capable of determining the stop position of the reel 31 for which the operation of the switch 42 has been accepted is transmitted.
Then, the sub-control board 80 can determine which reel 31 will stop at which position based on the information that can be used to determine the stop position of the reel 31 included in the received stop acceptance command. Thereby, for example, it is determined that the "blue BAR" of the left reel 31 is stopped and displayed in the upper stage, and that the symbols constituting the symbol combination of "blue BAR"-"blue BAR"-"blue BAR" are tempted. can do.

The 36th embodiment of the present invention has been described above, but the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the above-described embodiment, the sub-control board 80 determines the stop order and stop timing of each reel 31 based on the stop command received from the main control board 50, and determines the tempo sound or the tempo sound at an appropriate timing. The same sound effect was output.

However, the present invention is not limited to this. For example, the stop position, the stop order, and the stop timing of each reel 31 may be determined based on the condition device command and the stop acceptance command received from the main control board 50. Then, based on the stop position, the stop order, and the stop timing of each reel 31 determined from the condition device command and the stop acceptance command, a tempo sound or a sound effect similar to that at the time of tempo may be output.
In this case, the stop command for each reel 31 may not be transmitted from the main control board 50 to the sub control board 80.

(2) In the above embodiment, when the reel 31 and the motor 32 are stopped, the four-phase excitation output is performed to the motor 32 (stepping motor), but the present invention is not limited to this.
When the reel 31 and the motor 32 are stopped, for example, one-phase excitation output may be performed, two-phase excitation output may be performed, or three-phase excitation output may be performed. In addition, first, two-phase excitation output is performed to weaken the brake, then the two-phase excitation output is switched to the four-phase excitation output, and the stronger brake is applied to stop the rotation of the reel 31 and the motor 32. It may be allowed to.

(3) Although the three reels 31 are provided in the twenty-ninth to thirty-sixth embodiments, the number of reels 31 is not limited to three, and may be four or more, for example.
(4) In the twenty-ninth to thirty-sixth embodiments, the slot machine 10 is given as an example of the gaming machine, but the gaming machine is not limited to this. For example, the present invention can be applied to a parrot that uses a game ball as a game medium, an enclosed gaming machine (medalless gaming machine) that uses electronic information (electronic medal) without using a physical (as a physical object) medal, and a casino machine. The invention can be applied.
(5) The various modifications shown in the first to thirty-sixth embodiments and the first to thirty-sixth embodiments are not limited to being carried out alone, but may be carried out in an appropriate combination.

<Appendix>
The inventions (original inventions) described in the initial description of the present application can include, for example, the following original inventions 1 to 54, respectively, in order to solve the problems to be solved by the original invention and the problems related to the original invention. The means and effects of the original invention are as follows. However, the invention described in this specification does not mean that the inventions 1 to 54 are initially limited.

1. Original invention 1
(A) Problem to be Solved by Initial Invention 1 The initial invention relates to a gaming machine in which a process related to a game medium is not executed after a power failure occurs.
In the conventional gaming machine, by turning off the blocker before executing the backup process as the power-off process, even if a medal is inserted during the backup process, the medal is returned to the player via the blocker. Therefore, a technique is known in which the medal addition process is not performed (for example, Japanese Patent Laid-Open No. 2005-173832).
However, for example, if the power is cut off at the moment when a medal is inserted from the medal insertion slot, the medal will pass through the blocker before the power-off process is executed, and the medal will be counted. There was a possibility. In addition, it is not preferable in terms of control to execute the medal addition process (medal bet process or medal credit process) after the power is cut off.
Initially, the problem to be solved by the invention is to prevent the addition processing of the game medium from being executed even when the power is cut off at the same time as when the game medium is inserted from the game medium insertion slot. ..

(B) Means for solving the problem of invention 1 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (first embodiment (A)) is
A game medium slot (medal slot 47),
It is provided in the passage (medal passage) of the game medium (medal) inserted from the game medium insertion port, and the state of permitting the passage of the game medium (ON state) or the state of disallowing the passage of the game medium (OFF state) ) Controllable blocker (45),
Detecting means A (insertion sensor 44a) and B (insertion sensor 44b) (detection means B provided downstream of the detection means A provided in the passage of the game medium input from the game medium input port and capable of detecting the game medium) And located at
From the time when the power supply is cut off in the situation where the blocker is controlled to allow the passage of the game medium, the power supply is cut off to detect the game medium. Let T1 (T1 in FIGS. 2 and 3) be the time until the blocker is controlled in a state where passage is not permitted,
When the game medium is released from the game medium slot into the game machine while the blocker is controlled to allow passage of the game medium, the game medium is not visible from the front of the game machine. From when it becomes possible (the position of M2 in FIG. 2) until the detection means B detects the game medium and the detection means B stops detecting the game medium (the position of M4 in FIG. 2). When the time is T2 (T2 in FIGS. 2 and 3),
T1<T2
It is characterized in that

(C) Effects of the first invention According to the first invention, the power supply is cut off when the game medium is released from the game medium slot toward the inside of the game machine and the game medium becomes invisible from the front of the game machine. In such a case, the blocker is controlled to a state in which the passage of the game medium is prohibited by detecting an event that the power supply is cut off by the time the detecting unit B stops detecting the game medium, so that the game medium is At least, it is not detected by the detecting means B.
Therefore, since the game medium is not normally detected by the detection means A and B, the addition process (bet process or credit process) of the game medium is not executed. Therefore, even if the power is cut off when the game medium becomes invisible from the front of the game machine, that is, even if the power is cut off immediately after the game medium is released inside the game machine, the game is stopped. You can choose not to accept the medium. As a result, it is possible to prevent the addition processing of the game medium from being executed after the power is cut off.

2. Initial invention 2
(A) Problem to be Solved by Initial Invention 2 The initial invention relates to a gate mark of a board case in a gaming machine including a board case that accommodates a control board therein.
In a conventional gaming machine, a board case in which a main control board is housed is known. Here, since the substrate case is generally formed by molding, a gate mark remains on the substrate case. Then, a technique in which this gate mark is used as a mark has been proposed (for example, Japanese Patent Laid-Open No. 2017-042270).
However, since the gate mark on the substrate case has a resin cut portion, it is unclear from the outside. Therefore, there is a problem that the gate trace may be opened and the inside of the main control board may be accessed.
Initially, the problem to be solved by the invention is to suppress the goto action using the gate mark of the substrate case.

(B) Means for solving the problem of the first invention 2 (Note that the corresponding embodiment is described in parentheses.)
The original invention (second embodiment) is
A predetermined IC (main CPU 55) having an arithmetic function,
A control board (main control board 50) having the predetermined IC mounted on one surface (a surface facing the upper surface of the upper cover 57);
A board case (a board case 56 including an upper cover 57 and a lower cover 58) having a plurality of surfaces (upper surface, side surface, etc.) and accommodating the control board;
The substrate case is formed so that the inside can be visually confirmed,
A gate trace (57b) at the time of molding of the substrate case is arranged on the surface outside the substrate case and facing the one surface of the control substrate (outer upper surface of the upper cover 57),
It is characterized in that the predetermined IC of the control substrate is not located in the direction perpendicular to the facing surface from the gate trace.

(C) Effect of Initial Invention 2 According to the initial invention, since the predetermined IC of the control board is not positioned in the vertical direction of the gate mark on the substrate case, the gate mark is illegally opened to access the predetermined IC. It can be prevented.
Further, since the gate mark of the substrate case does not exist in the vertical direction of the predetermined IC on the control board, the predetermined IC can be visually confirmed without being blocked by the gate mark. As a result, it is possible to easily visually confirm whether or not a given IC has been tampered with.

3. Initial invention 3
(A) Problem to be Solved by Initial Invention 3 The initial invention relates to a process when communication is restored from a disconnection in the communication between the main control board and the sub-control board.
In a conventional gaming machine, a gaming machine is known in which a command is transmitted from a main control board to a sub control board, and the sub control board controls an image display device or the like based on the received command.
Here, there is known a technique in which the sub control board compares a command received last time with a command received this time, and judges that the command reception is abnormal based on the consistency of the received commands (for example, a special command). Open 2014-226503).
However, when a command is transmitted from the main control board to the sub control board, disconnection may occur between the main control board and the sub control board. Then, when communication is restored, the sub control board may not be able to output a normal effect.
Initially, the problem to be solved by the invention is to make an appropriate effect when communication is restored after a disconnection occurs between the main control board and the sub control board.

(B) Means for Solving the Problem of Original Invention 3 (Note that the corresponding embodiment is described in parentheses.)
The original invention (third embodiment) is
A main control board (50),
A sub control board (80) for controlling the effect based on the information received from the main control board,
The sub control board can receive information of the operated stop switch (42) from the main control board,
In a predetermined game state (AT), the sub-control board can output an effect corresponding to the operation of the stop switch based on the reception of the information of the operated stop switch,
The sub control board,
When the predetermined stop switch is operated in the "N" game in the predetermined game state, when the information that the predetermined stop switch is operated is received, a predetermined operation corresponding to the operation of the predetermined stop switch is received. Outputs the effect (effect when the reel corresponding to the predetermined stop switch is stopped), and then becomes unable to receive the information from the main control board before all the remaining stop switches in the "N" game are operated. , After that, the information from the main control board can be received in the "N+a" game, and then, in the "N+a" game, the information that a specific stop switch different from the predetermined stop switch is operated is received. At this time, an effect corresponding to the operation of the specific stop switch and an effect related to the predetermined effect (an effect subsequent to the predetermined effect, when the reel corresponding to the specific stop switch is stopped) is output. Then, after that, when the predetermined information is received in the "N+a+1" game, the production of the "N+a+1" game is output based on the predetermined information.

(C) Effect of Initial Invention 3 According to the initial invention, when communication is restored in the middle of the “N+a” game, an effect related to the predetermined effect of the “N” game that has been output until then is output. Therefore, in the "N+a" game, the effect following the "N" game can be output. Then, when the game shifts to the "N+a+1" game, the normal effect is restored, so that it is possible to prevent the effect from suddenly changing due to the return of communication in the middle of the "N+a" game. As a result, it is possible to output an effect without a sense of discomfort before and after the occurrence of the disconnection.

4. Original invention 4
(A) Problem to be Solved by Initial Invention 4 The initial invention relates to a gaming machine capable of operating a stop switch at high speed.
In the conventional gaming machine, when the stop switch is operated, the reel corresponding to the stop switch is stopped at a predetermined position corresponding to the lottery result. Also, after stopping the reel at a predetermined position, the motor is energized for a predetermined time. Here, when the operated stop switch is in the ON state or when the motor is in the excitation state, the operation of the next stop switch is not accepted.
Here, a technique is known in which, even after the first stop switch is operated until the reel status is stopped, the stop operation is not accepted even if the second stop switch is operated ( See, for example, JP-A-2017-093576).
However, in the above-described conventional technique, if the time until the next operation of the stop switch becomes acceptable after the stop switch is operated, there is a problem that the game cannot be digested at high speed.
Initially, the problem to be solved by the invention is to make it possible to operate the stop switch at high speed.

(B) Means for Solving the Problem of Original Invention 4 (Note that the corresponding embodiment is described in parentheses.)
The original invention (fourth embodiment) is
Reel (31),
A motor (32) for rotating the reel,
Reel control means (65) for driving and controlling the motor to stop the rotation of the reel based on detection of operation of a stop button (stop button 42a);
With internal drawing means (role drawing means 61),
A sensor (detection sensor 42e) that detects the operation of the stop button is turned on until the stop button is pushed to the deepest part (the position shown in FIG. 12C), and when the push of the stop button is released, the stop button is released. The button is configured to be movable to an initial position (the position shown in FIG. 12A) by a biasing force, and the sensor is turned off before the stop button moves to the initial position.
In the game in which the internal drawing means determines a predetermined result, the stop button is operated for a predetermined reel at a predetermined timing under the condition that all reels are rotated by the reel control means, After detecting the ON state of the sensor of the stop button for the reel, the excited state (four-phase excited state) for stopping the predetermined reel is set, and a predetermined time (T12 in FIG. 13) elapses from the excited state. Is configured to end the excitation state,
When the time from the moment when the stop button is released to the deepest part to the time when the sensor is turned off is T1 (T11 in FIG. 13) and the predetermined time is T2,
T1<T2
It is characterized in that

(C) Effect of Initial Invention 4 According to the initial invention, it is assumed that the start of the motor excitation state when the reel is stopped and the moment when the stop button pushed to the deepest portion is released. Sometimes the excitation state ends after the sensor is turned off. Therefore, the next operation of the stop button can be accepted at the timing when the motor excitation state is completed.

5. Original invention 5
(A) Problem to be Solved by Initial Invention 5 The initial invention relates to control of the medal payout device.
It is known that, in a conventional gaming machine, it takes about 100 ms to pay out one medal (for example, Japanese Patent Laid-Open No. 2016-214434).
Here, a DC motor (direct current motor) is used as a hopper motor for rotating the hopper disk, and the DC motor gradually accelerates from the state where the rotation of the drive shaft is stopped when a constant current is applied. Then, it reaches a certain speed (constant speed).
For this reason, the rotation of the drive shaft of the hopper motor gradually accelerates from the start of driving the hopper motor until the first medal is ejected. The required time becomes longer than the medal ejection interval when the drive shaft of the hopper motor is rotating at a constant speed, which may give the player a feeling that the ejection of the first medal has been delayed.
The problem to be solved by the first invention is to prevent the player from feeling that the discharge of the first medal is delayed.

