JP6933801B2 - Pachinko machine - Google Patents

Description

In the present invention, the value of the total number of game media granted, the total number of game media granted in the game in which the accessory is activated, and the total number of game media granted in the game informing the advantageous operation mode of the stop switch are used. It relates to a gaming machine that displays a based ratio on a role ratio monitor.

In a conventional gaming machine, four 7-segments provided on the main control board provide an advantageous section ratio, a continuous bonus ratio (6000 times), a bonus ratio (6000 times), a continuous bonus ratio (cumulative), and a combination. A gaming machine provided with a so-called "combination ratio monitor" that sequentially displays the object ratio (cumulative) is known (see, for example, FIGS. 3 and 38 of Patent Document 1).

Japanese Patent No. 6112524

However, in the above-mentioned conventional technique, although it is possible to confirm the ratio of the accessory such as 1BB, it is not possible to confirm how much the medal is paid out when the instruction function (ART) which is not the accessory is activated. ..
In particular, the instruction function is not the accessory itself, but has a function similar to the accessory. However, since it is not possible to know how many medals have been paid out by the operation of the instruction function, it is not possible to judge from the role ratio monitor whether or not there is a risk of remarkably intriguing gambling.
The problem to be solved by the present invention is the value of the total number of game media granted, the number of game media granted in the game in which the accessory is activated, and the number of game media granted in the game informing the advantageous operation mode of the stop switch. It is to be able to confirm the ratio based on the total value of.

The present invention solves the above-mentioned problems by the following solutions. In addition, the configuration of the corresponding embodiment is shown in parentheses.
The present invention (31st embodiment)
The first display means (management information display LED74 (role ratio monitor)) and
The second display means (acquired number display LED78 that notifies the correct answer pressing order) and
A first storage means (total payout (cumulative) counter) that can store the value of the total number of game media granted, and
It is possible to store the total value of the number of game media granted in the game in which the accessory is activated and the number of game media granted in the game in which the second display means is notified of the advantageous operation mode (correct answer pressing order) of the stop switch. Equipped with a second storage means (character instruction counter (cumulative))
In a predetermined situation where the value stored in the first storage means does not reach the predetermined upper limit value (3 bytes full), the game is a game in which the accessory does not operate, and the stop switch is used as the second display means. In the game in which the advantageous operation mode is not notified, the value stored in the second storage means is not updated regardless of the presence or absence of the game medium.
It is characterized in that predetermined ratio information (character instruction ratio) based on the value stored in the first storage means and the value stored in the second storage means can be displayed on the first display means. ..

According to the present invention, the value of the total number of game media granted, the total number of game media granted in the game in which the accessory is activated, and the total number of game media granted in the game in which the advantageous operation mode of the stop switch is notified. Since the ratio based on and can be confirmed, it is possible to confirm whether or not the ratio is within the design range.
Further, it is possible to confirm not only the number of game media granted in the game in which the accessory is activated, but also the ratio including the number of game media granted in the game in which the advantageous operation mode of the stop switch is notified.