(B) Means for solving the problem of the first invention 5 (Note that the corresponding embodiment is described in parentheses.)
The original invention (sixth embodiment) is
A hopper (35) for storing medals,
A hopper disc (101) provided in the hopper,
A hopper motor (36) for rotating the hopper disc,
A control means (main control board 50) for controlling the drive of the hopper motor,
The hopper disc is provided with a plurality of holding parts (102) capable of holding the medals stored in the hopper along the outer periphery of the hopper disc (eight).
When the hopper motor is driven to rotate the hopper disc, the medals held in the holding portion are sequentially discharged from the discharging portion (103),
The position of the holding unit that was holding the last ejected medal at the moment when the last ejected medal in the one payout process was ejected from the ejecting unit is the first position,
At the moment when the last ejected medal in the one payout process is ejected from the ejecting unit, the position of the holding unit that holds the first ejected medal in the next payout process is a second position,
When the control means finishes the one payout process, the holding part in which the first ejected medal in the next payout process is held is located between the first position and the second position. Then, the drive of the hopper motor is controlled so that the rotation of the hopper disk is stopped.

(C) Effect of Initial Invention 5 According to the initial invention, when the holding unit that holds the first ejected medal stops between the first position and the second position, it reaches the first position. The distance is shorter than when stopped in the second position. As a result, the time required to reach the first position is shorter than when the vehicle stops at the second position, so that even if the rotation of the drive shaft of the hopper motor is gradually accelerated, the ejection of the first medal is delayed. It is possible to prevent the player from feeling.

6. Original invention 6
(A) Problem to be Solved by Initial Invention 6 The initial invention relates to the arrangement of the main control board mounted inside the cabinet and the sub-control board mounted on the back surface of the front door.
It is known that a conventional gaming machine is provided with an electrolytic capacitor for storing electricity on a sub-control board for controlling an effect (for example, JP-A-2014-131656).
Here, the electrolytic capacitor for storage of electricity is filled with the electrolytic solution, but the electrolytic capacitor bursts due to a malfunction, and the filled electrolytic solution is scattered and adheres to the main CPU on the main control board. The main CPU may malfunction. In addition, the main CPU may be damaged by the shock when the electrolytic capacitor bursts.
Initially, the problem to be solved by the invention is to prevent the main CPU from malfunctioning even if the electrolytic capacitor is ruptured due to a malfunction and the electrolytic solution is scattered. Further, even if the electrolytic capacitor bursts due to a malfunction, the main CPU is not damaged by the impact at that time.

(B) Means for solving the problem of Invention 6 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (seventh embodiment) is
A cabinet (13),
A front door (12) attached to the cabinet so as to be openable and closable,
A main control board (50) for controlling the progress of the game,
And a sub-control board (80) for controlling production,
The main control board is mounted inside the cabinet,
The sub-control board is attached to the back surface of the front door,
The main control board and the sub control board are arranged so as to face each other when the front door is closed,
A main CPU (55) is arranged on the main control board,
The electrolytic capacitor (86) is arranged at a position other than the position facing the main CPU on the sub-control board.

(C) Effect of Initial Invention 6 According to the initial invention, since the electrolytic capacitor is arranged at a position other than the position facing the main CPU on the sub-control board, the electrolytic capacitor ruptures due to a defect and the electrolytic solution is discharged. Even if is scattered, it is possible to prevent the scattered electrolytic solution from adhering to the main CPU, thereby preventing the main CPU from malfunctioning.
Further, even if the electrolytic capacitor bursts, it is possible to prevent the main CPU from being directly affected by the impact, and thus it is possible to prevent the main CPU from being damaged.

7. Original invention 7
(A) Problem to be Solved by Initial Invention 7 The initial invention relates to reel stop control on the main control board side and production output control on the sub control board side.
In a conventional gaming machine, it is possible to execute a plurality of types of effect contents, and each effect content when a special part is won (inside) and when no special part is won (not inside) Are known with different selection probabilities (for example, Japanese Patent Laid-Open No. 2013-146608).
However, in the above-mentioned conventional gaming machine, the effect contents are selected regardless of the drawing result of the internal drawing, whether inside or outside.
Initially, the problem to be solved by the invention is to appropriately determine the effect to be output according to the drawing result of the internal drawing.

(B) Means for solving the problem of Invention 7 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (the ninth embodiment) is
A plurality of reels (31) displaying a plurality of symbols,
A plurality of stop switches (42) operated by the player when stopping each reel,
Main control means (main control board 50) for controlling the progress of the game,
And a sub-control means (sub-control board 80) for controlling the effect,
The main control means,
An internal lottery that performs a lottery so as to have a first lottery result (for example, "BB" single win in non-internal) or a second lottery result (for example, "non-win" in BB inside) Means (role lottery means 61),
A plurality of stop position determination tables defining stop positions of the reel corresponding to the position of the reel at the moment when the stop switch is operated,
Reel control means (65) for determining the stop position of the reel using any one of the stop position determination tables and stopping the reel at the determined stop position,
The reel control means determines the stop position of the reel by using the same stop position determination table for the game that has the first drawing result and the game that has the second drawing result,
The sub control means,
A plurality of effect determination tables that determine the effect to be output,
And a production output control means (91) for determining a production to be output using any one of the production determination tables and outputting the determined production.
The effect output control means determines an effect to be output by using different effect determination tables for a game having a first drawing result and a game having a second drawing result.

(C) Effect of Initial Invention 7 According to the initial invention, the reel control means stops at the same main control means side in the game in which the first drawing result is obtained in the internal drawing means and the game in which the second drawing result is obtained. Although the reel stop position is determined using the position determination table, the effect output control means on the side of the sub control means determines the effect to be output using a different effect determination table.
Thereby, even if the reel stop control is the same on the main control means side, different effects can be output on the sub control means side, and the effects can be diversified.

8. Original invention 8
(A) Problem to be Solved by Initial Invention 8 The initial invention relates to a gap between the cabinet and the front door.
In the conventional gaming machine, a protruding side protruding outward is provided at the edge of the opening on the front side of the cabinet, and when the front door is closed, the protruding side is housed inside the front door. As a result, it is known that the gap between the cabinet and the front door is bent to make it difficult for foreign matter to enter (for example, Japanese Patent Laid-Open No. 2005-198949).
However, it is conceivable that the front door is opened a little and the protruding side is removed from the front door to allow foreign matter to enter the gap between the cabinet and the front door.
Initially, the problem to be solved by the invention is to prevent a fraudulent act (goto act) of opening a front door a little and intruding a foreign substance through a gap between the cabinet and the front door.

(B) Means for solving the problem of the first invention 8 (Note that the corresponding embodiment is described in parentheses.)
The original invention (eighth embodiment) is
A cabinet (13),
A front door (12) attached to the cabinet so as to be openable and closable,
A door sensor for detecting opening of the front door,
A lower portion of the cabinet is provided with a first closing portion (13c) protruding toward the front door when the front door is closed,
A second closing part (12a) protruding toward the cabinet when the front door is closed is provided at a position below the first closing part in the lower part of the front door,
A lower part of the front door is provided at a position above the first closing part with a third closing part (12b) projecting toward the cabinet when the front door is closed,
In a state in which the front door is closed, the first closing portion is formed between the second closing portion and the third closing portion,
The detection start position is the position of the front door when the door sensor first detects the opening of the front door,
Even when the front door is at the detection start position, the first closing part is formed between the second closing part and the third closing part.

(C) Effect of Initial Invention 8 According to the initial invention, when the front door is opened from the closed state, the door sensor first detects the opening of the front door, and then the second closing portion and the third closing portion are separated. The first closed portion comes out from the space. Further, when the door sensor detects the opening of the front door, it is possible to inform that the front door is open.
For this reason, before it becomes possible to notify that the front door is open, it is possible to notify that the front door is open without the first closed part coming off between the second closed part and the third closed part. Even at a position where it is possible, the gap between the cabinet and the front door has a bent shape, so that it is possible to prevent an illegal act (gotting action) in which a foreign substance enters through the gap between the cabinet and the front door.

9. Original invention 9
(A) Problem to be Solved by Initial Invention 9 The initial invention relates to a gaming machine including an advantageous zone display.
Conventionally, a gaming machine provided with an advantageous zone display is known (see, for example, JP-A-2018-000797).
However, in the conventional gaming machine provided with the advantageous zone indicator, the lighting control of the advantageous zone indicator at the time of recovery from power failure has not been sufficiently studied.
Initially, the problem to be solved by the invention is to appropriately control the advantageous zone display at the time of recovery from power failure.

(B) Means for solving the problem of Invention 9 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (11th embodiment) is
A notification game state (AT) capable of notifying the operation mode (correct answer pressing order) of the stop button (stop switch 42),
An advantageous section in which the notification game state can be executed,
An advantageous zone indicator (advantageous zone display LED 77) indicating that it is an advantageous zone,
After the power supply is cut off while the advantageous zone indicator is lit, when the power supply is resumed with the setting change switch in the off state, the advantageous zone indicator is displayed after the interrupt process is started. Enables processing to turn on,
Processing for turning off the advantageous zone indicator when the supply of power is resumed while the setting change switch is in the ON state after the supply of power is cut off while the advantageous zone indicator is lit It is possible to move to the setting change process after executing.

(C) Effect of Original Invention 9 According to the initial invention, the advantageous zone indicator can be appropriately controlled according to the situation when the power is restored from the power failure.

10. Original invention 10
(A) Problem to be Solved by Initial Invention 10 The initial invention relates to a gaming machine having four reels and a stop button.
A conventional game machine generally has three reels and three stop buttons (for example, see JP-A-2018-000797).
It has been proposed that the number of reels and stop buttons in the conventional game machine be set to four. However, if the number of stop buttons is set to 4, there is a problem that an operation error of the stop button is likely to occur during AT.
Initially, the problem to be solved by the invention is to make it difficult for an operation error of the stop button to occur when the number of stop buttons is four.

(B) Means for solving the problem of the first invention 10 (Note that the corresponding embodiment is described in parentheses.)
The original invention (thirteenth embodiment) is
4 reels (31A-31D),
With four stop buttons (stop switches 42A to 42D) corresponding to each of the four reels,
Arrange a predetermined operation button (24) above the four stop buttons,
At least a part of the stop button (stop switch 42A) on the left end side is positioned vertically downward from the left end of the predetermined operation button,
At least a part of the stop button (stop switch 42D) on the right end side is positioned vertically downward from the right end of the predetermined operation button.

(C) Effect of Original Invention 10 According to the initial invention, even when the number of stop buttons is four, the stop buttons at the left and right ends can be operated with the left and right ends of the operation button as marks. , It is possible to prevent the operation mistake of the stop button from occurring.

11. Original invention 11
(A) Problem to be Solved by Initial Invention 11 The initial invention relates to a gaming machine capable of instructing a prescribed number.
2. Description of the Related Art Conventionally, there has been known a gaming machine capable of playing a game with a prescribed number out of a plurality of prescribed numbers (see, for example, JP-A-2018-000797).
However, in the conventional gaming machine, there are cases where an appropriate prescribed number and an inappropriate prescribed number occur even if the game can be played with any one prescribed number out of a plurality of types.
Initially, the problem to be solved by the invention is to make it possible to play a game in an appropriate prescribed number.

(B) Means for solving the problem of the first invention 11 (Note that the corresponding embodiment is described in parentheses.)
The original invention (twelfth embodiment) is
Equipped with a notification game state (AT) that can notify the operation mode of the stop button (stop switch 42),
When notifying the operation mode in the notification game state, information corresponding to the operation mode (pushing order instruction information) can be displayed on a predetermined display unit (acquired number display LED 78),
In the notification game state, the game can be started when the game value of at least one of a plurality of specified numbers (“2” or “3”) is input.
In the notification game state, it is possible to display information corresponding to a specified number on the predetermined display unit,
In the information game state, when information corresponding to a specified number is displayed on the predetermined display unit, a predetermined timing (after the start switch ON is detected after all reels stop) (in FIG. 42). , In step S322),
When the information corresponding to the specified number is displayed on the predetermined display unit, the information corresponding to the operation mode is displayed in a display mode that can be distinguished from the information corresponding to the operation mode (when the specified number is “2”, “0A” is displayed). Characterize.

(C) Effect of Original Invention 11 According to the initial invention, the information corresponding to the specified number can be displayed at a predetermined timing until it is detected that the start switch is turned on. Thus, it is possible to notify an appropriate prescribed number in the game.
Further, it is possible for the player not to confuse the information corresponding to the operation mode with the information corresponding to the specified number.

12. Original invention 12
(A) Problem to be Solved by Initial Invention 12 The initial invention relates to a gaming machine provided with a counter that counts the number of differences in the notification game state.
2. Description of the Related Art Conventionally, a gaming machine having a counter for counting the difference in AT is known (for example, see JP-A-2018-000797).
In the conventional gaming machine, it is required to initialize the information on the advantageous section at the end of the advantageous section. However, after the AT ends, the next AT may be elected early, and in some cases, the difference in the number of the previous AT may be taken over.
Initially, the problem to be solved by the invention is to make it possible to take over the difference in the previous notification game state (AT) while initializing the information about the advantageous section at the end of the advantageous section.

(B) Means for solving the problem of Invention 12 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (11th embodiment) is
A notification game state (AT) capable of notifying the operation mode (correct answer pressing order) of the stop button (stop switch 42),
An advantageous section in which the notification game state can be executed,
In the first control means (main control board 50), the cumulative value of the difference number showing the difference between the bet number of the game value and the payout number (including addition to credits; the same applies hereinafter) and the minimum value is "0". A first difference number counter (difference number counter) for storing the value
The second control means (sub-control board 80) includes a second difference number counter (sub-difference number counter) for storing an accumulated value of the difference numbers indicating the difference between the bet number of game values and the payout number,
At the end of the advantageous period, the first difference number counter may be cleared (step S435 in FIG. 51 or FIG. 52), and the second difference number counter may not be cleared.

(C) Effect of Original Invention 12 According to the initial invention, the first difference counter is cleared at the end of the advantageous section, so that it is possible to comply with the rule of initializing information about the advantageous section. Further, the second difference number counter may not be cleared, in which case it is possible to take over the difference number in the previous notification game state at the start of the next notification game state.