It is a block diagram which shows the outline of the control of the slot machine in this embodiment. It is a figure which shows the storage number display LED, the advantageous section display LED, the acquisition number display LED, the settlement switch and the like. It is a figure which shows the main control board housed in a board case, (a) shows Example 1, and (b) shows Example 2. It is a figure explaining the detail of a digit and a segment. It is a figure which shows the symbol arrangement of a reel. It is a figure which shows the display window (transparent window) provided in the slot machine, the positional relationship of each reel, the effective line and the like. It is a figure (1) which shows the type of a combination, the number of payouts, and the combination of symbols. It is a figure (2) which shows the type of a combination, the number of payouts, and the combination of symbols. It is a figure (3) which shows the type of a combination, the number of payouts, and the combination of symbols. It is a figure (4) which shows the type of a combination, the number of payouts, and the combination of symbols. It is a figure (5) which shows the type of a combination, the number of payouts, and the combination of symbols. It is a figure (6) which shows the type of a combination, the number of payouts, and the combination of symbols. It is a figure (1) which shows the relationship between the condition device, the winning combination, and the push order. It is a figure (2) which shows the relationship between the condition device, the winning combination, and the push order. It is a figure (3) which shows the relationship between the condition device, the winning combination, and the push order. It is a figure (4) which shows the relationship between the condition device, the winning combination, and the push order. It is a figure (1) which shows the figurative table. It is a figure (2) which shows the figurative table. It is a figure which shows the push order instruction number table. It is a figure which shows the relationship of push order instruction number, advantageous push order, and display contents. It is a figure which shows the production group number table. It is a figure explaining the transition of RT. It is a figure which shows the lighting process of the advantageous section display LED. It is a timing chart (Example 1 and Example 2) which shows the processing flow of a main control board, acquisition number display LED, and an image display device. It is a timing chart (Example 3 and Example 4) which shows the processing flow of a main control board, acquisition number display LED, and an image display device. It is a figure which shows the flow of the display of the push order instruction information by the acquisition number display LED, and the notification of the correct answer push order by an image display device. It is a part of RWM, and is the figure which shows the storage area about the advantageous section and the total number of games. It is a part of RWM and is a figure which shows the storage area about the total number of payouts. It is a part of RWM, and is a figure which shows the storage area about the number of payouts at the time of continuous accessory operation. It is a part of RWM, and is a figure which shows the storage area about the number of payouts at the time of operation of an accessory. It is a part of RWM, and is the figure (modification example) which shows the storage area about the number of payouts at the time of continuous accessory operation. It is a flowchart which shows the flow of the process of updating the number of games, etc. using a register. It is a flowchart which shows the specific example 1 in steps S109 to S114 of FIG. It is a flowchart which shows the specific example 2 in steps S109 to S114 of FIG. It is a flowchart which shows the specific example 3 in steps S109 to S114 of FIG. It is a flowchart which shows the flow of the process of updating the number of games, etc. without using a register. It is a flowchart which shows the flow of calculation process of the advantageous section ratio. It is a figure explaining the information to be displayed on the management information display LED. It is a figure which shows the example which displays the management information on the storage number display LED. It is a figure which shows the example which displays the management information on the acquisition number display LED. It is an external perspective view which shows the base part 1 of a slot machine 10. In the second embodiment, it is a figure which shows the main control board housed in a board case, (a) shows Example 1, and (b) shows Example 2. It is a flowchart which shows the process (example 1) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 2) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 3) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 4) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 5) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 6) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 7) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 8) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 9) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 10) on the main control board side in 3rd Embodiment. It is a flowchart which shows the process (example 1) on the sub-control board side in 3rd Embodiment. It is a flowchart which shows the process (example 2) on the sub-control board side in 3rd Embodiment. It is a figure which shows the image display example (Example 1 to Example 4) of the image display device by a sub-control board with respect to addition in AT (third embodiment). In the third embodiment, it is a figure explaining an increase in the number of AT games, a change of an effect, and the like. It is a time chart (Example 1 and Example 2) of an external signal in a fourth embodiment. It is a time chart (example 3) of an external signal in the 4th embodiment. It is a figure which shows the RT transition in Example 1 of 5th Embodiment. In the fifth embodiment, it is a time chart which shows the relationship between RT transition and AT. It is a figure which shows Example 2 ((a)-(c)) of 5th Embodiment. It is a figure which shows the RT transition in 6th Embodiment. In the sixth embodiment, it is a figure which shows the type of the replay D group drawn by RT3, the winning combination, and the relationship between the push order and the display combination. It is a time chart which shows Example 1 and Example 2 of 8th Embodiment. It is a time chart which shows Example 3 of 8th Embodiment. It is a time chart which shows Example 4 and Example 5 of 8th Embodiment. It is a figure explaining the flow of the game in 9th Embodiment. It is a time chart which shows Example 1 and Example 2 of 11th Embodiment. It is a time chart which shows Example 3 and Example 4 of 11th Embodiment. In the twelfth embodiment, it is a time chart showing an ending effect and the like. It is a figure which shows the numerical table (2) of the thirteenth embodiment. In the 14th embodiment, it is a time chart which shows the extension of an advantageous section. In the fifteenth embodiment, it is a time chart which shows the relationship between the advantageous section and freeze. (A) is a diagram showing the winning number definition (1) in the 16th embodiment, (b) shows Example 1, and (c) shows Example 2. (A) is a diagram showing the winning number definition (2) in the 16th embodiment, which is a diagram following FIG. 74 (a), (b) shows Example 1, and (c) shows Example 2. , (D) show Example 3, and (e) shows Example 4. (A) is a diagram showing the data definition for winning number conversion in the 16th embodiment, (b) shows Example 1, (c) shows Example 2, (d) shows Example 3, and (e). ) Indicates Example 4. (A) is a figure which shows the winning number conversion table in 16th Embodiment, (b) shows the explanation of "DEFB", (c) shows Example 1, and (d) shows Example 2. (A) is a diagram showing the winning number lottery data definition in the 16th embodiment, and (b) shows the meaning of each identifier. It is a figure which shows the lottery table (1) common to all RTs in 16th Embodiment. It is a figure which shows the lottery table (2) common to all RTs in 16th Embodiment, and is the figure which follows FIG. 79. It is a figure which shows the lottery table (3) common to all RTs in 16th Embodiment, and is the figure which follows FIG. 80. (A) is a diagram showing the lottery table (4) common to all RTs in the 16th embodiment, and is a diagram following FIG. 81, and (b) is a diagram showing a non-RT lottery table in the 16th embodiment. Yes, (c) is a diagram showing a lottery table at RT1 in the 16th embodiment. (A) is a diagram showing the RT2 o'clock lottery table in the 16th embodiment, and (b) is a diagram showing the RT3 o'clock lottery table in the 16th embodiment. (A) is a diagram showing a lottery table at RT4 in the 16th embodiment, and (b) is a diagram showing a lottery table at 1BBA in the 16th embodiment. It is a figure which shows the lottery table at the time of 1BBB in 16th Embodiment. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in 16th Embodiment. It is a flowchart which shows the flow of processing of the internal lottery 1 in 16th Embodiment. It is a flowchart which shows the flow of the process of lottery determination in 16th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 1 in 16th Embodiment. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in the modification of 16th Embodiment. It is a flowchart which shows the flow of the processing at the time of stopping all reels in the modification of the 16th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 2 in the modification of the 16th Embodiment. (A) is a diagram showing the winning number definition (3) in the 17th embodiment, (b) shows Example 1, (c) shows Example 2, and (d) shows the winning number conversion data definition. It is a figure which shows. (A) is a diagram showing a winning number conversion table in the 17th embodiment, (b) shows Example 1, (c) shows Example 2, and (d) shows a lottery table (5) common to all RTs. It is a figure which shows. It is a figure which shows the lottery table (6) common to all RTs in 17th Embodiment, and is the figure which follows FIG. 94 (d). It is a figure which shows the lottery table (7) common to all RTs in 17th Embodiment, and is the figure which follows FIG. 95. (A) is a diagram showing a two-stage lottery address table in the seventeenth embodiment, (b) is a diagram showing a two-stage lottery table 1, and (c) is a diagram showing a two-stage lottery table 2. (D) is a diagram showing a two-stage lottery table 3, (e) is a diagram showing a two-stage lottery table 4, and (f) is a diagram showing a two-stage lottery table 5. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in 17th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 3 in 17th Embodiment. It is a flowchart which shows the flow of the process of the two-step lottery in 17th Embodiment. It is a flowchart which shows the flow of processing of the lottery without setting difference in 17th Embodiment. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in the modification of 17th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 4 in the modification of 17th Embodiment. (A) is a figure which shows the data definition for a winning number lottery in 18th Embodiment, and (b) shows the meaning of each identifier. It is a figure which shows the lottery table (8) common to all RTs in 18th Embodiment. It is a figure which shows the lottery table (9) common to all RTs in 18th Embodiment, and is the figure which follows FIG. 105. It is a figure which shows the lottery table (10) common to all RTs in 18th Embodiment, and is the figure which follows FIG. 106. It is a figure which shows the lottery table (11) common to all RTs in 18th Embodiment, and is the figure which follows FIG. 107. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in 18th Embodiment. It is a flowchart which shows the flow of the process of the advantageous section number acquisition in 18th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 5 in 18th Embodiment. (A) is a diagram showing the winning number definition (4) in the 19th embodiment, (b) is a diagram showing the winning number conversion and the data definition for determining the advantageous section transition, and (c) shows Example 1. , (D) show Example 2. (A) is a figure which shows the winning number conversion table in 19th Embodiment, (b) shows Example 1, and (c) shows Example 2. It is a figure which shows the lottery table (12) common to all RTs in 19th Embodiment. It is a figure which shows the lottery table (13) common to all RTs in 19th Embodiment, and is the figure which follows FIG. 114. It is a figure which shows the lottery table (14) common to all RTs in 19th Embodiment, and is the figure which follows FIG. 115. (A) is a figure which shows the advantageous section transition judgment random number table in 19th Embodiment, (b) shows the explanation of "DEFW", (c) shows Example 1, (d) shows Example 2. .. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in 19th Embodiment. It is a flowchart which shows the flow of processing of the internal lottery 2 in 19th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 6 in 19th Embodiment. It is a flowchart which shows the flow of processing of the advantageous section transition lottery in 19th Embodiment. It is a flowchart which shows the flow of the lottery processing such as a condition apparatus number in the modification of 19th Embodiment. It is a flowchart which shows the process flow of the condition apparatus number set 7 in the modification of 19th Embodiment. It is a figure explaining the more detailed configuration of the main CPU, ROM, and RWM in 20th Embodiment. (A) is a figure which shows various LEDs on the display board in 20th Embodiment. (B) is a figure which shows more concretely the management information display LED in 20th Embodiment. It is a figure explaining the detail of the digit and the segment in 20th Embodiment. It is a figure which shows the data table stored in ROM. It is a figure which shows the output ports 2-5 provided in the main control board in 20th Embodiment (reference example is also shown). It is a figure which shows the wiring of the electric signal on the main control board in 20th Embodiment. It is a figure which shows the wiring of the electric signal on the main control board in 20th Embodiment. It is a figure which shows the wiring of the electric signal on the display board in 20th Embodiment. (A) is a figure which shows the relationship between an interrupt, an LED display counter (_CT_LED_DSP), and an output signal in the twentieth embodiment. (B) is a figure which shows LED display request flag (_FL_LED_DSP). It is a flowchart which shows interrupt processing (I_INTR) by a main control board (main CPU). It is a flowchart which shows LED display control (I_LED_OUT) in 20th Embodiment. It is a flowchart which shows the ratio display process (S_LED_OUT) in 20th Embodiment. It is a flowchart which shows the unrecoverable error process 1 (SS_ERROR_STOP1). It is a flowchart which shows the non-recoverable error processing 2 (SS_ERROR_STOP2). It is a figure which shows the structure of the output port in 21st Embodiment. (A) is a figure which shows the relationship between the digit and the segment in 21st Embodiment. (B) is a figure which shows the LED display counter of 21st Embodiment. It is a flowchart