13. Original invention 13
(A) Problem to be Solved by Initial Invention 13 The initial invention relates to a gaming machine provided with a counter that counts the difference number in the notification game state.
2. Description of the Related Art Conventionally, a gaming machine having a counter for counting the difference in AT is known (for example, see JP-A-2018-000797).
However, in the conventional gaming machine, how to count (update) the number of differences during replay winning has not been sufficiently studied.
Initially, the problem to be solved by the invention is to appropriately execute the difference number update processing at the time of replay winning.

(B) Means for solving the problem of Invention 13 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (11th embodiment) is
A notification game state (AT) capable of notifying the operation mode of the stop button (stop switch 42),
An advantageous section in which the notification game state can be executed,
A difference number counter that stores a cumulative value of the difference number showing the difference between the bet number of the game value and the number of payouts (including addition to credits; the same applies hereinafter), with the minimum value being “0”.
With an advantageous zone counter (advantageous zone clear counter) that counts the number of games in the advantageous zone,
1. At least in the game in which the small winning combination has been won, after all reels have stopped (after step S289 in FIG. 41), it is judged whether or not the value of the advantageous zone counter is a value satisfying the condition for ending the advantageous zone ( 51 or 52, step S424),
1) When it is determined that the value of the advantageous interval counter is a value that satisfies the condition for ending the advantageous interval, the advantageous interval is determined without determining the value of the difference counter (without executing the process of step S434). Enable processing for ending (step S435),
2) When it is determined that the value of the advantageous zone counter does not satisfy the condition for ending the advantageous zone (when “No” in step S424), the difference number counter is updated (steps S428 and W429). Thereafter, it is determined whether or not the value of the difference counter is a value satisfying the end condition of the advantageous section (step S434), and when it is determined that the value satisfies the end condition of the advantageous section ("Yes" in step S434). In the case of “)”, the processing for ending the advantageous section (step S435) can be executed,
2. In the game that wins the replay, after all reels have stopped (after step S289 in FIG. 41), it is determined whether or not the value of the advantageous zone counter is a value that satisfies the termination condition of the advantageous zone (FIG. 51). Alternatively, in FIG. 52, step S424),
1) When it is determined that the value of the advantageous zone counter satisfies the condition for ending the advantageous zone (when “Yes” in step S424), the value of the difference counter is not determined (step S434). A process (step S435) for ending the advantageous section is made executable without executing the process,
2) When it is determined that the value of the advantageous zone counter does not satisfy the condition for ending the advantageous zone (“No” in step S424), the difference number counter is not updated and the difference number counter is not updated. It is determined whether the value of is a value satisfying the end condition of the advantageous section (in FIG. 51 or FIG. 52, if “Yes” in step S426, the process proceeds to step S434), and the value satisfying the end condition of the advantageous section is satisfied. When it is determined that the value is “1” (“Yes” in step S434), the process for ending the advantageous section (step S435) is enabled.

(C) Effect of Original Invention 13 According to the original invention, in the game won in the replay, the difference number counter is updated regardless of whether the value of the advantageous section counter is a value satisfying the condition for ending the advantageous section. Since it is not executed, it is possible to appropriately execute the update processing of the difference number in the game that is won in the replay. Further, it is possible to speed up the program processing.

14. Original invention 14
(A) Problem to be Solved by Initial Invention 14 The initial invention relates to a gaming machine capable of executing a process related to an instruction function in a predetermined prescribed number.
Conventionally, a game machine having an instruction function has been known (see, for example, JP-A-2018-000797).
However, in the conventional gaming machine, the relationship between the specified number and the processing related to the instruction function and the processing related to the advantageous section has not been sufficiently studied.
Initially, the problem to be solved by the invention is to appropriately execute the processing related to the instruction function and the processing related to the advantageous section in accordance with the specified number.

(B) Means for solving the problem of the first invention 14 (Note that the corresponding embodiment is described in parentheses.)
The original invention (11th embodiment) is
A notification game state (AT) capable of executing an instruction function for notifying the operation mode of the stop button (stop switch 42),
An advantageous section that can execute the notification game state,
An advantageous zone counter (advantageous zone clear counter) for counting a predetermined variable relating to the advantageous zone,
An information game counter (AT game number counter or AT difference number counter) for counting a specific variable related to the information game state (for example, the number of games or a difference number),
At least a first specified number (specified number “3”) or a second specified number (specified number “2”) of game value can be input,
In the game in the advantageous section (AT), in the game started on the basis of the first specified number being input, it is possible to execute the process related to the instruction function (for example, the notification of the correct pressing order) (in FIG. 48). , Yes in step S382), and in the game started based on the second specified number being input, the process related to the instruction function cannot be executed (“No” in step S382 in FIG. 48). ,
In the information game state, in the game started on the basis that the first specified number has been thrown, the update of the advantageous zone counter can be executed (step S422 in FIG. 51 or FIG. 52), and the information game. The counter can be updated (step S333 in FIG. 43),
In the information game state, in the game started on the basis of the second specified number being thrown in, it is possible to update the advantageous zone counter (step S422 in FIG. 51 or FIG. 52), and the information game counter Update cannot be executed (“No” in step S332 in FIG. 43)
It is characterized by

(C) Effect of Initial Invention 14 According to the initial invention, the advantageous section counter can be updated by either the first prescribed number of games or the second prescribed number of games, so that the advantageous section can be optimized. ..
Further, by not updating the notification game counter in the second prescribed number of games in which the processing related to the instruction function cannot be executed, the execution of the processing related to the instruction function and the update of the notification game counter can be consistent. it can.

15. Original invention 15
(A) Problem to be Solved by Initial Invention 15 The initial invention relates to a gaming machine having a signal line for starting.
It has been conventionally known to use a harness composed of a plurality of signal lines (lead wires) when electrically connecting control boards of a gaming machine. Then, as one of the signal lines, there is a signal line related to starting.
In the prior art, since the signal related to the start is used for the lottery, it is necessary to suppress the goto action on the signal line related to the start.
Initially, the problem to be solved by the invention is to make it difficult to identify the signal line related to the start and suppress the goto action.

(B) Means for Solving the Problems of Initial Invention 15 (Note that the corresponding embodiments are described in parentheses.)
The original invention (21st embodiment) is
In a gaming machine (slot machine 10, pachinko gaming machine 500) including a control board (main control boards 50, 530),
A plurality of signal lines (lead lines) electrically connected to the control board,
As the plurality of signal lines, at least a first signal line, a second signal line, and a third signal line,
The first signal line is a signal line for starting a game (for example, the lead wire of harness D in FIG. 111),
Both the second signal line (for example, the 8th lead wire of the harness D in FIG. 111) and the third signal line (for example, the 3rd lead wire of the harness D in FIG. 111), It is a signal line different from the signal line regarding the start of the game,
The first signal line and the second signal line have substantially the same diameter,
The first signal line and the third signal line have different diameters.

(C) Effect of Initial Invention 15 According to the initial invention, it is possible to make it difficult to specify which signal line is related to the start. As a result, it is possible to suppress the goto action on the signal line related to the start.

16. Original invention 16
(A) Problem to be Solved by Initial Invention 16 The initial invention relates to a gaming machine capable of outputting a setting change end sound.
Conventionally, a gaming machine capable of setting any one of a plurality of setting values is known.
In the prior art, for example, the setting change process ends when the setting key is turned off, and it is not possible to easily grasp the timing when the setting change process ends from the outside.
Therefore, when the setting change process is completed, it is possible to give a notice to that effect.
However, when the game is started immediately after the end of the setting change process, if the notification of the end of the setting change process is issued, the notification of the end of the setting change process and the notification output in the game are the same. There is a risk of being output (overlapping) at the time, and it may be difficult to understand important notifications output in the game.
Initially, the problem to be solved by the invention is to appropriately output an end sound indicating that the setting change state has ended.

(B) Means for Solving the Problem of Original Invention 16 (Note that the corresponding embodiment is described in parentheses.)
The original invention (the nineteenth embodiment) was
A gaming machine (slot machine 10, pachinko gaming machine 500) capable of changing the degree of advantage for a player,
Specific operation detecting means for detecting that a specific operation has been performed in order to control either the setting change state in which the advantage can be changed or the normal state in which the advantage cannot be changed and a game can be started (Setting key switches 152, 535),
With speakers (22, 542),
In the setting change state, when the condition for shifting to the normal state is satisfied, an end sound indicating that the setting change state has ended can be output from the speaker for time T1 (“T01” in FIG. 96). And
The start condition of the game (in the case of the slot machine 10, the specified number is bet and the start switch 41 is operated, and in the case of the Pachinko game machine 500, the game ball has entered the starting opening 532). In one satisfied game, it is possible to end the game at time T2 (“T12” or “T22” in FIG. 96),
In the setting change state, at least time T3 (“T11” or “T12” in FIG. 96) is required until the start condition of the game is satisfied after shifting to the normal state,
When one game is started immediately after shifting from the setting change state to the normal state, the following formula is established: T1<T2+T3 (T1>0, T2>0, T3>0 )
It is characterized by

(C) Effect of Original Invention 16 According to the original invention, even when the game is started at the same time as the end of the setting change state, an end sound indicating that the setting change state is ended is given before the end of the game. Since the output ends, the effect output at the end of the game does not overlap with the end sound indicating that the setting change state has ended. Therefore, it is possible to prevent the effect output at the end of the game from becoming difficult to understand due to the end sound indicating that the setting change state has ended.

17. Original invention 17
(A) Problem to be Solved by Initial Invention 17 The initial invention relates to a gaming machine capable of setting the net increase and the base value to appropriate values.
Conventionally, a gaming machine in which both non-AT and AT are in the inside of 1BB is known (see, for example, JP-A-2018-029839).
However, in the 1BB internal medium specifications as described above, the payout rate cannot exceed "1" even when playing in the pushing order that is most advantageous to the player, so the net increase in AT is increased. There is a problem that it is difficult to do.
The problem to be solved by the first invention is to realize a high net increase during AT without increasing the base value.

(B) Means for solving the problem of the first invention 17 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
In the advantageous section, it is possible to execute a notification game state (AT) capable of notifying the operation information of the stop switch (correct answer pressing order),
When the symbol combination corresponding to the special combination (1BB) is stopped and displayed, the special game (1BB game) can be executed,
In the first situation (within 1BB), which is an advantageous section and carries over the winning information of the special role,
With the second situation (1BB is operating), which is an advantageous section and is in a special game,
In the first situation, there is no case of executing the notification game state,
In the second situation, there is a case where the notification game state is executed,
The payout rate in the first situation (refers to the value obtained by dividing the number of game media provided by the bet number. The same applies hereinafter) is α, and the payout rate in the second situation and the non-reporting game state is β, In the situation of 2 and the notification game state, the payout rate (in the game where the operation information of the stop switch is notified, refers to the payout rate when the stop switch is operated according to the notified operation information) is set to γ. When
α<β<1<γ
And
The probability of deciding to execute the informing game state in the non-informing game state of the second situation is x (value larger than “0”),
When the probability of deciding to execute the informing game state in the non-informing game state of the first situation is y (“0” in the 23rd embodiment),
x<y
And
The second situation is characterized in that a predetermined value (advantageous section clear counter value) relating to the advantageous section can be updated according to the execution of the game even in the non-notification game state.

(C) Effect of Initial Invention 17 According to the original invention, the payout rate in the special game is higher than that in the non-special game. Therefore, by executing the notification game state during the special game, the payout in the notification game state The rate can be increased. Moreover, since the notification game state is not executed in the non-special game, the base value can be lowered.
Furthermore, when the game shifts to the special game in the non-notification game state, the payout rate does not exceed "1", and the predetermined value regarding the advantageous section is updated, so that the player does not have the right to the special game state Even if the player shifts to the game, the player can be made to have no merit. In particular, when the special game is transferred in the non-notification game state, the probability of being set to the notification game state is set to be lower than that in the non-special game state, so it is restrained from shifting to the special game in the non-notification game state. can do.

18. Original invention 18
(A) Problem to be Solved by Initial Invention 18 The initial invention relates to a gaming machine that outputs a test signal.
Conventionally, a gaming machine in which both non-AT and AT are in the inside of 1BB is known (see, for example, JP-A-2018-029839).
However, in the 1BB internal medium specifications as described above, the payout rate cannot exceed "1" even when playing in the pushing order that is most advantageous to the player, so the net increase in AT is increased. It's hard to make.
Here, various specs have been proposed which realize a low base and increase a net net during AT.
In such a low base and AT mid-high net increase specification, what kind of test signal is output becomes a problem.
The problem to be solved by the first invention is to be able to output an appropriate test signal even with a low base and a specification of AT high net increase.

(B) Means for Solving the Problem of Original Invention 18 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
A game in which the winning information of the special role (1BB) is carried over, and the symbol combination corresponding to the special role can be stopped and displayed (the character condition device number is "1", and the winning and replay condition device numbers are "0"). )),
If the predetermined condition is satisfied (main game state "3", and AT standby counter "0"), the test signal including the operation information of the stop switch that makes it possible to stop and display the symbol combination corresponding to the special combination (" 0,16,7,2”) can be executed,
When the predetermined condition is not satisfied, it is possible to execute the process for outputting the test signal (“0, 6, 127, 127”) including the operation information of the stop switch that does not stop and display the symbol combination corresponding to the special combination. It is characterized by

(C) Effect of Initial Invention 18 According to the initial invention, when a predetermined condition is satisfied, a test signal capable of stopping and displaying a symbol combination corresponding to a special combination can be output, and when the predetermined condition is not satisfied, a special signal is output. Since it is possible to output a test signal that does not stop and display the symbol combination corresponding to the winning combination, in a gaming machine with specifications that guide the player to a special game when executing the notification game state (AT), the same as the player (market) It is possible to carry out a test with a different hitting method.