which shows LED display control (I_LED_OUT) in 21st Embodiment. It is a flowchart which shows the ratio display process (S_LED_OUT) in 21st Embodiment. (A) is a figure which shows various LEDs on the display board in 22nd Embodiment. FIG. (B) is a diagram showing the management information display LED in the 22nd embodiment more specifically. (C) is a figure which shows the set value display LED in 22nd Embodiment. It is a figure which shows the relationship between a digit and a segment in 22nd Embodiment. It is a figure which shows the output port in 22nd Embodiment. In the 22nd embodiment, it is a circuit diagram which shows the wiring of the electric signal of the main control board. In the 22nd embodiment, it is a circuit diagram which shows the wiring of the electric signal of the main control board. In the 22nd embodiment, it is a circuit diagram which shows the wiring of the electric signal of the display board. (A) is a figure which shows the relationship between an interrupt, an LED display counter (_CT_LED_DSP) value, a digit signal, and a segment signal in the 22nd embodiment. (B) is a figure which shows LED display request flag (_FL_LED_DSP). It is a flowchart which shows LED display control (I_LED_OUT) in 22nd Embodiment. It is a flowchart which shows the ratio display process (S_LED_OUT) in 22nd Embodiment. It is a figure which shows the output port 2-6 in the 23rd Embodiment. It is a figure which shows the relationship between a digit and a segment in 23rd Embodiment. (A) is a figure which shows the relationship between an interrupt, an LED display counter (_CT_LED_DSP) value, a digit signal, and a segment signal in the 23rd embodiment. (B) is a figure which shows LED display request flag (_FL_LED_DSP). It is a figure which shows the output port 2-7 in 24th Embodiment. It is a figure which shows the relationship between the digit and the segment in 24th Embodiment. It is a figure which shows the example 1 of the LED display counter in 24th Embodiment. It is a figure which shows the example 2 of the LED display counter in 24th Embodiment. It is a flowchart which shows LED display control (I_LED_OUT) in 24th Embodiment. It is a flowchart which shows the ratio display process (S_LED_OUT) in 24th Embodiment. It is a figure which shows the numerical table (1) in 25th Embodiment. It is a figure which shows the numerical table (2) at the time of non-RT in 25th Embodiment. It is a figure which shows the numerical table (2) at RT1 in 25th Embodiment. It is a figure which shows the numerical table (2) at RT2 in 25th Embodiment. It is a figure which shows the numerical table (2) at RT3 in 25th Embodiment. It is a figure which shows the numerical table (2) at RT4 in 25th Embodiment. It is a figure which shows the numerical table (2) at the time of 1BBA operation in 25th Embodiment. It is a figure which shows the numerical table (2) at the time of 1BBB operation in 25th Embodiment. (A) is a diagram showing the transition to the advantageous section at the time of winning the rare combination in the first embodiment and the presence / absence of lighting of the advantageous section display LED, and (b) is the transition to the advantageous section at the time of winning the rare combination in the 25th embodiment. It is a figure which shows the presence / absence of lighting of an advantageous section display LED. It is a figure which shows the 1BB winning probability and the advantageous section transition probability at the time of 1BB winning for each set value in 25th Embodiment. It is a flowchart which shows the flow of instruction function operation processing in 25th Embodiment. In the 25th embodiment, it is a time chart showing an example in which the instruction function is activated at the time of winning the first push order bell after shifting to an advantageous section having no instruction game section. In the 25th embodiment, the time chart showing an example in which the operation of the instruction function is canceled by winning a special combination after shifting to the advantageous section having no instruction game section and before the operation of the first instruction function. be. In the 25th embodiment, it is a time chart which shows an example which activates an instruction function at the time of winning the first push order bell after satisfying the instruction operation condition once in the advantageous section which does not have the instruction game section. In the 25th embodiment, it is a time chart showing an example in which the operation of the instruction function is canceled by winning a special combination before satisfying the instruction operation condition once in an advantageous section having no instruction game section. In the 25th embodiment, in the advantageous section having no designated game section, after the number of games in the advantageous section is exhausted (after the count value of the advantageous section counter becomes "0"), the instruction function is provided when the push order bell is won. It is a time chart which shows an example which operates and ends an advantageous section. In the 25th embodiment, in an advantageous section that does not have an indicated game section, a special combination is won before the number of games of the advantageous section is exhausted (before the count value of the advantageous section counter becomes "0"). It is a time chart which shows the example of canceling the operation of an instruction function. Information on the RWM that is cleared by the initialization process at the end of the advantageous section (first initialization process) in the 25th embodiment, information on the RWM that is retained even after the initialization process at the end of the advantageous section, and when the setting is changed. It is a figure which shows the information on the RWM which is cleared by the initialization process (the second initialization process). (A) shows a modified example of the numerical table (1) of FIG. 160, and (b) shows the transition to the advantageous section and the presence / absence of lighting of the advantageous section display LED at the time of winning the rare combination of FIG. 168 (b). It is a figure which shows the modification of. (A) shows a modified example of the numerical table (1) of FIG. 160, and (b) shows the transition to the advantageous section and the presence / absence of lighting of the advantageous section display LED at the time of winning the rare combination of FIG. 168 (b). It is a figure which shows the modification of. (A) shows a modified example of the numerical table (1) of FIG. 160, and (b) shows the transition to the advantageous section and the presence / absence of lighting of the advantageous section display LED at the time of winning the rare combination of FIG. 168 (b). It is a figure which shows the modification of. It is a figure which shows the management information displayed by the management information display LED in the 26th Embodiment. It is a figure which shows the storage area (1) of RWM53 in 26th Embodiment. It is a figure which shows the storage area (2) of RWM53 in 26th Embodiment. It is a figure which shows the blinking display condition of the identification segment and the ratio segment in the 26th Embodiment. It is a flowchart which shows the program start (M_PRG_START) in 26th Embodiment. It is a flowchart which shows the setting change process (M_RANK_SET) in the 26th Embodiment. It is a flowchart which shows the power supply restoration process (M_POWER_ON) in the 26th Embodiment. It is a flowchart which shows the main process (M_MAIN) in the 26th Embodiment. (A) is a flowchart showing the update of the number of payouts in the 26th embodiment. (B) is a flowchart showing interrupt wait (C_INTR_WAIT) in the 26th embodiment. It is a flowchart which shows interrupt processing (I_INTR) in 26th Embodiment. It is a flowchart which shows the ratio set processing (S_RATE_SET) in 26th Embodiment. It is a flowchart which shows the count upper limit check (S_LIMIT_CHK) in the 26th Embodiment. It is a flowchart which shows the game count (S_GAME_CNT) in the 26th Embodiment. It is a flowchart which shows the count-up (S_CNT_UP) in the 26th Embodiment. It is a flowchart which shows the advantageous section game number count (S_ATGAME_CNT) in 26th Embodiment. It is a flowchart which shows the payout number count (S_PAYOUT_CNT) in the 26th Embodiment. It is a flowchart which shows the payout number set (S_PAYOUT_SET) in the 26th Embodiment. It is a flowchart which shows the ring buffer set (S_RINGADR_SET) in the 26th Embodiment. It is a flowchart which shows the count (S_BNSPAY_CNT) of the number of payouts of an accessory in 26th Embodiment. It is a flowchart which shows the continuous bonus payout number count (S_RBPAY_CNT) in the 26th Embodiment. In the 26th embodiment, (A) is a diagram showing a ratio calculation RWM address table (TBL_ADR_CAL) stored in a ROM, and (B) is a specific ROM storage area (address and data). It is a figure which shows. It is a flowchart which shows the ratio calculation process (S_CAL_SET) in the 26th Embodiment. It is a flowchart which shows the calculated value set (S_VALUE_SET) in the 26th Embodiment. It is a flowchart which shows the ratio calculation execution (S_CAL_EXE) in the 26th Embodiment. It is a flowchart which shows the ring buffer number update (S_RINGNO_SET) in the 26th Embodiment. It is a flowchart which shows the ratio display preparation (S_DSP_READY) in the 26th Embodiment. It is a flowchart which shows the blinking request flag generation (S_LED_FLASH) in the 26th Embodiment. It is a figure which shows the blinking / non-corresponding item determination value table (TBL_SEG_FLASH) in the 26th Embodiment. It is a flowchart which shows the ratio display timer update (S_RATE_TIME) in the 26th Embodiment. It is a flowchart which shows the ratio display process (S_LED_OUT) in the 26th Embodiment. It is a figure which shows the blinking bit inspection count table (TBL_FLASH_CHK). It is a flowchart which shows the ratio set processing (S_RATE_SET) in 27th Embodiment (1). It is a flowchart which shows the ratio display preparation (S_DSP_READY) in 27th Embodiment (1). It is a flowchart which shows the ratio calculation management (S_CAL_CTL) in 27th Embodiment (1). It is a flowchart which shows the ratio calculation process (S_CAL_SET) in 27th Embodiment (1). It is a flowchart which shows the main process (M_MAIN) in 27th Embodiment (2). It is a flowchart which shows the ratio set processing (S_RATE_SET) in 27th Embodiment (2). It is a flowchart which shows the setting change process (M_RANK_SET) in 27th Embodiment (3). It is a flowchart which shows the power-on ratio calculation (S_CAL_PWON) in 27th Embodiment (3). It is a flowchart which shows the main process (M_MAIN) in 27th Embodiment (3). FIG. 202 is a flowchart showing another example in the processing after step S2400 (a modified example of the 26th embodiment). It is a figure which shows the address, the label and the content of the data stored in the use area of RWM in 28th Embodiment. It is a figure which shows the LED segment table 1 and 2 stored in the use area of ROM in 28th Embodiment. It is a figure which shows the data and the address of the LED segment table 1 and 2 in 28th Embodiment. It is a figure which shows the address of the push order instruction number table in 28th Embodiment. It is a flowchart which shows the setting change process (M_RANK_SET) in 28th Embodiment. It is a flowchart which shows the main process (M_MAIN) in 28th Embodiment. It is a flowchart which shows the push order instruction number set processing (M_ORD_INF) in 28th Embodiment. It is a flowchart which shows the medal payout number update process in 28th Embodiment. It is a flowchart which shows the medal payout processing (MS_WIN_PAY) by a prize in 28th Embodiment. (1) is a diagram showing a state in which "88" (setting is being changed) is displayed on the acquired number display LED, and (2) is a diagram showing "= 1" (left first stop) on the acquired number display LED. (3) is a diagram showing a state in which "dE" (front door open) is displayed on the acquired number display LED, and (4) is a diagram showing a state in which "dE" (front door open) is displayed on the acquired number display LED, and (4) is a diagram showing "E1" (4) on the acquired number display LED. It is a figure which shows the state which displayed the power-off recovery error), and (5) shows the state which displayed the stored number "50" on the storage number display LED, and displayed the acquired number "9" on the acquired number display LED. It is a figure. It is a figure which shows the address, the label and the content of the data stored in the use area of RWM in 29th Embodiment. It is a figure which shows the relationship between the set value data, the set value display data, and the set value display in the 29th Embodiment. It is a flowchart which shows the setting change process (M_RANK_SET) in 29th Embodiment. It is a flowchart which shows the setting value display data set processing in 29th Embodiment. (1) is a diagram showing a state in which the set values "1" to "6" are displayed on the digit 4, and (2) displays "= 1" (first stop on the left) on the acquired number display LED. It is a figure which shows the state, (3) is a figure which shows the state which displayed the acquired number "9" on the acquired number display LED. It is a figure which shows the relationship of the push order instruction number, push order instruction information, and advantageous push order in the modified example of 28th and 29th Embodiment. It is a figure which shows the relationship between the segment A to G and bit 0-6 in the modification of the 28th and 29th embodiments. It is a figure which shows the relationship between the push order instruction number, display data, digit display, and advantageous push order in the modified example of 28th and 29th Embodiment. It is a figure which shows the relationship of the next operation instruction information, display data, digit display, and the stop switch which should be operated next in the modification of 28th and 29th Embodiment. It is a figure exemplifying the relationship between the condition device number, the display data, the display of the digit and the advantageous push order in the modification of the 28th and 29th embodiments for the condition device numbers 11-22. It is a flowchart which shows the setting change process (M_RANK_SET) in the modification of the 29th Embodiment. It is a figure which shows the storage area of the RWM which concerns on 30th Embodiment. It is a flowchart which shows the main process in 30th Embodiment. FIG. 244 is a flowchart showing a game start set (M_GAME_SET) in step S2701. It is a flowchart which shows the advantageous section setting (M_ADV_SET) in step S2724 in FIG. 245. FIG. 246 is a flowchart showing a 2-byte countdown (M_W_CNT_DOWN) in step S2742. FIG. 246 is a flowchart showing RWM initialization (M_RWM_CLEAR) in step S2746. In FIG. 244, it is a flowchart which shows the advantageous section type update in step S2703. FIG. 244 is a flowchart showing a push order instruction number set (M_ORD_INF) in step S2704. FIG. 250 is a flowchart showing the update of the maximum payout notification flag in step S2793. FIG. 244 is a flowchart showing a game end check process (M_GAME_SET) in step S2705. In FIG. 252, it is a flowchart which shows the advantageous section end preparation (M_ADVEND_STNBY) in step S2823.