19. Original invention 19
(A) Problem to be Solved by Initial Invention 19 The initial invention relates to a gaming machine that prevents a wrong winning of a special role.
Conventionally, a gaming machine that executes a non-AT and an AT in a state where the inside of the MB is inside is known. In this case, in order to avoid the winning of the MB that has been carried over from the winning, it is known to notify the target symbol to avoid the winning of the MB (for example, refer to JP-A-2014-147537).
However, the above-mentioned notification has a problem that the player may be mistakenly recognized. Further, even if the notification is given after the MB has been tempted, if the time from the second stop to the third stop of the stop switch is short, the notification may not be in time and the MB may win the prize.
Initially, the problem to be solved by the invention is to prevent an incorrect winning of a special role when a special role that has carried over the winning and a special role that should avoid winning is a tempai.

(B) Means for solving the problem of Invention 19 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
When the symbol combination corresponding to the special combination (1BB) is stopped and displayed, the special game (1BB game) can be executed,
In the game in which the symbol combination corresponding to the special combination can be stopped and displayed, a special reel (third reel 31) is rotating and the other reels (first and second reels 31) are stopped specially. When the symbols constituting the symbol combination corresponding to the winning combination are stopped and displayed (so-called special winning is tempted), the predetermined condition is satisfied until a predetermined condition is satisfied (for example, waiting time elapses). Even if the stop switch corresponding to the reel is operated, the predetermined reel is not stopped.

(C) Effect of Original Invention 19 According to the initial invention, the predetermined reel is not stopped even if the stop switch corresponding to the predetermined reel is operated until the predetermined condition is satisfied. be able to.

20. Original invention 20
(A) Problems to be Solved by Initial Invention 20 Same as original invention 19.
(B) Means for solving the problem of the first invention 20 (Note that the corresponding embodiments are described in parentheses.)
The original invention (23rd embodiment) is
When the symbol combination corresponding to the special combination (1BB) is stopped and displayed, the special game (1BB game) can be executed,
In the special game, it is possible to execute a notification game state (AT) capable of notifying the operation information (correct answer pressing order) of the stop switch (42),
In the game in which the symbol combination corresponding to the special combination can be stopped and displayed, the stop switch corresponding to a reel other than the predetermined reel (third reel 31) is operated, and the symbol combination corresponding to the special combination can be stopped and displayed. When the predetermined condition is not satisfied (when the waiting time has not elapsed) in the case of becoming a so-called special role, the stop switch corresponding to the reel other than the predetermined reel is operated. From a predetermined timing thereafter (when the standby time is initially saved in step S810 in FIG. 147) until at least one rotation of the predetermined reel (at least 750.624 ms from the time of step S810 (one rotation time of the reel 31). Until () is passed), the predetermined reel is not stopped even if the stop switch corresponding to the predetermined reel is operated.
(C) Effect of Original Invention 20 Same as Original Invention 19.

21. Original invention 21
(A) Problem to be Solved by Initial Invention 21 The initial invention enables a gaming machine having an advantageous section to realize a ceiling function.
2. Description of the Related Art Conventionally, there has been known a gaming machine that is provided with a ceiling counter and counts the number of games that have passed without shifting to AT (see, for example, Japanese Unexamined Patent Application Publication No. 2018-061760).
However, the advantageous section may end while the number of games is being counted by the ceiling counter. Here, since the ceiling counter is data related to the instruction function, it is considered that the ceiling counter is a target of data that is cleared when the advantageous section ends. Therefore, there is a problem that the ceiling counter is cleared when the advantageous section ends while the number of games is being counted by the ceiling counter.
Initially, the problem to be solved by the invention is to realize a ceiling function even when an advantageous section is provided.

(B) Means for solving the problem of the first invention 21 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
A first lottery state (RT1) and a second lottery state (non-RT),
It is provided with an advantageous section that can execute a notification game state (AT) that can notify the operation information of the stop switch,
When the number of games in the first lottery state satisfies a predetermined condition (when 1400 games are reached), it is possible to shift to the second lottery state,
In the first lottery state, which is an advantageous zone, if the conditions for ending the advantageous zone are satisfied, it is possible to shift to the first lottery state, which is a non- advantageous zone.
It is characterized in that the number of games in the first lottery state is continuously counted even when the first lottery state which is the advantageous zone is shifted to the first lottery state which is the non-advantageous zone.

(C) Effect of Original Invention 21 According to the initial invention, the number of games in the first lottery state is continued to be counted even if the advantageous section ends midway. Therefore, based on the number of games in the first lottery state. It becomes possible to provide a ceiling function.

22. Original invention 22
(A) Problem to be Solved by Initial Invention 22 The initial invention relates to a gaming machine capable of executing a reel effect.
2. Description of the Related Art Conventionally, there has been known a gaming machine that performs a reel effect in which a reel is temporarily stopped in a pseudo game (for example, Japanese Patent No. 5709176).
However, the pseudo game in the prior art is reel production based on the operation of the stop switch by the player.
Initially, the problem to be solved by the invention is to execute the reel effect without being based on the operation of the stop switch by the player, and to give the reel stop timing regularity.

(B) Means for Solving the Problem of Original Invention 22 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
Each reel (31) is stopped at a predetermined stop position, and a reel effect (standby effect) for stopping and displaying a predetermined symbol combination can be executed (standby effect start (M_TARPIC_EXE)),
When the reel effect is executed, information about a scheduled stop position (information of the reel effect data table (TBL_TARPIC_DAT)) and a timer value until the reel can be stopped (reel effect execution timer table (TBL_TARPIC_TM#) ) Information) can be stored,
While the reel effect is being executed, the timer value corresponding to the predetermined reel is a value that enables the predetermined reel to be stopped even when the predetermined reel can be stopped at the scheduled stop position. If not, the predetermined reel is not stopped.

(C) Effects of Initial Invention 22 According to the initial invention, in the reel effect, it is possible to give regularity to the timing at which each reel is stopped by a simple method.

23. Original invention 23
(A) Problem to be Solved by Initial Invention 23 The initial invention relates to a gaming machine that outputs information regarding prevention of slipping in.
2. Description of the Related Art Conventionally, there is known a gaming machine that outputs information regarding prevention of slipping in when triggered by the end of AT (for example, Japanese Patent No. 6288357).
However, the conventional output of information relating to the prevention of slipping has been uniform.
Initially, the problem to be solved by the invention is to appropriately execute output of information relating to prevention of slipping in.

(B) Means for solving the problem of the first invention 23 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
A notification game state (AT) capable of notifying the operation information (correct answer pressing order) of the stop switch (42) can be executed,
In the case where it is determined that a plurality of sets of informative game states can be executed, there is a case of notifying that the informative game state of the next set will be executed during execution of the informative game state of one set,
In a situation where a plurality of information game states can be executed, while notifying that the next information game state will be executed while the information game state of one set is being executed, the information game of one set will be executed. After executing the state, but before the next set of informative game states is executed, information regarding the prevention of slipping in is not output (“Yes” in step S975 in FIG. 160),
In a situation where a plurality of sets of information game states can be executed, while not informing that the next set of information game states will be executed while the information game state of one set is being executed, After executing the information game state, before the next set information game state is executed, it is possible to output the information regarding the slip-in prevention (in the case of "No" in step S975 in FIG. 160, step S978 is executed). Do)
It is characterized by

(C) Effect of Initial Invention 23 According to the initial invention, it is possible to make the output of information relating to the prevention of slipping in correspond to the content of the notification in the notification game state of one set. Further, it is possible to prevent whether or not the information game state of the next set is to be executed depending on whether or not the information regarding the prevention of slipping in is output.

24. Original invention 24
(A) Problem to be Solved by Initial Invention 24 The initial invention relates to a gaming machine capable of outputting a subsequent effect based on an operation of a stop switch.
It is known in the related art to include a message with a delay function that delays execution of an effect message after a set time has elapsed when the effect message is transmitted from the control device to the effect device (for example, JP-A-04-042759). Publication).
In the conventional technique, when the effect is delayed at the third stop, it is necessary to transmit a command indicating the delay at the third stop.
The problem to be solved by the invention at the beginning is to make it possible to delay the output timing of an effect without transmitting a command indicating a delay at the time of the third stop.

(B) Means for Solving the Problem of Original Invention 24 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
A timer value from a predetermined timing after a predetermined switch (start switch 41) is operated can be stored (step S993 in FIG. 161),
In a game that outputs a specific effect (end of effect), when the timer value has reached a predetermined value when the last operated stop switch is turned on ("Yes" in step S995). When the stop switch operated last is turned on, a specific effect can be output.
In a game that outputs a specific effect, if the timer value is not the predetermined value when the last operated stop switch is turned from ON to OFF, at a timing when the timer value becomes the predetermined value (step It is characterized in that a specific effect can be output (when “Yes” is obtained in S995).

(C) Effect of Original Invention 24 According to the initial invention, it is possible to delay the timing of outputting a specific effect. In addition, a player who does not want to immediately output a specific effect can delay the output timing of the specific effect by his/her intention.

25. Original invention 25
(A) Problem to be Solved by Initial Invention 25 The initial invention relates to a gaming machine capable of setting an output volume.
In the prior art, it is known that the administrator (store side) sets the reference level for the volume of the effect, and further allows the player to set the volume (for example, Japanese Unexamined Patent Publication No. 2017-0743301). ..
However, in the above-mentioned conventional technology, the volume is often set to a high level on the store side, and in this case, even if the player sets a low volume, the volume should be reduced to the extent desired by the player. There is a problem that you can not.
Initially, the problem to be solved by the invention is to enable a player who desires a low volume to reduce the volume regardless of the setting on the store side.

(B) Means for Solving the Problem of Original Invention 25 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
As a mode for setting the volume, a first volume setting mode (administrator mode in FIG. 162(A)) and a second volume setting mode (player mode in FIG. 162(B)) are provided,
The first volume setting mode can be executed when a predetermined condition is satisfied (power on/off, in a setting change state, in a setting confirmation state),
The second volume setting mode can be executed by the player,
The output volume is configured to be determined based on the volume set in the first volume setting mode and the volume set in the second volume setting mode,
A predetermined effect sound (for example, start) that is output when the volume is set to a predetermined volume (for example, “high”) in the first volume setting mode and the minimum volume (volume 1) is set in the second volume setting mode. The volume of the operation sound of the switch 41, the operation sound of the stop switch 42, the tempo sound, the winning sound of the winning combination, the GBM during AT, etc. (“20” in FIG. 162(C)) and the first volume setting mode. The volume of a predetermined effect sound (“20” in FIG. 162(C)) output when the volume is set to a specific volume (for example, “small”) and set to the minimum volume in the second volume setting mode. Are substantially the same.

(C) Effect of Original Invention 25 According to the original invention, the volume is set in the second volume setting mode depending on whether the volume is set to the predetermined volume or the specific volume in the first volume setting mode. If the volume is set to the minimum volume, the predetermined effect sound is output at substantially the same volume. Thereby, the volume can be set to the minimum volume in the second volume setting mode without being influenced by the volume setting in the first volume setting mode.

26. Original invention 26
The first invention relates to a gaming machine capable of setting an output volume.
In the prior art, it is known that the administrator (store side) sets the reference level for the volume of the effect, and further allows the player to set the volume (for example, Japanese Unexamined Patent Publication No. 2017-0743301). ..
However, in the above-mentioned conventional technology, since it is not possible to grasp the specific volume on the volume setting screen, the administrator may try the game after setting the volume. Was needed.
Initially, the problem to be solved by the invention is to be able to know a concrete measure of the volume when setting the volume.

(B) Means for solving the problem of the first invention 26 (Note that the corresponding embodiment is described in parentheses.)
The original invention (23rd embodiment) is
As a mode for setting the volume, a first volume setting mode (administrator mode in FIG. 162(A)) and a second volume setting mode (player mode in FIG. 162(B)) are provided,
The first volume setting mode can be executed when a predetermined condition is satisfied (power on/off, in a setting change state, in a setting confirmation state),
The second volume setting mode can be executed by the player,
The output volume is configured to be determined based on the volume set in the first volume setting mode and the volume set in the second volume setting mode,
In the first volume setting mode, an icon corresponding to a plurality of selectable volume levels is displayed as an image, and when one of the icons is selected, a predetermined sound can be output at the volume corresponding to the selected icon. It is characterized by

(C) Effect of Original Invention 26 According to the initial invention, when setting the volume in the first volume setting mode, it is possible to grasp the standard of how much the set volume is.

27. Original invention 27
(A) Problem to be Solved by Initial Invention 27 The initial invention relates to a gaming machine that executes a predetermined instruction by a program.
In a conventional gaming machine, it is known to be composed of a plurality of modules (processes) in order to execute game control (for example, Japanese Patent Laid-Open No. 2017-104160).
However, in the above-mentioned conventional technique, there is room for improvement because there is a complicated point in the instruction that configures the module.
The problem initially solved by the invention is to simplify the instructions.

(B) Means for solving the problem of invention 27 at the beginning (Note that the corresponding embodiment is described in parentheses.)
The original invention (24th embodiment) is
Having a plurality of storage areas (RWM53) capable of storing data based on execution of programs,
As a program command,
Store the value of the reference address in a predetermined register (HL register),
Storing "0" in the storage area from the storage area corresponding to the reference address stored in the predetermined register to the "n (n is an integer)" address destination A specific instruction (CLRHL ( HL), n),
The value of the reference address is stored in the predetermined register even after the execution of the specific instruction.

(C) Effect of Original Invention 27 According to the original invention, it is possible to clear the entire specified range (store “0”) with one instruction.
Further, the value of the reference address is stored in the predetermined register, and the value of the predetermined register does not change even after executing the specific instruction (the value of the reference address is stored). As a result, the value of the reference address can be read based on the value stored in the predetermined register even after the completion of the specific instruction. Is unnecessary, and the processing can be simplified.

28. Original invention 28
(A) Problems to be Solved by Initial Invention 28 Same as Original Invention 27.
(B) Means for Solving the Problems of Original Invention 28 (Note that the corresponding embodiment is described in parentheses.)
The original invention (24th embodiment) is
Having a storage means (RWM53) having a stack area,
It is possible to execute a main process (for example, FIG. 41) and an interrupt process (for example, FIG. 53) that is executed in a predetermined cycle.
As a program command,
A predetermined value stored in a predetermined register (for example, A register) and "n (n is an integer)" are compared and calculated (for example, "n" is subtracted from the A register value), and carry is carried out by the comparison operation. When the flag becomes "1", a specific instruction ("RCP C, A, n" capable of executing a program corresponding to an address based on the information stored in the stack area can be executed. ))
Even when the predetermined cycle of the interrupt processing comes during the execution of the specific instruction, the interrupt processing is permitted after the end of the specific instruction.

(C) Effect of Original Invention 28 According to the original invention, since interrupt processing is not executed during execution of a specific instruction, the value of the carry flag corresponding to the operation by the specific instruction is the operation executed by the interrupt processing. Doesn't change. Thereby, the value of the carry flag can be prevented from being broken by the interrupt processing, and the correct processing can be executed.

29. Original invention 29
(A) Problem to be Solved by Initial Invention 29 The initial invention relates to a method for identifying a stop symbol combination on an activated line.
In the conventional gaming machine, even if an abnormality etc. occurs after the operation of the stop switch is accepted and the unintended symbol combination stops on the activated line, the payout process is executed based on the operation of the stop switch. (For example, Japanese Patent No. 6229810).
Initially, the problem to be solved by the invention is to more appropriately identify a stop symbol combination.

(B) Means for Solving the Problems of Original Invention 29 (Note that the corresponding embodiment is described in parentheses.)
The original invention (25th embodiment) is
Equipped with a storage area (stop symbol data (first group) to (9th group) (_WK_STOP_PIC1 to 9)) that can store data that can specify a stop symbol combination,
A predetermined initial value (11111111(B), 000011111(B), or 00000011(B)) can be stored in the storage area at a predetermined timing before the stop switch (42) is operated,
Acquired and acquired the stop symbol data (symbol combination data stored in the # reel symbol combination table (TBL_PICCMB_#)) corresponding to the symbol to be stopped and displayed on the activated line on the reel corresponding to the operated stop switch A calculation is performed based on the stop symbol data and the data stored in the storage area, and a predetermined process that allows the data corresponding to the calculation result to be stored in the storage area can be executed (stop symbol set in FIG. 195). (M_STOPPIC_SET )),
Each time the stop switch corresponding to the spinning reel is operated, the predetermined process can be executed, whereby the data stored in the storage area can be updated.

(C) Effect of Original Invention 29 According to the original invention, even if the power is cut off during the game, the stop symbol data up to the middle of the game can be held. Also, after the stop position was determined, before the symbol stopped, the reel could not be stopped at the correct position due to an abnormality due to power failure or motor drive abnormality (the correct symbol did not stop on the effective line. Even in the case), it is possible to execute the payout process by assuming that the vehicle has stopped at the correct position. Therefore, no disadvantage is given to the player.

30. Original invention 30
(A) Problems to be Solved by Initial Invention 30 Same as original invention 29.
(B) Means for solving the problem of the first invention 30 (Note that the corresponding embodiment is described in parentheses.)
The original invention (26th embodiment) is
Equipped with a data table (# reel design search table (TBL_PICARG_#)) that stores data that can specify a stop symbol combination,
Storage means (symbol array address buffers 1 to 3 (_BF_PICARG_ADR1 to 3)) capable of storing the address value of the data table for each reel,
Address value corresponding to the stop symbol can be stored in the storage means,
Data can be acquired from the data table based on the address value stored in the storage means,
Based on the acquired data, it is possible to execute a predetermined calculation for identifying a stop symbol combination.

(C) Effect of Initial Invention 30 According to the initial invention, even if the power is cut off during the game, it is possible to retain the data relating to the stop symbol until the middle of the game. Also, after the stop position was determined, before the symbol stopped, the reel could not be stopped at the correct position due to an abnormality due to power failure or motor drive abnormality (the correct symbol did not stop on the effective line. Even in the case), it is possible to execute the payout process without depressing the storage capacity of the RWM, assuming that the RWM has stopped at the correct position. Therefore, no disadvantage is given to the player.

31. Original invention 31
(A) Problem to be Solved by Initial Invention 31 Same as original invention 29.
(B) Means for solving the problem of the first invention 31 (Note that the corresponding embodiment is described in parentheses.)
The original invention (28th embodiment) is
The first position of the first reel (eg, “1” in FIG. 230), the second position of the second reel (eg, “5” in FIG. 230), and the third position of the third reel (eg, “5” in FIG. 230). A predetermined effective line (for example, an effective line L1) passing through "9"),
First storage area (_WK_PIC_LFT1) that can store the symbol data of the first position, second storage area (_WK_PIC_CEN2) that can store the symbol data of the second position, and third memory that can store the symbol data of the third position Equipped with a region (_WK_PIC_RIG3),
Based on the symbol data stored in the first storage area, the second storage area, and the third storage area, it is possible to specify the stop symbol combination of the predetermined effective line.

(C) Effect of the first invention 31 According to the first invention, after the stop position is determined, before the symbol is stopped, the reel cannot be stopped at the correct position due to an abnormality due to power failure, a drive abnormality of the motor, or the like. Even if the correct pattern is not stopped on the effective line, it is possible to execute the payout process without considering the capacity of the program as if the program was stopped at the correct position. Therefore, no disadvantage is given to the player.

32. Original invention 32
(A) Same as the first invention 29.
(B) Means for solving the problem of the first invention 32 (Note that the corresponding embodiment is described in parentheses.)
The original invention (28th embodiment) is
As effective lines in a predetermined game, from the first effective line (effective line L1) to the Nth (N>1) effective line (effective line L5),
Has a specific storage area (_WK_ALL_PIC) that can store data for specifying the stop symbol combinations of all active lines in a given game,
In a given game,
The first data (_WK_PIC_L1) corresponding to the stop symbol combination of the first activated line can be calculated,
The Nth data (_WK_PIC_L5) corresponding to the stop symbol combination of the Nth effective line can be calculated,
The first data corresponding to the stop symbol combination of the first effective line to the Nth data corresponding to the stop symbol combination of the Nth effective line are combined by a predetermined calculation (logical sum), and the combined data is a specific storage area. It is characterized in that it can be stored in.

(C) Effect of the first invention 32 According to the first invention, after the stop position is determined and before the symbol is stopped, the reel cannot be stopped at the correct position due to an abnormality due to power failure, a motor drive abnormality, or the like. Even if the correct pattern is not stopped on the effective line, it is possible to execute the payout process without considering the capacity of the program, as if it was stopped at the correct position. Therefore, no disadvantage is given to the player.
Further, since the winning determination is made based on the specific storage area instead of making the winning determination for each activated line, it is possible to collectively determine the payout number.

33. Original invention 33
(A) Problem to be Solved by Original Invention 33 The initial invention relates to a data table for acquiring the symbol data of the symbol on the activated line.
In a conventional game machine, it is known to store a symbol array in order to specify a symbol on an activated line (for example, Japanese Patent Laid-Open No. 2015-039456).
Initially, the problem to be solved by the invention is to more appropriately acquire the symbol data of the symbol on the activated line.

(B) Means for solving the problem of the first invention 33 (Note that the corresponding embodiment is described in parentheses.)
The original invention (Example 1 of 27th embodiment (or 25th embodiment))
As a reel, at least a predetermined reel (left reel 31) and a specific reel (middle reel 31) are provided,
The position of the effective line of the predetermined reel (upper stage) and the position of the effective line of the specific reel (middle stage) are positions that do not match on the horizontal line,
A predetermined data table storing the symbol data of the predetermined reel (in FIG. 228(B), the symbol arrangement table of the left reel) and a specific data table storing the symbol data of the specific reel (in FIG. 228(B), middle) With a reel pattern arrangement table),
In the predetermined data table, the symbol data corresponding to the symbol number X (symbol number 2) is stored at the head address (1000 (H)) where the symbol data is stored,
In the specific data table, at the top address (1100 (H)) where the symbol data is stored, the symbol data corresponding to the symbol number Y (Y≠X) (symbol number 1) is stored. ..

(C) Effect of Original Invention 33 According to the initial invention, the symbol data on the activated line can be acquired by a simple method without performing complicated calculation.

34. Original invention 34
(A) Problems to be Solved by Initial Invention 34 Same as Original Invention 33.
(B) Means for solving the problem of the first invention 34 (Note that the corresponding embodiment is described in parentheses.)
The original invention (Example 1 of 27th embodiment (or 25th embodiment))
A first position (lower left) which is a reference position of a predetermined reel (left reel 31) and a second position (second position) which is a symbol position on at least one effective line of the predetermined reel are different from the first position. ) (Upper left) and
A data table storing the symbol data (the symbol arrangement table of FIG. 228(B)) is provided,
In the game in which the symbol of the predetermined symbol number (0) of the predetermined reel stops at the first position, the symbol data of the symbol to be stopped at the second position based on the predetermined symbol number and the data table ( The design data of the design number 2) can be acquired.

(C) Effect of Original Invention 34 According to the initial invention, the symbol data on the activated line can be acquired by a simple method without performing complicated calculation.
Further, a reference position (reference line) is provided separately from the effective line, and the symbol on the effective line is specified based on this reference position. Therefore, even if the effective line is changed, the change can be easily dealt with. be able to. In other words, the data and program can be simply modified.

35. Original invention 35
(A) Problem to be Solved by Initial Invention 35 Same as Original Invention 33.
(B) Means for solving the problem of the first invention 35 (Note that the corresponding embodiment is described in parentheses.)
Initially, the invention of claim 1 (example 1 of 27th embodiment) is
As a reel, at least a predetermined reel (right reel 31) and a specific reel (middle reel 31) are provided,
A first position (lower right) which is a reference position of the predetermined reel and is a symbol position on at least one effective line of the predetermined reel,
A second position (the second position and the first position are located on the same horizontal line) that is a reference position of the specific reel (middle and lower tiers), and a symbol on at least one effective line of the specific reel. A third position (third position≠second position) (middle/middle stage), which is a position,
A predetermined data table that stores the symbol data of the predetermined reel (the symbol arrangement table of the right reel in FIG. 228(B)), and a specific data table that stores the symbol data of the specific reel (the symbol of the middle reel in FIG. 228) Array table) and
In the predetermined data table, the symbol data of the symbol number X (No. 0) is stored at the head address storing the symbol data,
In the specific data table, the symbol data of the symbol number Y (Y≠X) (No. 1) is stored at the head address where the symbol data is stored,
In the game in which the symbol of the specific symbol number of the specific reel stops at the second position, the symbol of the symbol that will be stopped at the third position of the specific reel based on the specific symbol number and the specific data table. The feature is that data can be acquired.
Initially, the invention of claim 2 is
As a reel, at least a predetermined reel (left reel 31) and a specific reel (middle reel 31) are provided,
A first position (lower left) which is a reference position of the predetermined reel, and a second position which is a symbol position on at least one effective line of the predetermined reel (the second position may be the same as the first position) ( Upper left) and
A third position (the third position and the first position are located on the same horizontal direction line) that is the reference position of the specific reel (middle lower row), and a symbol on at least one effective line of the specific reel. A fourth position (fourth position≠third position) (middle and middle stage), which is a position,
A predetermined data table storing the symbol data of the predetermined reel (in FIG. 228(B), the symbol arrangement table of the left reel) and a specific data table storing the symbol data of the specific reel (in FIG. 228(B), middle) With a reel pattern arrangement table),
In the predetermined data table, the symbol data of the symbol number X (No. 2) is stored at the head address (1000 (H)) where the symbol data is stored,
In the specific data table, at the head address (1100 (H)) where the symbol data is stored, the symbol data of the symbol number Y (Y≠X) (No. 1) is stored,
In the game in which the symbol of the predetermined symbol number (0) of the predetermined reel is stopped at the first position, based on the predetermined symbol number and the predetermined data table, it is stopped at the second position of the predetermined reel. It becomes possible to acquire the symbol data of the symbol (the symbol data of the symbol number 2),
In the game in which the symbol of the specific symbol number (0) of the specific reel is stopped at the third position, based on the specific symbol number and the specific data table, it is stopped at the fourth position of the specific reel. The feature is that the symbol data of the symbol (the symbol data of the symbol number 1) can be acquired.

(C) Effect of Original Invention 35 Same as Original Invention 34.

36. Original invention 36
(A) Problem to be Solved by Initial Invention 36 Same as Original Invention 33.
(B) Means for solving the problem of the first invention 36 (Note that the corresponding embodiment is described in parentheses.)
The original invention (Example 2 of 27th embodiment) is
A first position (upper right stage) which is a reference position of a predetermined reel (right reel 31) and a second position (second position) which is a symbol position on at least one effective line of the predetermined reel are different from the first position. ) (Bottom right) and
Storage means (ROM 54 or RWM 53) for storing or capable of storing information (difference data) for identifying the second position of the predetermined reel from the first position of the predetermined reel;
And a data table (FIG. 229(B)) storing pattern data,
Based on the first position of the predetermined reel, the information of the storage means, and the data table, it is possible to obtain the symbol data of the symbol that will be stopped at the second position of the predetermined reel.

(C) Effect of Original Invention 36 According to the initial invention, the symbol data on the activated line can be acquired by a simple method without performing complicated calculation.
Further, a reference position (reference line) is provided separately from the effective line, and the symbol on the effective line is specified based on this reference position. Therefore, even if the effective line is changed, the change can be easily dealt with. be able to. In other words, the data and program can be simply modified.
Furthermore, even if the effective line is changed, it is only necessary to change the data in the storage means without changing the data table.

37. Original invention 37
(A) Problem to be Solved by Initial Invention 37 The initial invention relates to a method for determining the number of game media provided corresponding to a stop symbol combination on an activated line.
In a conventional gaming machine, there is known a method of determining the number of payouts using a payout table when a symbol combination corresponding to a small winning combination is stopped on an activated line (for example, Japanese Patent Laid-Open No. 2006-130066). ).
Initially, the problem to be solved by the invention is to more appropriately determine the number of game media provided corresponding to the stop symbol combination on the activated line.