In the present specification, the meanings of the terms are as follows.
"RT" means that the type (number) of the condition devices (1BB, replay, small winning combination) to be drawn and the winning probability thereof are in a unique lottery state, and "RT transition" is one. By shifting from RT to another RT, it means that the winning probability of at least one conditional device (for example, replay) to be a lottery target fluctuates. Therefore, the winning probability for each type of replay in one RT is a value peculiar to that RT, and the winning probability for each type of replay is the same for one RT and the other RT. No. However, it is permissible that the total value of the winning probabilities of the replay is the same for one RT and the other RT.

In this embodiment, the RT includes non-RT, RT1, RT2, RT3, and RT4 (FIG. 22 described later).
Note that "non-RT" does not mean that it is not included in the concept of RT, but is equivalent to "RT0". Therefore, the term "RT" as used herein includes non-RT.
In the present embodiment, the non-internal part is non-RT, RT1, RT2, or RT3, and the internal part is RT4. The type (number) of replays to be drawn and the winning probability are different between non-internal and internal.

Furthermore, in the present embodiment, 1BBA operation and 1BBB operation are provided as RTs during the special game. In this embodiment, at least one replay lottery is performed for both the 1BBA operation and the 1BBB operation.
The “combination” refers to a lottery target, and in the present embodiment, a condition device is drawn by lottery, and the condition device is set to include at least one combination. Therefore, when any of the conditional devices is won, at least one winning combination is won (having at least one winning combination).

The condition device to be drawn includes a "character condition device" including one of "special roles (roles)" and a "winning and replay condition device" including either a small role or a replay. ..
The "feature condition device" includes any of the special roles. When a special role wins, SB (single bonus), RB (type 1 special character; regular bonus), CB (type 2 special character; challenge bonus), which are devices that make it easy to win a small role, 1BB (Type 1 accessory continuous operation device; Type 1 big bonus) and 2BB (Type 2 accessory continuous operation device; Type 2 big bonus) are activated.

Here, the first-class accessory continuous operation device (1BB) means a device capable of continuously operating the first-class special accessory (RB).
Similarly, the type 2 accessory continuous operation device (2BB) refers to a device capable of continuously operating the type 2 special accessory (CB).
In this embodiment, only 1BB is provided as a special role, and has two types (1BBA and 1BBB) described later.
During the operation of 1BB, the RB ends when either the winning of two wins or the two games is satisfied, and after the end, the RB is operated again on condition that the end condition of the 1BB operation is not satisfied. ..
Further, in this embodiment, SB, CB, and 2BB are not provided.

On the other hand, the "winning and replay condition device" includes either a small winning combination or a replay in which the winning information is not carried over to the next game or later.
In the present embodiment, the winning and replay condition device numbers "0" to "30" are provided.
On the other hand, the "feature condition device" includes either RB, 1BB and 2BB in which the winning information can be carried over to the next game, and SB and CB in which the winning information is not carried over to the next game. In this embodiment, only 1BB (1BBA and 1BBB) that can carry over the winning information to the next game or later are provided.

When the winning information is won in the character condition device that includes any of the special roles that can be carried over to the next game or later, the winning information of the special role is until the combination of symbols corresponding to the special role stops at the valid line. Will be carried over to the next game.
A game in which the winning information is not won in the character condition device including any of the special roles that can be carried over to the next game or later is referred to as "non-internal". On the other hand, when the winning character condition device is won, but the combination of symbols corresponding to the winning special role is not yet stopped at the effective line, that is, the game in which the winning information of the special role is carried over is "inside". That is. In the present embodiment, the game won by the bonus condition device is included in "non-internal", but the game won by the bonus condition device may be included in "internal".

The "advantageous operation mode" of the stop switch is an operation mode in which a winning combination with a large number of payouts wins in a game in which the game result (combination of symbols that stop at the effective line) is advantageous / disadvantageous depending on the operation mode of the stop switch. Alternatively, it refers to an operation mode in which a winning combination that does not shift (promote) to an advantageous RT or shift (fall) to an unfavorable RT wins a prize. The "advantageous operation mode" is also referred to as a correct operation mode.

The "operation mode" is a concept that refers to the pressing order of the stop switch and / or the operation timing (the timing of pressing the stop switch for the target symbol to stop at the effective line).
Then, in the present embodiment, the "game having an advantageous operation mode of the stop switch" is a game at the time of winning the push order bell (small winning combination B group, small winning combination C group), and duplicate replays (replay B group, replay C group). ) Corresponds to the game at the time of winning.

Furthermore, when the push order bell is won, the number of bells (small winning combination) that wins when the stop switch is operated in the correct pressing order is the higher bell (out of the duplicate winning bell group (small winning combination), the number of payouts is It may be referred to as a bell (small role) in which it is most advantageous for the player to display the combination of the symbols such as the most small combination.
On the other hand, when the stop switch is operated in the wrong pressing order when the push order bell is won, the Yasume bell may win a prize or the role may be missed depending on the operation timing of the stop switch. The stop rolls (combination of symbols on the effective line, also referred to as "spilled stitches") displayed when the winning combination is missed are referred to as "pattern symbols" in the present embodiment, and have pattern symbols 01 to 03.

On the other hand, when the replay is duplicated (winning of the replay B group and the replay C group), the combination of different symbols is stopped and displayed according to the order in which the stop switch is pressed, but when the replay is won, no omission occurs (“PB = 1” described later). ").
In this case, the push order for stopping and displaying the combination of symbols that is advantageous to the player, for example, the combination of symbols that shifts to the RT with a higher replay winning probability, or the combination of symbols that maintains the RT with a high replay winning probability is "correct answer". It is called "push order" or "promotion push order".
On the other hand, the push order in which the combination of symbols that shift from the RT that is advantageous to the player (for example, the RT with a high probability of winning a replay) to the RT that is unfavorable (for example, the RT with a low probability of winning a replay) is stopped and displayed is "incorrect". It is called "push order" or "fall (demotion) push order".