(B) Means for solving the problem of the first invention 37 (Note that the corresponding embodiment is described in parentheses.)
The original invention (25th embodiment) is
A predetermined storage area capable of storing data for specifying a stop symbol combination (stop symbol data (first group) to (ninth group) (_WK_STOP_PIC1 to 9)) is provided,
The data stored in the predetermined storage area and the data for determining whether or not the symbol combination giving the game value "X" is stopped (stored in the payout amount table (TBL_WIN_CTL) in FIG. 195). Data) and a predetermined calculation (processing shown in FIG. 200) can be executed,
Based on the calculation result of the predetermined calculation, it is possible to determine whether to give the game value “X” (for example, 15 cards),
When it is not decided to give the game value “X” based on the calculation result of the predetermined calculation (in FIG. 201, all bits of stop symbol data (fifth group), and stop symbol data (sixth group) If the result of checking the D0 to D3 bits of) is “No” in step S1118), the data stored in the predetermined storage area and the game value “Y” (Y≠X) (3 pieces) ), the predetermined calculation can be executed based on the data for determining whether or not the symbol combination to be given is stopped,
Based on the calculation result of the predetermined calculation, it is possible to determine whether or not to give the game value “Y”.

(C) Effect of Original Invention 37 According to the initial invention, since the payout number is used as a reference for searching in order, the payout number can be specified by a simple method.

38. Original invention 38
(A) Problem to be Solved by Initial Invention 38 Same as original invention 37.
(B) Means for solving the problem of the first invention 38 (Note that the corresponding embodiment is described in parentheses.)
The original invention (25th embodiment) is
A predetermined storage area capable of storing data for specifying a stop symbol combination (stop symbol data (first group) to (ninth group) (_WK_STOP_PIC1 to 9)),
An award number table (a payout amount table (TBL_WIN_CTL) in FIG. 193) storing data capable of specifying the award amount of game value,
The award number table stores at least collation data (designated data) for collating with data for identifying a stop symbol combination, and data (acquisition data) of a game value award number,
In a situation where the predetermined data is stored in the predetermined storage area, it is possible to determine the number of granted game values based on the predetermined data and the matching data stored in the number-of-applied table. To do.

(C) Effect of Original Invention 38 Same as Original Invention 37.

39. Original invention 39
(A) Problem to be Solved by Initial Invention 39 Same as original invention 37.
(B) Means for solving the problem of the first invention 39 (Note that the corresponding embodiment is described in parentheses.)
Initially, the invention (25th embodiment) of claim 1 is
A predetermined storage area capable of storing data for specifying a stop symbol combination (stop symbol data (first group) to (ninth group) (_WK_STOP_PIC1 to 9)) is provided,
As a symbol combination that gives the game value "X" (15), there are a plurality of symbol combinations (symbol combinations of small winning combination 01 to small winning combination 12),
At least one symbol combination (for example, a symbol combination of the small winning combination 13) is provided as a symbol combination that gives a game value "Y" (3).
Of the predetermined storage area, the data storage area (bit or address) for specifying the symbol combination to which the game value “X” is given is continuous,
Among the predetermined storage areas, there is a data storage area for specifying the symbol combination to which the game value "Y" is given, between a plurality of data storage areas for specifying the symbol combination to which the game value "X" is given. Try not to
After determining whether or not the symbol combination giving the game value “X” is stopped, it is possible to determine whether or not the symbol combination giving the game value “Y” is stopped.

Initially, the invention of claim 2 (25th embodiment) is
A predetermined storage area capable of storing data for specifying a stop symbol combination (stop symbol data (first group) to (ninth group) (_WK_STOP_PIC1 to 9)) is provided,
As a symbol combination that gives the game value "X" (15), there are a plurality of symbol combinations (symbol combinations of small winning combination 01 to small winning combination 12),
At least one symbol combination (for example, a symbol combination of the small winning combination 13) is provided as a symbol combination that gives a game value "Y" (3).
Of the predetermined storage area, the data storage area (bit or address) for specifying the symbol combination to which the game value “X” is given is continuous,
Among the predetermined storage areas, there is a data storage area for specifying the symbol combination to which the game value "Y" is given, between a plurality of data storage areas for specifying the symbol combination to which the game value "X" is given. Try not to
After determining whether or not the symbol combination giving the game value “Y” is stopped, it is possible to determine whether the symbol combination giving the game value “X” is stopped or not.

In the case where the “data storage area for specifying the symbol combination to which the gaming value “X” is given” is a bit unit as in the twenty-fifth embodiment, the symbol combination to which the “gaming value “X” is given is set. The data storage area for specifying is continuous," and, for example, in the stop symbol data (fifth group), 15 coins are paid out from the D0 bit corresponding to the small win 01 winning symbol that pays out 15 coins. It indicates that up to D7 bit corresponding to the small winning combination 08 winning symbol is continuous.
Further, between the plurality of data storage areas for specifying the symbol combination to which the "playing value "X" is given, there is no data storage area for specifying the symbol combination to which the game value "Y" is given, In the stop symbol data (fifth group), between the D0 bit corresponding to the small prize 01 winning symbol which pays out 15 cards, and the D7 bit corresponding to the small winning prize 08 winning symbol which pays out 15 cards. It indicates that there is no bit corresponding to the small winning award symbol for paying out three or one.

On the other hand, in the case where the “data storage area for specifying the symbol combination to which the game value “X” is given” is an address unit, as shown in the modified example described above,
Stop symbol data (5th group): Small winning combination 01 winning design to small winning combination 08 winning design (15 payouts)
Stop symbol data (6th group): Small winning 09 winning symbol to small winning 12 winning symbol (15 payouts)
Stop symbol data (7th group): Small winning combination 13 winning symbol to small winning combination 20 winning symbol (3 payouts)
Stop symbol data (8th group): Small prize 21 prize symbol to small prize 24 prize symbol (3 pieces payout)
Stop symbol data (9th group): Small winning 25 winning symbol to small winning 32 winning symbol (1 payout)
Stop symbol data (10th group): Small winning symbol 33 winning symbol to small winning symbol 34 winning symbol (1 payout)
This corresponds to the case where separate addresses are provided for each number of payouts.
In this case, "the data storage area for specifying the symbol combination to which the game value "X" is given is continuous," means, for example, 15 symbols of stop symbol data (fifth group) and stop symbols. This indicates that the addresses of the data (sixth group) are continuous.
Further, between the plurality of data storage areas for specifying the symbol combination to which the "playing value "X" is given, there is no data storage area for specifying the symbol combination to which the game value "Y" is given, ", between the address of the stop symbol data (fifth group) and the address of the stop symbol data (sixth group) that pays out 15 sheets, the address of the stop symbol data (seventh group) to the stop symbol data ( It indicates that the address of the 10th group) does not exist.

(C) Effect of Original Invention 39 According to the initial invention, a predetermined operation can be executed in the order of addresses in a predetermined storage area, and the program can be simplified.

40. Original invention 40
(A) Problem to be solved by the initial invention 40 Same as the original invention 37.
(B) Means for solving the problem of the first invention 40 (Note that the corresponding embodiment is described in parentheses.)
The original invention (26th embodiment) is
An award number table (a payout amount table (TBL_WIN_CTL) in FIGS. 220 and 221) for determining the award amount of the game value is provided.
Predetermined data can be generated based on the stop symbol combination,
The address of the number-of-applied table can be specified based on the bit position having the predetermined value in the predetermined data (steps S1189 to S1192 in FIG. 227).
The number of grants can be determined based on the data stored in the address of the grant number table (steps S1192 and S1193 of FIG. 227).
It is characterized by

(C) Effect of Original Invention 40 According to the original invention, only the bit corresponding to the winning is a predetermined value, so that the payout number can be specified by a simple method.

41. Original invention 41
(A) Problem to be Solved by Initial Invention 41 The initial invention relates to a gaming machine that uses a stepping motor as a motor for rotating a reel.
In a conventional gaming machine, it is known that a stepping motor is used as a motor for rotating a reel and a 4-phase excitation output is provided to the stepping motor when the reel is stopped (for example, JP-A-2015-016110). Publication).
Here, in the conventional gaming machine, it is general to use a DC motor (DC motor) as a hopper motor for rotating the hopper disk.
However, since the DC motor requires a relatively large current at the time of driving, if the game medium can be added while the stepping motor is performing the four-phase excitation output, the drive control of the hopper accompanying the addition of the game medium will be performed. There is a possibility that the required current cannot be secured.
Initially, the problem to be solved by the invention is to ensure a current necessary for drive control of a hopper accompanying application of a game medium.

(B) Means for solving the problem of the first invention 41 (Note that the corresponding embodiment is described in parentheses.)
The original invention (29th embodiment) is
Equipped with "N" (3) reels (31),
When the number of credits is the upper limit value (“50”), a predetermined lottery result is obtained (for example, the winning lottery means 61 wins the winning number “10”, the small win A1 condition device operates, and 15 coins are activated. In the situation in which the winning combination of the small winning combination 01 or the small winning combinations 13 to 17 of the three payouts is possible) and the reels of "N-1" (two) are stopped, The operation of the stop switch (42) corresponding to the "N"th (third) reel is accepted, and the specific symbol combination in which the game medium (medal) is given (for example, a small payout of 3 pieces is given. In the game in which the symbol combination corresponding to the combination 13) is stopped and displayed, after the operation of the stop switch corresponding to the "N"th reel is accepted, the excitation output for stopping the "N"th reel Even if the stop switch corresponding to the "N"th reel is released at a predetermined timing before the predetermined period of time, the drive signal of the hopper (35) is passed after the predetermined period. Drive signal output processing to output
When the number of credits is "0", the predetermined lottery result is obtained, and under the situation where "N-1" reels are stopped, operation of the stop switch corresponding to the "N" reel Is accepted, in the game in which the specific symbol combination is stopped and displayed, after the operation of the stop switch corresponding to the "N"th reel is accepted, the excitation for stopping the "N"th reel Even when the stop switch corresponding to the "N"th reel is released at a predetermined timing before the predetermined period for performing the output has elapsed, the credit number is added after the predetermined period has elapsed. The feature is that processing can be executed.

(C) Effect of the first invention 41 According to the first invention, the hopper drive signal can be output after the elapse of a predetermined period for performing the excitation output for stopping the reel, so that the hopper is driven according to the addition of the game medium. The current required for control can be secured.
Further, the number of credits is the upper limit value, and when the hopper is driven to give the game medium, and when the number of credits is "0" and the number of credits is added to give the game medium, the reel It is possible to perform common processing until a predetermined period for performing the excitation output for stopping the is passed. As a result, the processing can be simplified and the amount of ROM used by the program can be reduced.

42. Original invention 42
(A) Problem to be Solved by Initial Invention 42 Same as original invention 41.
(B) Means for solving the problem of the first invention 42 (Note that the corresponding embodiment is described in parentheses.)
The original invention (29th embodiment) is
Equipped with "N" (3) reels (31),
A predetermined lottery result is obtained (for example, the winning lottery means 61 wins the winning number "10", the small win A1 condition device is activated, and a small win 01 of 15 payouts or three payouts is made. In the situation where any of the small winning combinations 13 to 17 can win, and the "N-2" (1) reel is stopped, the "N-1" (2nd) reel is When the operation of the stop switch (42) corresponding to the “N”th reel (third reel) is accepted at a predetermined timing before the predetermined period of performing the excitation output for stopping has elapsed. Also makes it possible to execute control for stopping the "N"th reel,
In the situation where the predetermined lottery result is obtained and the “N−1” reels are stopped, the operation of the stop switch corresponding to the “N”th reel is accepted, and the game medium (medal) In the game in which the specific symbol combination to be given (for example, the symbol combination corresponding to the small winning combination 13 of three payouts) is stopped and displayed, the operation of the stop switch corresponding to the "N"th reel is accepted. After that, the stop switch corresponding to the “N”th reel is released at a predetermined timing before a predetermined period of time for performing the excitation output for stopping the “N”th reel has elapsed. However, it is characterized in that the control for giving the game medium can be executed after the lapse of the predetermined period.

(C) Effect of Original Invention 42 According to the initial invention, since the control for applying the game medium can be executed after the elapse of the predetermined period of performing the excitation output for stopping the reel, the hopper accompanying the application of the game medium is executed. It is possible to secure the current required for the drive control of.
In addition, even before the elapse of the predetermined period for performing the excitation output for stopping the "N-1"th reel, the control for stopping the "N"th reel can be executed. , The game can proceed smoothly.

43. Original invention 43
(A) Problem to be Solved by Initial Invention 43 Same as original invention 41.
(B) Means for solving the problem of the first invention 43 (Note that the corresponding embodiment is described in parentheses.)
The original invention (29th embodiment) is
Equipped with "N" (3) reels (31),
A predetermined lottery result is obtained (for example, the winning lottery means 61 wins the winning number "10", the small win A1 condition device is activated, and a small win 01 of 15 payouts or three payouts is made. In the situation where any of the small winning combinations 13 to 17 can win, and the "N-2" (1) reel is stopped, the "N-1" (2nd) reel is When the operation of the stop switch (42) corresponding to the “N”th reel (third reel) is accepted at a predetermined timing before the predetermined period of performing the excitation output for stopping has elapsed. Also makes it possible to execute control for stopping the "N"th reel,
In the situation where the predetermined lottery result is obtained and the “N−1” reels are stopped, the operation of the stop switch corresponding to the “N”th reel is accepted, and the game medium (medal) In the game in which the specific symbol combination to be given (for example, the symbol combination corresponding to the small winning combination 13 of three payouts) is stopped and displayed, the operation of the stop switch corresponding to the "N"th reel is accepted. After that, the stop switch corresponding to the “N”th reel is released at a predetermined timing before a predetermined period of time for performing the excitation output for stopping the “N”th reel has elapsed. Even after the lapse of the predetermined period of time, it becomes possible to execute the control of adding the game medium,
It is characterized in that the maximum value of the current required for the excitation output for stopping the reel is designed to be smaller than the maximum value of the current required for driving the hopper.