The "instruction function" means a function of displaying (notifying) the above-mentioned "advantageous operation mode" to the player.
In other words, the "instruction function" refers to a device that facilitates winning. On the other hand, when the "instruction function" is a device that facilitates the winning of a small winning combination, the "instruction function" displays the correct answer pressing order for winning the correct answer pressing order (higher bell) when the pressing order bell is won. This does not include displaying the correct push order for winning a favorable replay (a replay for shifting to a favorable RT or a replay for maintaining a favorable RT) when a duplicate replay is won.

In the following embodiments, the "instruction function" refers to a function of displaying the "advantageous operation mode" to the player, and the "operation of the instruction function" indicates the correct answer pressing order when the pressing order bell is won. , And to display the correct answer push order to win an advantageous replay at the time of duplicate replay winning.
It should be noted that showing the content of the "instruction" to the player is "display", and notifying the player of the content of the instruction is "notification". Therefore, the "instruction function" is both a "display function" and a "notification function".
Further, the "instruction" is a concept having the meaning of "instruction", but the player is not penalized for not following the "instruction". However, if the correct answer push order displayed by the operation of the instruction function is not followed, the higher bell may not win when the push order bell is won, or the unfavorable replay may win when the replay duplicate win is won.

Further, the "instruction function operating game" is a game having an advantageous operation mode of the stop switch (condition device having an advantageous operation mode of the stop switch (small combination B group, small combination C group, replay B group, replay C). In the game) won in the group), it means a game in which the instruction function is activated. Therefore, the instruction function operating game is one game. The instruction function operation game may also be referred to as a notification game.
Further, even if the game has an advantageous operation mode of the stop switch, when the instruction function is not activated, the game is not the instruction function operation game.

In the present embodiment, the "game section" includes a "normal section", a "standby section", and an "advantageous section".
First, the "normal section" refers to a signal related to the instruction function, specifically, a push order instruction number and a winning and replay condition device number (information capable of determining the correct push order) described later, which are peripheral boards (for example, sub-control). It is a game section for which transmission to the board) is prohibited, and refers to a game section that does not affect the performance related to the instruction function at all (does not activate the instruction function). In other words, the normal section is a game section in which the instruction function cannot be operated and a game section in which an advantageous operation mode cannot be displayed. However, in addition to the lottery of the conditional device (combination), it is possible to determine whether or not to shift to the advantageous section (lottery, etc.).
In the normal section, since the instruction function must not be activated, it is not possible to display the push order instruction information on a predetermined display device (LED, etc.) electrically connected to the main control board, and the instruction function can be used. Since such a signal is not transmitted to the peripheral board, it is not possible to display (notify) an advantageous operation mode by an image display device electrically connected to the sub-control board described later.

When making a transition decision to an advantageous section in a normal section, it is necessary to make a transition decision in association with (associating) with the winning condition device.
Here, making a decision to shift to an advantageous section in association with the winning conditional device means determining whether or not to shift to the advantageous section at the same time as the lottery of the conditional device, and winning a specific conditional device. There is a case where a lottery is separately performed to determine whether or not to shift to an advantageous section on the condition of.

In the present embodiment, it is set to determine whether or not to shift to the advantageous section at the same time as the lottery of the conditional device. In addition, the length (number of games) of the advantageous section to be determined (winning) differs depending on the winning condition device. For example, when it is decided to shift to the advantageous section when 1BB, which will be described later, is won, the initial value is counted from the end of the 1BB game to become the advantageous section of 50 games, and when the small winning combination E1 is won alone. When it is decided to shift to the advantageous section, it may be an advantageous section in which only one instruction function operation game (excluding the game in which the small role C group, the replay B group, and the replay C group are won) is executed. be.

Furthermore, when deciding the transition to the advantageous section in association with the winning condition device, the condition device that can decide to shift to the advantageous section (in the case of separately drawing a lottery as to whether or not to shift to the advantageous section) , The condition device that is a condition for performing the lottery) is set so that it is a condition device that does not have a setting difference in the winning probability.
Here, the "set value" determines the player's advantage, and the higher (or lower) the set value is, the more advantageous the player is (the expected value of the ball output is higher). ) It is set. The set value is provided in six stages, for example, setting 1 to setting 6.
The "conditional device having no setting difference in the winning probability (common to the setting)" refers to a conditional device having the same winning probability in all the settings.

It should be noted that it is only "possible" to determine the transition to the advantageous section in association with the winning of the conditional device having no setting difference in the winning probability, and when the conditional device having no setting difference in the winning probability is won. However, it does not mean that you must always shift to an advantageous section or always draw a lottery to shift to an advantageous section. Of course, it is possible not to make any decision regarding the advantageous section even at the time of winning the conditional device having no setting difference in the winning probability.

On the other hand, the "conditional device having a setting difference in the winning probability (for each setting)" means that the winning probability is not the same for all settings. For example, when the winning probabilities of all the set values are different, or when the winning probabilities of some set values are different from the winning probabilities of some other set values (for example, the winning probabilities of settings 1 to 5). Is "x" and the winning probability of setting 6 is "y (≠ x)").

Further, the "advantageous section" is a game section having performance related to the instruction function (the instruction function may be activated), and specifically, when the instruction function is activated, the instruction content on the main control board. It refers to a game section in which a signal related to an instruction function can be transmitted to a sub-control board only when the push order instruction information is displayed so that (advantageous operation mode) can be identified. In other words, the advantageous section is a game section in which the instruction function can be operated (the instruction function may be activated) and a game section in which the advantageous operation mode can be displayed (may be displayed). The game in the advantageous section may also be referred to as a noticeable game. On the contrary, the game in the normal section and the game in the standby section may be referred to as a non-notifying game.
However, the sub control board cannot output an effect contrary to the instruction content given by the main control board or the signal related to the received instruction function.

Then, in the advantageous section of the present embodiment, the maximum number of payouts (“9”) corresponding to the specified number (“3”) in the game (when the accessory is not activated) in which the instruction function operation game can be executed can be obtained. In a game in which a conditional device (small winning combination B group) having an advantageous operating mode is won, at least one game is instructed to indicate the operating mode of the stop switch in which the winning combination (small winning combination 01) related to the maximum number of payouts is awarded. It is necessary.

Specifically, in the present embodiment, the small winning combination B group and the small winning combination C group are provided as so-called push order bell condition devices.
In the small winning combination B group, the small winning combination 01, which is a 9-card winning combination, always wins when the pushing order is correct, and the 1-card winning combination can be won when the pushing order is incorrect (may be missed).
On the other hand, in the small winning combination C group, the small winning combination 02, which is a three-card combination, always wins when the pushing order is correct, and the one-card winning combination always wins when the pushing order is incorrect.

The game when the instruction function activated game is executed is when the accessory is not activated (normal game), and the specified number (the number of medals to be inserted) in this normal game is "3".
Further, when the specified number is "3", the maximum number of payouts is "9" (at the time of winning the small winning combination 01).
Therefore, in the advantageous section of the present embodiment, the correct answer pressing order for winning the small winning combination 01 is determined by activating the instruction function at the time of winning the condition device (small winning combination B group) in which the small winning combination 01 can be won. It is necessary to execute at least one game to be displayed.

Further, during the advantageous section, in the game in which the condition device having the advantageous operation mode is won, the instruction function may be always activated to display the advantageous operation mode of the stop switch.
On the other hand, even if the game is won by a condition device having an advantageous operation mode during the advantageous section, the instruction function may not be activated.

Furthermore, the "waiting section" refers to a game section when the transition to the advantageous section has not yet been made after the decision to shift to the advantageous section. The waiting section may or may not be provided. That is, the normal section may be shifted to the advantageous section, the normal section may be shifted to the standby section, and the standby section may be further shifted to the advantageous section. It should be noted that it is not possible to shift from the advantageous section to the standby section, and after the end of the advantageous section, it always shifts to the normal section. The waiting section can be shifted only when it is decided to shift to the advantageous section based on the winning of the conditional device including the special combination that can be carried over to the next game or later, and corresponds to the special combination. A game in which a combination of symbols is displayed must be completed. Of course, the game may end before the game in which the combination of symbols corresponding to the special combination is displayed.
Further, in the standby section, it is not possible to operate the instruction function on the main control board or transmit a signal related to the instruction function to the sub control board. When the instruction function is operated on the main control board and the signal related to the instruction function is transmitted to the sub control board, it is a condition that the section is in an advantageous section.

In the advantageous section of the present embodiment, there are cases where one instruction function operating game (excluding games won in the small winning combination C group, replay B group, and replay C group) is executed, and cases where a predetermined number of games are executed. Has.
In the advantageous section in which the game is executed a predetermined number of times, when the condition device having the advantageous operation mode of the stop switch is won, the instruction function is basically activated.
The end condition of the advantageous section is not to determine the number of games described above, but for example, to perform an end (puncture) lottery at a predetermined timing, and to end the advantageous section when the lottery is won. You may.

Alternatively, the execution condition of the instruction function operating game is not satisfied only by shifting to the advantageous section, and whether or not to execute the instruction function operating game is determined by lottery or the like on the condition that the instruction function operating game is in the advantageous section. When it is decided to execute the instruction function operation game, the instruction function operation game may be executed until a predetermined end condition is satisfied.
In addition, during the advantageous section, it is determined (lottery, etc.) whether or not to add (add) the number of (remaining) games in the advantageous section.
In addition, the maximum number of games is set in the advantageous section, and when the maximum number of games is reached, the advantageous section is always terminated at that point even if the remaining number of games in the advantageous section is reached (limiter). Operation), shift to the normal section.

Furthermore, when the maximum number of games is reached, even if the condition device (small winning combination B group) having an advantageous operation mode capable of obtaining the maximum number of payouts (“9”) has never been won, or the winning is won. However, even if the winning combination (small combination 01) related to the maximum number of payouts has never instructed the operation mode of the stop switch, the advantageous section is always ended at that point (limiter operation), and it is normal. Move to the section.

As mentioned above, although the content partially overlaps with the above, the advantageous section in the present embodiment shall be defined as follows.
a) In the normal section, the lottery for whether or not to shift to the advantageous section (even if it is decided at the same time as the lottery for the conditional device) must be linked to the conditional device with no setting difference. That is, the transition probability to the advantageous section must not differ depending on the set value.
b) The additional lottery for the advantageous section (even if it is decided without the lottery) must not refer to the set value. When adding an advantageous section based on the winning condition device, it must be linked to the condition device with no setting difference.

c) Special role in the normal section (meaning the special role that carries over the winning. The same shall apply hereinafter in this paragraph). ) Must not be done. In addition, during the special role, even during the advantageous section, an additional lottery for the advantageous section (may be decided without performing the lottery) must not be performed. Furthermore, when a condition device having a setting difference including a special combination is won in an advantageous section and the special combination is in operation, an additional lottery in the advantageous section (determined without performing a lottery) is performed during the special combination operation. Also) must not be done.
Here, in the past, it was common to hold an AT lottery even after being inside, so even if it is inside, wait for the AT winning while maintaining the inside without winning a special role. It was possible. However, recently, it is desirable not to draw AT lottery inside. Therefore, in the present embodiment, when a special combination is won in the normal section and the inside is inside, it is determined that the normal section should not be changed to the advantageous section in the inside. Furthermore, if a special role is won in the advantageous section and it becomes inside, it is stipulated that the advantageous section must not be added in the inside.

d) When it is decided to shift to the advantageous section, as a general rule, the transition from the next game to the advantageous section is made, and until the advantageous section starts (in the present embodiment, the bet of the next game becomes possible). ), It is necessary to indicate to the player that it is an advantageous section from the next game (lighting of a lamp indicating that it is an advantageous section, etc.).
Here, conventionally, when an AT is won, it is common to digest a certain number of games (via a precursor) from the time when the AT is won until the player is notified of the AT winning. rice field. In addition, for example, in the case of drawing an AT based on the winning of a rare role, if the rare role is missed in the game, the player has won the rare role and the AT is drawn based on the rare role. Because I don't know, even if I won the AT by winning the rare role, I sometimes stopped the game before the AT winning was notified. After that, when another person plays a game on the platform, there is a problem that the other person may enjoy the benefit of the AT (assigned by the previous player). However, when it is decided to shift to the advantageous section, as a general rule, it is displayed that the advantageous section is from the next game until the advantageous section starts (in the present embodiment, until the bet of the next game becomes possible). Therefore, the above-mentioned problem does not occur.
As described above, in the past, the AT winning is notified after the AT is won (particularly after the AT precursor is passed), whereas in the present embodiment, in principle, until the next game can be bet. , The difference is that it is displayed that it is an advantageous section before the advantageous section is started.
Further, although the conventional notification of AT winning is only performed as a part of the production, it is displayed to the player that it is an advantageous section from the next game in the present embodiment (a lamp indicating that it is an advantageous section). The lighting of the lamp, etc.) is different in that it is performed to solve the above problem.

Further, the advantageous section ratio refers to the ratio of staying in the advantageous section with respect to the total gaming section (normal section + waiting section + advantageous section). Specifically, for example, when the number of games played in all the game sections is "1000" and the number of games played in the advantageous section during that period is "700", the ratio of advantageous sections is "70%".
As will be described later, in the present embodiment, the advantageous section ratio is displayed, but the displayed advantageous section ratio is a numerical value rounded down to the nearest whole number as a result of the calculation.

The pull-in rate (PB) is the probability that the desired symbol to be stopped on the effective line can be stopped on the effective line from the moment the stop switch is operated until the reel stops (maximum number of moving frames). show.
Then, if the stop switch is not operated at an appropriate reel position (at an operation timing at which the target symbol can be stopped at the effective line within the range of the maximum number of moving frames), the target symbol is stopped at the effective line (up to the effective line). The inability to pull in) is referred to as "PB (pull-in rate) ≠ 1".
On the other hand, "PB" indicates that the target symbol can always be stopped (pulled in) to the effective line regardless of the position of the reel at the moment when the stop switch is operated (regardless of the operation timing of the stop switch). = 1 ".

Then, "PB = 1" has a case where all reels are so and a case where only a specific (some) reels are so for the combination.
In the present embodiment, the maximum number of moving frames is set to "4", and when the target symbols are arranged at intervals of 5 symbols or less, "PB = 1" and exceeds 5 symbols (6 symbols or more). When arranged at intervals, "PB ≠ 1". In particular, the number of symbols on the reels of the present embodiment is set to "20", and if four symbols are arranged at intervals of five symbols, the symbols are "PB = 1".

When the game progresses with "N-1" game, "N" game, "N + 1" game, ... ("N" is an integer of 2 or more), the current game is "N" game. When it is an eye, the game of the "N" game is referred to as "this time game". Further, the game of the "N-1" game is referred to as a "previous game".
On the other hand, the game of the "N + 1" game is referred to as the "next game".

The "ball payout rate" is a value calculated by the expected number of medals to be paid out / the number of medals to be inserted. When it is "1", the status quo is maintained, and when it exceeds "1", the number of medals increases. It is a state, and when it is less than "1", the number of medals is reduced.
Further, the "expected value of the number of medals to be paid out" is calculated by the sum of "probability of winning the winning number x number of payouts" for all the winning combinations to be drawn in the game.

Furthermore, the "difference number" is a value calculated by "the number of medals paid out (the number of medals actually paid out or the expected value of the number of medals paid out) -the number of medals inserted". When the number of medals inserted is "3", if the number of medals paid out (expected value) is "3", the difference number is "± 0", and if the number of medals paid out (expected value) exceeds "3", When the difference number exceeds "0" and the medal payout number (expected value) is less than "3", the difference number becomes less than "0".

"Bet" means betting a medal (game medium) in order to play a game. In the present embodiment, the number of bets (specified number) that can be played is set to 3 when the accessory is not operating (during a normal game). On the other hand, while the accessory (1BB) is operating, the number of bets (specified number) that can be played is set to two. To bet a medal, the actual medal is groomed and inserted from the medal slot, or the bet switch is operated to bet the stored medal.
The "game medium" is a medal in the present embodiment, but in the case of an enclosed game machine, for example, electronic information is used as the game medium. The "electronic information" means, for example, that when money (banknotes) is inserted 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 the gaming machine. It can be stored in a gaming machine as a gaming medium for performing the above.
In addition, the display of the accessory ratio, etc., which will be described later, can be applied not only to slot machines but also to ball game machines, so the "game medium" includes not only medals but also game balls. Is done.

“Storage” means crediting medals inside the slot machine 10, unlike the above-mentioned “bet”. The term "storage" may be used to include a bet, but in the present specification, the term "storage" is used to mean not to include a "bet". In the present embodiment, the maximum (limit) number of cards that can be stored is set to "50" regardless of the gaming state or the like. When a small role wins and a medal is paid out, the medal is accumulated. In addition, when medals are maintained and inserted from the medal insertion slot, if the maximum number of medals has already been bet, the inserted medals are stored. Therefore, when the medals are maintained and inserted from the medal insertion slot, there are cases where the medals are bet and cases where the medals are stored.

It should be noted that the slot machine 10 "paying out" a medal to the player is equivalent to the player "acquiring" the medal. Therefore, from the viewpoint of the slot machine 10, it is "payout of medals", and from the viewpoint of the player, it is "acquisition of medals". Therefore, there are a case of calling it "payout (number of sheets)" (for example, payout means 67) and a case of calling it "acquisition (number of sheets)" (for example, acquisition number display LED 78), both of which have the same meaning.