(C) Effect of Initial Invention 43 According to the initial invention, since the control for imparting the game medium can be executed after the elapse of the predetermined period for performing the excitation output for stopping the reel, the hopper accompanying the impartation of the game medium can be executed. It is possible to secure the current required for the drive control of.
In addition, even before the elapse of the predetermined period for performing the excitation output for stopping the "N-1"th reel, the control for stopping the "N"th reel can be executed. , The game can proceed smoothly.
Furthermore, the maximum current required to drive the hopper is less than the maximum current required to drive the hopper, so the stop control of multiple reels can be performed simultaneously. Can be

44. Original invention 44
(A) Problems to be Solved by Initial Invention 44 Same as original invention 41.
(B) Means for solving the problem of the first invention 44 (Note that the corresponding embodiment is described in parentheses.)
The original invention (30th embodiment) is
"N" (3) reels (31),
Storage means (# reel management timer (_WK_RL#_TIME) of RWM53) capable of storing information (data of "0 to 108 (D)") for measuring the period for performing the excitation output for stopping the reel (Fig. 237) ) And
A predetermined lottery result is obtained (for example, the winning number “10” is won by the winning lottery means 61, the small winning role A1 condition device is activated, and a small winning number 01 of 15 payouts or three paying out is achieved. It corresponds to the “N”th reel (third reel) under the situation where “N-1” reels (2 reels) are stopped and any of the small wins 13 to 17 can be won. In the game in which the operation of the stop switch (42) is accepted, the specific symbol combination (for example, the symbol combination corresponding to the small winning combination 13 of three payouts) in which the game medium (medal) is given is stopped and displayed. , At a predetermined timing after the operation of the stop switch corresponding to the “N”th reel is received and before the period for performing the excitation output for stopping the “N”th reel has elapsed. , Even when the stop switch corresponding to the “N”th reel is released (“No” in step S1314 of FIG. 238), the information stored in the storage means is a predetermined value (“0”). ) (“Yes” in step S1342 of FIG. 241), control for assigning a game medium (medal payout at the time of winning in step S294 of FIG. 238) can be executed.

(C) Effect of Original Invention 44 According to the initial invention, a storage unit capable of storing information for measuring a period for performing the excitation output for stopping the reel is provided, and the information stored in the storage unit has a predetermined value. After that, it becomes possible to execute the control of adding the game medium, so that it is possible to secure the current necessary for the drive control of the hopper accompanying the addition of the game medium.
Further, it is possible to easily judge that the period for performing the excitation output for stopping the reel has elapsed based on the information stored in the storage means.

45. Original invention 45
(A) Problem to be Solved by Initial Invention 45 Same as original invention 41.
(B) Means for solving the problem of the first invention 45 (Note that the corresponding embodiment is described in parentheses.)
The original invention (31st embodiment) is
"N" (3) reels (31),
Storage means capable of storing information regarding the excitation output of the motor related to the reel (# reel motor signal data of RWM53 (_PT_MOTOR#) (FIG. 134)),
A predetermined lottery result is obtained (for example, the winning number “10” is won by the winning lottery means 61, the small winning role A1 condition device is activated, and a small winning number 01 of 15 payouts or three paying out is achieved. It corresponds to the “N”th reel (third reel) under the situation where “N-1” reels (2 reels) are stopped and any of the small wins 13 to 17 can be won. In the game in which the operation of the stop switch (42) is accepted and the specific symbol combination (for example, the symbol combination corresponding to the small winning combination 13 of three payouts) in which the game medium (medal) is given is stopped and displayed. , Information indicating that the excitation output for stopping the “N”th reel is performed after the operation of the stop switch corresponding to the “N”th reel is received (pulse data at deceleration “ 000011111(B)" (4 phase ON)) is stored in the storage means ("Yes" in step S1355 of FIG. 242), and the stop switch corresponding to the "N"th reel is released ( In the case of "No" in step S1354 of FIG. 242), the information stored in the storage means is not the predetermined information, without executing the control of giving the game medium (medal payout at the time of winning in step S294 of FIG. 242). After (stop time pulse data “00000000(B)”) has been reached (“No” in step S1355 of FIG. 242), the control of assigning the game medium can be executed.

(C) Effect of Original Invention 45 According to the initial invention, the storage means is provided which is capable of storing information regarding the excitation output of the motor related to the reel, and the information indicating that the excitation output for stopping the reel is provided is the storage means. When it is stored in, the control for adding the game medium is not executed, but the control for adding the game medium can be executed after the information stored in the storage means becomes the predetermined information. It is possible to secure the electric current required for drive control of the hopper accompanying the application of the medium.
Further, it is possible to easily judge that the period for performing the excitation output for stopping the reel has elapsed based on the information stored in the storage means.

46. Original invention 46
(A) Problem to be Solved by Initial Invention 46 Same as original invention 41.
(B) Means for Solving the Problem of Original Invention 46 (Note that the corresponding embodiment is described in parentheses.)
The original invention (31st embodiment) is
Equipped with "N" (3) reels (31),
A predetermined lottery result is obtained (for example, the winning number “10” is won by the winning lottery means 61, the small winning role A1 condition device is activated, and a small winning number 01 of 15 payouts or three paying out is achieved. It corresponds to the “N”th reel (third reel) under the situation where “N-1” reels (2 reels) are stopped and any of the small wins 13 to 17 can be won. In the game in which the operation of the stop switch (42) is accepted, the specific symbol combination (for example, the symbol combination corresponding to the small winning combination 13 of three payouts) in which the game medium (medal) is given is stopped and displayed. , After the stop switch corresponding to the “N”th reel is released (“No” in step S1354 of FIG. 242), and the excitation output for stopping the “N”th reel is performed. Even under the situation (“Yes” in step S1355 in FIG. 242), the number of game media to be added can be determined (display determination in step S291 in FIG. 242), and after the number of game media to be added is determined. Then, after the excitation output for stopping the “N”th reel is finished (“No” in step S1355 of FIG. 242), the control of giving the game medium (the medal at the time of winning in step S294 of FIG. 242) It is characterized in that it can be executed.

(C) Effect of Original Invention 46 According to the initial invention, since the control of adding the game medium can be executed after the excitation output for stopping the “N”th reel is completed, the addition of the game medium is performed. It is possible to secure the current required for drive control of the hopper.
Further, if the stop switch corresponding to the "N"th reel is released, the number of game media provided is increased even under the condition that the excitation output for stopping the "N"th reel is being performed. Since it is possible to determine, it is possible to shorten the time from the release of the stop switch corresponding to the "N"th reel to the execution of the control for adding the game medium.

47. Original invention 47
(A) Problem to be Solved by Initial Invention 47 The initial invention relates to a gaming machine that gives a game medium when a predetermined symbol combination is stopped and displayed.
In conventional gaming machines, when all reels are stopped, then it is determined whether all stop switches are released (none of the stop switches is operated), and all stop switches are released. It is known that when it is determined that there is a symbol combination to which a game medium is given, whether or not the symbol combination is stopped and displayed (prize determination) (for example, JP-A-2016-026717).
However, if the winning determination is performed after all the stop switches are released, the processing of the winning determination will be delayed when the player continues to operate the stop switch corresponding to the reel that is stopped last.
Initially, the problem to be solved by the invention is to shorten the time from the acceptance of the operation of the stop switch corresponding to the “N”th reel to the determination of the number of game media to be provided, and the subsequent game media It is to be able to execute the grant smoothly.

(B) Means for solving the problem of the first invention 47 (Note that the corresponding embodiment is described in parentheses.)
The original invention (32nd embodiment) is
Equipped with "N" (3) reels (31),
A predetermined lottery result is obtained (for example, the winning number “10” is won by the winning lottery means 61, the small winning role A1 condition device is activated, and a small winning number 01 of 15 payouts or three paying out is achieved. Any one of the small winning combinations 13 to 17 can be won), and by operating the stop switch (42) in a predetermined operation mode (correct answer pressing order), a specific symbol combination in which a game medium (medal) is given ( For example, in the game in which the symbol combination corresponding to the small winning combination 01 that pays out 15 cards) is stopped and displayed, the operation of the stop switch corresponding to the “N”th (third) reel is accepted and the stop is performed. Even when the state where the operation of the switch is accepted continues, it is possible to determine the number of game media to be provided (display determination in step S291 of FIG. 244), and after determining the number of game media to be provided, When it is determined whether or not a predetermined switch including a stop switch corresponding to at least the "N"th reel is operated, and it is determined that the predetermined switch is not operated (in step S1362 of FIG. 244, " No”) is capable of executing control for giving a game medium (medal payout at the time of winning in step S294 of FIG. 244).
The original invention was
Equipped with "N" reels,
A predetermined lottery result is obtained, and by operating the stop switch in a predetermined operation mode, in the game in which the specific symbol combination in which the game medium is given is stopped and displayed, the stop corresponding to the "N" reel Even when the operation of the switch is accepted and the state where the operation of the stop switch is accepted continues, the number of game media to be added can be determined, and after determining the number of game media to be added, “ It is characterized in that it is judged whether or not the stop switch corresponding to the N'th reel is operated, and if it is judged that the stop switch is not operated, the control for giving the game medium can be executed.

(C) Effect of Original Invention 47 According to the initial invention, it is possible to determine the number of game media to be provided even if the operation of the stop switch corresponding to the “N”th reel continues to be accepted. Therefore, it is possible to shorten the time from when the operation of the stop switch corresponding to the "N"th reel is accepted until the number of game media to be provided is determined, and the subsequent application of game media is smoothly performed. be able to.
In addition, after determining the number of game media to be provided, it is determined whether or not the stop switch corresponding to the “N”th reel has been operated. Since it is executable, the game medium can be added at a timing desired by the player.

48. Original invention 48
(A) Problems to be Solved by Original Invention 48 Same as Original Invention 41.
(B) Means for solving the problem of the first invention 48 (Note that the corresponding embodiment is described in parentheses.)
The original invention (third embodiment) is
Equipped with "N" (3) reels (31),
In the game in which the predetermined lottery result is obtained (for example, the winning lottery means 61 wins the winning number "7", and the "1BB+cherry" condition device corresponding to the winning number "7" operates), "N-1" Under the condition that the number (two) reels is stopped, the operation of the stop switch (42) corresponding to the “N”th (third) reel is accepted, and the specific symbol combination (for example, cherry). When the "cherry"-"ANY"-"ANY" symbol combination corresponding to (one-card combination) is stopped and displayed, the operation of the stop switch corresponding to the "N"th reel is accepted. Even under the condition where the state continues, after the exciting output for stopping the "N"th reel is finished ("No" in step S1413 of FIG. 251), the game medium (medal) is loaded. It is possible to execute the giving control (medal payout at the time of winning in step S294 of FIG. 251), and when the operation of the stop switch corresponding to the “N”th reel is accepted, the game medium giving control is executed. If the game continues after that, a predetermined effect regarding the game result is output after the stop switch corresponding to the “N”th reel is released (“No” in step S1415 of FIG. 251). (The production lamp is turned on to notify the winning of the 1BB condition device).

(C) Effect of Original Invention 48 According to the initial invention, since the control of adding the game medium can be executed after the excitation output for stopping the “N”th reel is completed, the addition of the game medium is performed. It is possible to secure the current required for drive control of the hopper.
Further, when the stop switch corresponding to the "N"th reel is released, there is a case where a predetermined effect regarding the game result is executed, so that the predetermined effect regarding the game result is executed at a timing desired by the player. Can be done.

49. Original invention 49
(A) Problem to be Solved by Initial Invention 49 The initial invention relates to a gaming machine including a plurality of reels and a plurality of stop switches operated by a player when stopping each reel.
In conventional gaming machines, when rotation of all reels reaches a constant speed and the indexes of all reels are detected, it is possible to perform reel stop control for all reels based on operation of a stop switch. (For example, Japanese Patent Laid-Open No. 2016-026717).
The problem to be solved by the invention at the beginning is to make it possible to determine whether or not the indexes of all reels have been detected by a simple arithmetic process.

(B) Means for solving the problem of the first invention 49 (Note that the corresponding embodiment is described in parentheses.)
The original invention (34th embodiment) is
Equipped with "N" (3) reels (31),
Each reel is provided with a storage means (# reel driving state (_WK_RL#_STS) (FIG. 253)) capable of storing information on the reel driving state,
A predetermined operation (an AND operation of the data stored in the # reel drive state (_WK_RL#_STS) and "40(H)") can be executed by using the information stored in each of the storage means,
Even when the plurality of reels are rotating at a constant speed, if the index is not yet detected for any of the reels, the predetermined result (“0” (zero flag is set to “1 )))
Even when the stop switch (42) is operated, if the predetermined result is not obtained as a result of executing the predetermined calculation, the reel stop control corresponding to the stop switch is not executed.
The original invention was
Equipped with "N" reels,
Each reel is provided with a storage means capable of storing information about the driving state of the reel,
A predetermined calculation can be executed using the information stored in each of the storage means,
Even when a plurality of reels are rotating at a constant speed, if the index is not yet detected for any of the reels, the predetermined result is not obtained even if the predetermined calculation is executed,
In a situation where the predetermined result is not obtained as a result of executing the predetermined calculation, even if the stop switch is operated, the reel stop control corresponding to the stop switch is not executed.

(C) Effect of Original Invention 49 According to the initial invention, it is possible to judge whether or not the indexes of all reels have been detected, depending on whether or not the predetermined result is obtained as a result of executing the predetermined calculation. It is possible to determine whether or not the reel stop control based on the operation of the stop switch can be executed by various arithmetic processes.

50. Original invention 50
(A) Problem to be Solved by Initial Invention 50 The initial invention relates to a gaming machine that starts rotation of a reel based on operation of a start switch.
In conventional gaming machines, when all reels are stopped, then it is determined whether all stop switches are released (none of the stop switches is operated), and all stop switches are released. It is known that when it is determined that there is a symbol combination to which a game medium is given, whether or not the symbol combination is stopped and displayed (prize determination) (for example, JP-A-2016-026717).
Initially, the problem to be solved by the invention is to execute appropriate control according to the type of other input signal when the operation of the start switch is accepted.

(B) Means for solving the problem of the first invention 50 (Note that the corresponding embodiment is described in parentheses.)
The original invention (34th embodiment) is
When the start switch operation is accepted after the bet number at which the game can be executed has been bet and the bet switch operation has been accepted (input port 0 level data (_PT_IN0_OLD) of the RWM 53 (_PT_IN0_OLD) ( (When the result of the AND operation of the data of FIG. 254) and “11011111(B)” is not “0”), the rotation start control of the reel based on the operation of the start switch is not executed,
Based on the operation of the start switch when the operation of the start switch is accepted under a predetermined condition that the signal of the setting key switch is input after the bet number for which the game can be executed is bet Reel rotation start control can be executed,
In a specific situation where the bet number is not bet, when the signal of the setting key switch is input, it is possible to shift to a mode in which the set value can be confirmed.

(C) Effect of Initial Invention 50 According to the initial invention, when the operation of the start switch is accepted while the operation of the bet switch is accepted, the rotation start control of the reel is not executed. It is possible to let a player or a store clerk in the hall recognize that an abnormality such as not returning to the original state has occurred due to the deterioration.
In addition, when the operation of the start switch is accepted while the signal of the setting key switch is being input, the reel rotation start control is executed, but the signal of the setting key switch is noisy while the game is in progress. Since there is a high possibility, it is possible to prevent the progress of the game from being interrupted by noise.

51. Original invention 51
(A) Problem to be Solved by Initial Invention 51 The initial invention relates to a gaming machine that stops a reel based on an operation of a stop switch.
In conventional gaming machines, when all reels are stopped, then it is determined whether all stop switches are released (none of the stop switches is operated), and all stop switches are released. It is known that when it is determined that there is a symbol combination to which a game medium is given, whether or not the symbol combination is stopped and displayed (prize determination) (for example, JP-A-2016-026717).
Initially, the problem to be solved by the invention is to execute appropriate control according to the type of other input signal when the operation of the stop switch is accepted.

(B) Means for solving the problem of the first invention 51 (Note that the corresponding embodiment is described in parentheses.)
The original invention (34th embodiment) is
With multiple (3) reels (31),
When a plurality of reels rotate at a constant speed and the operation of the start switch (41) is accepted, when the operation of the predetermined stop switch is accepted, the reel based on the operation of the predetermined stop switch. Stop control is not executed (the data of the input port 0 level data (_PT_IN0_OLD) (FIG. 254) does not match any of the data of the stop switch determination table (FIG. 255), the result is “No” in step S1435 of FIG. 257. , Do not proceed to step S1437),
When the operation of the predetermined stop switch is accepted under a predetermined condition in which the plurality of reels are rotating at a constant speed and the signal of the setting key switch is input, the reel based on the operation of the predetermined stop switch Stop control can be executed (even if the signal of the setting key switch is input, the data of the input port 0 level data (_PT_IN0_OLD) (Fig. 254) and any data of the stop switch determination table (Fig. 255) If they match, it becomes “Yes” in step S1435 of FIG. 257, and the process proceeds to step S1437).
In a specific situation where the bet number is not bet, when the signal of the setting key switch is input, it is possible to shift to a mode in which the set value can be confirmed.

(C) Effect of Initial Invention 51 According to the initial invention, when the operation of the start switch is accepted and the operation of the stop switch is accepted, the reel stop control is not executed. It is possible to let a player or a store clerk in the hall recognize that an abnormality such as the original state not occurring due to deterioration has occurred.
Also, when the operation of the stop switch is accepted while the signal of the setting key switch is being input, the reel stop control is executed, but the signal of the setting key switch is noise during the progress of the game. Since the possibility is high, it is possible to prevent the progress of the game from being interrupted by noise.

52. Original invention 52
(A) Problem to be Solved by Initial Invention 52 The initial invention relates to a gaming machine that stops a reel based on an operation of a stop switch.
In conventional gaming machines, when all reels are stopped, then it is determined whether all stop switches are released (none of the stop switches is operated), and all stop switches are released. It is known that when it is determined that there is a symbol combination to which a game medium is given, whether or not the symbol combination is stopped and displayed (prize determination) (for example, JP-A-2016-026717).
Initially, the problem to be solved by the invention is to execute appropriate control when operations of a plurality of stop switches are simultaneously accepted.

(B) Means for solving the problem of the first invention 52 (Note that the corresponding embodiment is described in parentheses.)
The original invention (35th embodiment) is
With multiple (3) reels (31),
If the operation of the first stop switch (42) and the operation of the second stop switch are simultaneously accepted under the condition that the plurality of reels are rotating at a constant speed, the operation corresponds to the first stop switch. The reel stop control can be executed (input port rising data A (_PT_IN_A_UP) (FIG. 133) and the reel stop flag (_FL_STOP_LP) (FIG. 173) as an offset value, which is the reference address “1100”. (H)” is used as the designated address, and the stop control of the reel 31 is executed based on the data indicated by the designated address in the stop switch acceptance table (TBL_STOP_BTN) (FIG. 259).
When the reel corresponding to the first stop switch is stopped and the reel corresponding to the second stop switch is rotating at a constant speed, the operation of the first stop switch and the operation of the second stop switch are If both are accepted at the same time, the reel stop control corresponding to the second stop switch can be executed.

(C) Effect of Initial Invention 52 According to the initial invention, when the operations of the plurality of stop switches are simultaneously accepted, the stop control of any one reel can be appropriately executed.

53. Original invention 53
(A) Problem to be Solved by Initial Invention 53 Same as original invention 52.
(B) Means for solving the problem of the first invention 53 (Note that the corresponding embodiment is described in parentheses.)
The original invention (35th embodiment) is
A plurality of (3) reels (31),
With a predetermined table (stop switch reception table (TBL_STOP_BTN) (Fig. 259)),
When the operation of the first stop switch and the operation of the second stop switch are simultaneously accepted under the condition where the plurality of reels are rotating at a constant speed, the predetermined information is obtained using the predetermined table. (The result of the logical product operation of the input port rising data A (_PT_IN_A_UP) (Fig. 133) and the reel stop flag (_FL_STOP_LP) (Fig. 173) was taken as an offset value, and this was added to the reference address "1100 (H)". With the result as the designated address, the data indicated by the designated address is acquired from the stop switch reception table (TBL_STOP_BTN) (Fig. 259), and the reel stop control corresponding to the first stop switch can be executed based on the predetermined information. age,
When the reel corresponding to the first stop switch is stopped and the reel corresponding to the second stop switch is rotating at a constant speed, the operation of the first stop switch and the operation of the second stop switch are When received at the same time, the specific information is obtained using the predetermined table, and the stop control of the reel corresponding to the second stop switch can be executed based on the specific information. ..

(C) Effect of Initial Invention 53 According to the initial invention, when the operations of the plurality of stop switches are simultaneously accepted, the stop control of any one reel can be appropriately executed.

54. Original invention 54
(A) Problem to be Solved by Initial Invention 54 The initial invention relates to a gaming machine that stops a reel based on an operation of a stop switch.
In conventional gaming machines, when all reels are stopped, then it is determined whether all stop switches are released (none of the stop switches is operated), and all stop switches are released. It is known that when it is determined that there is a symbol combination to which a game medium is given, whether or not the symbol combination is stopped and displayed (prize determination) (for example, JP-A-2016-026717).
Initially, the problem to be solved by the invention is that a stop switch corresponding to a predetermined reel is operated, and then a stop switch corresponding to a specific reel is operated before the predetermined reel is stopped to stop the specific reel first. When the predetermined reel is stopped later, the proper control is executed.

(B) Means for solving the problem of the first invention 54 (Note that the corresponding embodiment is described in parentheses.)
The original invention (36th embodiment) is
With multiple (3) reels (31),
A predetermined lottery result is obtained (for example, the winning lottery means 61 wins the winning number "25", the 1BB condition device corresponding to the winning number "25" operates, and the "blue BAR"-"blue BAR" corresponding to 1BB. ]-"Blue BAR" symbol combination can be stopped and displayed on the activated line) In the game, the stop switch (42) corresponding to the predetermined reel is operated at the first timing, and then the predetermined reel is stopped. Before, when the stop switch corresponding to the specific reel is operated at the second timing, there is a case where the predetermined reel is stopped after the specific reel is stopped,
As a result of the predetermined reel stopping after the specific reel has stopped, when the symbols constituting the specific symbol combination (“blue BAR”-“blue BAR”-“blue BAR”) are stopped and displayed on a straight line, the predetermined reel is It is characterized in that a predetermined effect (temple sound) can be output according to the timing of stopping.

(C) Effect of Initial Invention 54 According to the initial invention, even if the operation order of the stop switch and the stop order of the reels are different, it is possible to output the predetermined effect at an appropriate timing that does not give the player a feeling of strangeness. ..

10 slot machines (gaming machines)
11 Power Switch 12 Front Door 12a Second Block 12b Third Block 12c Control Panel 12d Index 13 Cabinet 13a Bottom Plate 13b Back Plate 13c First Block 14 Pattern Display 14a Reel Frame 15 Medal Payout Device 16 Medal Payout 17 Door Switch 18 Display window 21 Effect lamp 22 Speaker 23 Image display device 24 Operation button 25 Operation instruction lamp 31 Reel 32 Motor 33 Reel sensor 35 Hopper 36 Hopper motor 37a, 37b Discharge sensor 38a Fixed shaft 38b Movable shaft 39a Movable piece 39b Spring 40a 1 Bet switch 40b 3 Bet switch 41 Start switch 42 Stop switch 42a Stop button 42b Stopper 42c Coil spring 42d Moving piece 42e Detection sensor 43 Adjustment switch 44a, 44b Insertion sensor 45 Blocker 46 Passage sensor 47 Medal insertion slot 47a Medal guard part 47b Medal holder Part 48 Chute passage 49 Chute sensor 50 Main control board (main control means)
50a Screw hole 51 Input port 52 Output port 53 RWM
54 ROM
55 Main CPU
56 board case (main board case)
57 Upper cover 57a Caulking part 57b Gate mark 57c Recessed part 57d Protrusion 57e Projection part 58 Lower cover 58a Caulking part 58b Gate mark 58c Boss 61 Hand lottery means 62 Winning flag control means 63 Pushing order instruction number selection means 64 Production group number selection means 65 reel control means 66 winning determination means 67 payout means 71 control command transmission means 73 set value display LED
74 Management information display LED (role ratio monitor)
75 display board 76 credit number display LED
77 Advantageous zone display LED
78 Acquisition number display LED
79 Status display LED
79a 1-bet display LED
79b 2 bet display LED
79c 3-bet display LED
79d Game start display LED
79e Input LED
79f Replay display LED
80 Sub control board (sub control means)
81 Input port 82 Output port 83 RWM
84 ROM
85 Sub CPU
86 Electrolytic Capacitor 87 Sub Board Case 91 Production Output Control Means 101 Hopper Disk 102 Holding Section 103 Discharging Section 110 Reel Base 120 Reel Control Board 121 Reel Board Case 130 Passage Forming Member 131 Upper Medal Inlet 132 Return Medal Passage 133 Lower Medal Inlet 134 Payout medal passage 151 Setting key insertion slot 152 Setting key switch 153 Setting change (reset) switch 500 Pachinko game machine 501 Outer frame 502 Front frame 503 Hinge mechanism 504 Game board 505 Glass door 506 Upper plate 507 Lower plate 508 Launching handle 510 Power supply Board 511 Power switch 512 Launch board 513 Launcher 520 Discharge control board 521 Key insertion opening 522 Door opening switch 523 Frame opening switch 524 Dispensing device 525 External terminal board 530 Main control board 530a hole 531 Special pattern display device 532 Starting port 533 Starting port Switch 534 Setting key insertion slot 535 Setting key switch 536 Setting change (reset) switch 537 Setting value display LED
538 Management information display LED (performance display monitor)
539a to 539h connector 539b' to 539h' connector foot 540 sub control board 541 production lamp 542 speaker 543 image display device 550 board case 560 upper case 560a lower edge 561 cover 562 caulking portion 563a to 563g opening portion 564 boss 565 side wall lower case 570 570a Outer edge 571 Side wall 572 Caulking portion B to H harness

Claims (1)

As a reel, at least a first reel and a second reel are provided,
It has a first position which is a reference position of the first reel and a second position which is a symbol position on at least one effective line of the first reel (the second position is different from the first position),
A third position which is a reference position of the second reel (the third position and the first position are located on the same horizontal line), and a symbol position which is on at least one effective line of the second reel. 4 positions (the 4th position and the 2nd position are not located on the same horizontal line, and the 4th position and the 3rd position may be different positions or may be the same position).
A first data table in which symbol data corresponding to the first reel (“symbol data” means data indicating the type of symbol. The same applies hereinafter) ,
And a second data table storing the symbol data corresponding to the second reel ,
In the storage area of the first address of the first data table, the symbol data of the reference symbol number of the first reel is stored,
In the game in which the symbol of the predetermined symbol number of the first reel stops at the first position, the symbol data of the symbol stopped at the second position can be acquired from the first data table based on the predetermined symbol number,
In the storage area of the first address of the second data table, the symbol data of the reference symbol number of the second reel (the reference symbol number of the second reel and the reference symbol number of the first reel are different) are stored. ,
In the game in which the symbol of the specific symbol number of the second reel stops at the third position, the symbol data of the symbol that stops at the fourth position can be acquired from the second data table based on the specific symbol number. And the gaming machine.