In the present specification, a numerical value having a "B" at the end (particularly, 8 bits) means a binary number. Similarly, a number with an "H" at the end 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 meaning a decimal number is expressed as "16 (D)" as necessary.
However, when it is clear which of the binary number, the decimal number, and the hexadecimal number is, the suffixes of "B", "D", and "H" may be omitted, respectively.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings and the like.
<First Embodiment>
FIG. 1 is a block diagram showing an outline of control of the slot machine 10 in the present embodiment.
As a typical control board provided in the slot machine 10, a main control board 50 and a sub control board 80 are provided.
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 (it does not mean that only those shown in FIG. 1 are provided).

In FIG. 1, the main control board 50 and peripheral devices for game progress including operation switches such as a bet switch 40 are electrically connected via an input port 51 or an output port 52. The input port 51 is a connection unit to which a signal such as an operation switch is input, and the output port 52 is a connection unit for transmitting a signal to a peripheral device such as a motor 32.
In FIG. 1, the input peripheral device is indicated by an arrow pointing from the main control board 50 to the peripheral device, and the output peripheral device is indicated by an arrow pointing from the main control board 50 to the peripheral device. It is shown (the same applies 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 or the like. Data (total number of games, etc.) necessary for displaying the management information described later is stored in the RWM 53.
The ROM 54 is a storage medium for storing programs and various data (for example, a data table) necessary for the progress of the game.

The main CPU 55 refers to a CPU provided on the main control board 50, executes a program necessary for the progress of the game, performs calculations, and the like. To pay out, etc.
The main CPU 55 has a built-in register. In particular, in the present embodiment, a plurality of registers (for example, A register to L register, transmission register, etc.) are provided.

Further, on the main control board 50, an MPU including an RWM 53, a ROM 54, a main CPU 55, and a register is mounted. The RWM 53 and ROM 54 may be provided externally in addition to those mounted inside the MPU.
An MPU including an RWM83, a ROM84, and a subCPU85 is mounted on the sub-control board 80 described later. The RWM83 and ROM84 may be provided externally in addition to those mounted inside the MPU.

In FIG. 1, the medals inserted from the medal insertion slot 43 are sent to the inside of the medal selector.
As shown in FIG. 1, the medal selector includes a passage sensor 43a, a blocker 45, and a closing sensor 44 (but is not limited thereto), and is electrically connected to the main control board 50.
When a medal is inserted from the medal insertion slot 43, it is first detected by the passage sensor 43a.

Further, a blocker 45 is provided on the downstream side of the passage sensor 43a. The blocker 45 is for permitting / disallowing the insertion of medals, and when the insertion of medals is not permitted, the blocker 45 forms a medal passage for returning the medals inserted from the medal insertion slot 43 from the payout slot. do. On the other hand, when the insertion of medals is permitted, a medal passage for guiding the medals inserted from the medal insertion slot 43 to the hopper 35 is formed.

Here, the blocker 45 is in a state of disallowing the insertion of medals during the game (from the start of rotation of the reels 31 to the end of the payout corresponding to the winning combination when all the reels 31 are stopped and the winning combination is won). do. That is, the blocker 45 permits the insertion of medals at least when the game is not performed.

On the further downstream side of the blocker 45, a closing sensor 44 (a plurality of optical sensors) is provided. Therefore, the medal inserted from the medal insertion slot 43 is configured to be detected by the passage sensor 43a and then further detected by the insertion sensor 44.

Further, as shown in FIG. 1, on the main control board 50, a bet switch 40, a start switch 41, a (left, middle, right) stop switch 42, and a settlement switch 46 are electrically operated as operation switches operated by the player. Is connected.
The bet switch 40 (40a or 40b) is a switch operated by the player when betting the stored medals for the game this time. In the present embodiment, a 1-bet switch 40a for inserting one medal and a 3-bet switch 40b for inserting three (maximum number or a specified number) medals are provided.
Not limited to this, a bet switch for two bets may be provided.

Further, the specified number of the present embodiment is set to 3 when the accessory is not activated and 2 when the accessory is activated, but when the 1-bet switch 40a is operated (pressed) twice, 2 medals are used. Can be inserted, and three medals can be inserted by operating (pressing) three times. Further, while the accessory is operating, two medals (specified number) can be inserted at one time by operating the 3-bet switch 40b.

Further, the start switch 41 is a switch operated by the player when starting the reels 31 (all of the left, middle, and right).
Furthermore, the stop switch 42 is a switch provided by three corresponding reels 31 (left, middle, right) and operated by the player when the corresponding reels 31 are stopped.
Further, the checkout switch 46 is a switch operated by the player when refunding (paying out) medals bet 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 reality, 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 to each other. In No. 1, the illustration of the relay board is omitted. As described above, 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 between them.
Further, the control boards are not limited to being directly connected by a harness or the like, and may be connected via another board (relay board or the like). For example, one or more other separate boards (relay board, etc.) may be interposed between the main control board 50 and the sub control board 80.

The display board 75 is equipped with a storage number display LED 76, an advantageous section display LED 77, and an acquisition number display LED 78. These LEDs 76 to 78 are provided in the vicinity of the operation switch operated by the player, and are provided at positions that the player can always see. It is not necessary that all LEDs 76 to 78 are provided on one display board 75, and a plurality of display boards 75 such as display boards 75A, 75B, ... Are provided, and any display board 75 is provided. Any LED 76 to 78 may be provided in the above.

FIG. 2 shows the actual positional relationship (arrangement) of the storage number display LED76, the advantageous section display LED77, the acquisition number display LED78, the settlement switch 46, the 1-bet switch 40a, and the 3-bet switch 40b on the front side of the slot machine 10. It is a plan view.
Further, in FIG. 2, a display board 75 (indicated by a dotted line in FIG. 2) is arranged inside the slot machine 10 below the stored number display LED 76, the advantageous section display LED 77, and the acquired number display LED 78. ing.

The stored number display LED 76 is an LED that displays the number of medals stored inside the slot machine 10, and is composed of a digit 1 that displays the upper digit and a digit 2 that displays the lower digit. That is, the stored number display LED 76 displays two digits.
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) and a segment DP (decimal point, which is a dot-shaped LED that displays a decimal point). Has been done.
As shown in FIG. 2, the number of digits mounted on the display board 75 is four, that is, digits 1 to 4, but in the present embodiment, there are nine digits, and the other digits are the main control board. It is mounted on the 60 (details will be described later).

The stored number display LED 76 displays the number of stored medals, and in the present embodiment, displays a number between "00" and "50" (integer).
For example, in a state where no medals are bet and stored, the display of the stored number display LED76 is "00". Here, when one medal is cared for, the one medal is bet for the game. If two more medals are added, three medals will be bet for the game (when the specified number is three). Therefore, when the number of medals maintained is up to three, the medals are bet and are not stored. When the medals are further maintained, the medals are stored inside the slot machine 10, and the number of stored medals is displayed by the stored number display LED 76.

In this embodiment, up to 50 medals can be stored. Therefore, when the number of stored medals reaches 50 (when "50" is displayed on the stored number display LED 76), no more medals are stored. In this state, if a medal is maintained from the medal slot 43, the blocked medal is returned from the payout slot by the blocker 45.

Here, when a winning combination (excluding replay) with a medal payout wins and a medal corresponding to that role is paid out, priority is given to the actual payout of the medal from the payout port, and the inside of the slot machine 10 is used. The medals are stored. For example, when the number of stored cards before winning the winning combination is "10" and the winning number of 9 cards is won, the display of the storage number display LED 76 is updated from "10" to "19".

Furthermore, when the number of stored cards exceeds "50" at the time of winning the winning combination, the amount exceeding "50" is actually paid out from the payout slot. For example, when the number of stored cards is "47" before the winning combination and 9 medals are paid out by winning the 9-card winning combination, 3 cards are stored and the number of stored cards becomes "50", which exceeds "50". Six cards will be paid out from the payout slot.

Further, when the replay is won, the medals are not stored and paid out, and the number of medals bet in the game is automatically bet for the replay. For example, when the game is played with 3 bets (3 cards) and the replay wins, 3 medals are automatically bet. Then, since the automatic bet based on the winning of the replay is the insertion of a medal for performing the replay, the medal cannot be settled even if the settlement (return) operation is performed after that.

In addition, in the "Rules for certification of gaming machines and certification of types (hereinafter, simply referred to as" rules ")", when the combination of symbols corresponding to replay stops at the valid line, the condition device for replaying It is interpreted as an operation, not a "winning". However, in the present application (the present specification, etc.), the replay is also treated as one of the roles (replaying role), and the fact that the combination of symbols corresponding to the replay stops at the effective line is referred to as "replay winning".

Further, the advantageous section display LED 77 is composed of the segment DP of the digit 2. The advantageous section display LED 77 is controlled to be turned off in the normal section and the standby section, but is controlled to be turned on during the advantageous section. Therefore, the player can determine at a glance whether or not he / she is currently staying in the advantageous section by confirming the lighting / extinguishing state of the advantageous section display LED 77.

In particular, as shown in FIG. 2, the advantageous section display LED 77 is located in the vicinity of the settlement switch 46. Therefore, when the player finishes the game and has a storage medal (for example, when "10" is displayed on the storage number display LED 76), the player operates the settlement switch 46, but at that time, It can be easily confirmed by the off state of the advantageous section display LED 77 that the section is not in the advantageous section. Further, in the present embodiment, when it is decided to shift to the advantageous section, in principle, the advantageous section display LED 77 is turned on before the settlement switch 46 can be operated. As a result, it is possible to prevent the player from ending the game against the intention of the player even though the section is in the advantageous section (or the advantageous section from the next game).

Furthermore, the acquired number display LED 78 is an LED that displays the number of payouts (the number of acquired players) when a winning combination is won, and is composed of a digit 3 that displays the upper digit and a digit 4 that displays the lower digit. ing. Therefore, the acquired number display LED 78 displays two digits in the same manner as the stored number display LED 76.
The display of the acquired number display LED78 is "00" when there are no medals to be paid out, but for example, when the 9-card combination described later wins and 9 medals are paid out, the display of the acquired number display LED78 is It changes from "00" to "09".
The acquired number display LED 78 may be controlled to turn off when there are no medals to be paid out. Alternatively, the upper digit (digit 3) may be turned off and only the lower digit (digit 4) may be displayed as "0".

Further, the acquired number display LED 78 normally displays the acquired number, but functions as an LED for displaying the content (type) of the error when an error occurs. For example, when the front door of the slot machine 10 is opened and a door open error is detected, the error number "dE" is displayed on the acquired number display LED 78.
Furthermore, the acquired number display LED 78 functions as an LED that displays an advantageous operation mode (push order instruction information) when the instruction function is activated. Therefore, the acquired number display LED 78 in the present embodiment is an LED that also displays the acquired number, the error content, and the advantageous operation mode by operating the instruction function. Note that the advantageous push order notification when the instruction function is activated is also executed by the image display device 23 connected to the sub control board 80.

Here, in the present specification, the display of the push order using the acquired number display LED 78 by the main control board 50 is referred to as "operation of the instruction function", and the display of the push order by the sub control board 80 is "notification of the push order". It is called.
Further, as shown in FIG. 20 described later, a number corresponding to an advantageous push order is referred to as a “push order instruction number”.
Further, the push order displayed on the acquired number display LED 78 by the operation of the instruction function, for example, information such as "= 1" in FIG. 20, is referred to as "push order instruction information". That is, when the instruction function is activated, the push order instruction information is displayed on the acquired number display LED 78.

FIG. 3 is a plan view showing other digits (digits 5 to 9) mounted on the main control board 50. In FIG. 3, (a) shows Example 1 and (b) shows Example 2.
The main control board 50 is housed and sealed in a transparent board case 16 for security reasons. The main control board 50 cannot be accessed (the board case 16 cannot be opened) unless the crimped portion 16a of the board case 16 is destroyed. In FIG. 3, the main control boards 50 (50A and 50B) are shown so as to be transparent without being blocked by the board case 16. The crimped portion 16a may also be referred to as a sealing member.

On the board case 16, stickers showing proof that it is a regular main control board 50, a serial number, an opening record of the crimped portion 16a, etc. are affixed, but these stickers may obstruct the view. Digits 5 to 9 are mounted on the main control board 50 so as not to be present.
The digit 5 is a set value display LED 73, which is an LED that displays the current set value when the setting is confirmed or the setting is changed. The set value display LED 73 does not necessarily have to be mounted on the main control board 50, and can also be used as, for example, the back side of the front door, the stored number display LED 76, or the acquired number display LED 78.

Digits 6 to 9 are management information display LEDs 74. In order to ensure the visibility of the management information display LED 74, for example, one digit housing is shown in FIG. 3 (a).
It is preferable to design the size of width m1 × height n ≧ 36 square millimeters. Alternatively, when the management information display LED 74 is used as one horizontally long (width m2) digit housing,
It is preferable to design the size of width m2 × height n ÷ 4 (number of digits) ≧ 36 square millimeters.

In FIG. 3, in Example 1 of (a), the number of main control boards 50 is one, but the present invention is not limited to this, and as in Example 2 of (b), the main control board 50 is composed of a plurality of separate boards. However, each board may be connected by a harness or the like. However, even if the main control board 50 is composed of a plurality of separate boards, it is necessary to house the entire main control board 50 in the board case 16 and seal it.
In the example of FIG. 3B, the main control boards 50 are two main control boards 50A and 50B, connectors are provided on the main control boards 50A and 50B, respectively, and the connectors are connected by a harness. However, the present invention is not limited to this, and a connector capable of directly connecting the main control boards 50A and 50B may be used, and a harness may not be used (the same applies to FIG. 42B described later).
Further, the set value display LED 73 is provided on the main control board 50A side, but the management information display LED 74 is mounted on the main control board 50B. That is, the main control board 50B also serves as a display board for mounting the management information display LED 74.

Further, in the management information display LED 74, in addition to the case where the management information display LED 74 is arranged in one horizontal row as shown in Example 1 of (a), for example, the digits 6 and 7 are arranged in the upper row as in Example 2 of (b). , Digits 8 and 9 may be arranged in the lower row.

FIG. 4 is a diagram showing the relationship between digits 1 to 9, segments A to G, and segment DP.
As described above, each digit is composed of seven rod-shaped segments A to G and one dot-shaped segment DP, and the segments A to G (7 pieces) form a so-called 7-segment display. ..

As shown in FIG. 4, for example, in the digit 1, the segments A to G constitute the upper digit 7-segment of the stored number display LED 76, and the segment DP is unused.
Further, among the digits 2, the segments A to G form the lower digit 7-segment of the stored number display LED 76, and the segment DP is used as the advantageous section display LED 77.
Furthermore, each of the segments A to G of the digits 3 and 4 constitutes 7 segments of the upper digit and the lower digit of the acquired number display LED 78, respectively, and the segment DP is unused.

Further, among the digits 5, the segments A to G form 7 segments of the set value display LED 73, and the segment DP is an LED that lights up during the setting change. That is, among the set value display LEDs 73, when only the 7-segment is lit, it indicates that the setting is being confirmed, and when the 7-segment and the segment DP are lit, it indicates that the setting is being changed. The segment DP of the set value display LED 73 is not necessarily limited to such usage. For example, the segment DP of the set value display LED 73 may be a segment that lights up when the set value is fixed during the setting change.

Segments 6 to 9 constitute the management information display LED 74, and segments 6 and 7 display the information type of the management information. Further, the segments 8 and 9 display the numerical values corresponding to the information types displayed in the segments 6 and 7 among the management information. The segment DPs of digits 6-9 are unused. However, when the management information display LED 74 is turned on, it is also possible to turn on the segment DP of the digit 7. Further, by turning on the segment DP of the digit 7, the boundary between the digits 6 and 7 indicating the information type and the digits 8 and 9 indicating the numerical value can be clarified and the confirmation can be facilitated.

Further, FIG. 4 shows a configuration diagram of segment data. For example, when "0" is displayed on the digit 1, the segments A to F are turned on and the segments G and DP are turned off, so that the segment data is "00111111 (B)".
Further, when "1" is displayed on the digit 2 and the segment B, C, and DP are turned on during the advantageous section, the segment data is "10000110 (B)". That is, by setting the most significant bit (8th bit) of the segment data of the digit 2 to "0" or "1", the advantageous section display LED 77 is turned off or turned on. Thereby, by determining whether the 8th bit of the segment data of the digit 2 is "0" or "1", it is possible to determine whether or not the segment data is in the advantageous section.

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

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

The reel 31 has a ring shape, and a reel tape on which a plurality of types of symbols (designs constituting a combination of symbols corresponding to the combinations) are printed is attached to the outer peripheral surface thereof. The specific arrangement of the symbols on the reel 31 will be described later.
Further, each reel 31 is provided with one (or two or more) indexes. The index is provided on the peripheral side surface of the reel 31, for example, in a convex shape, and is used when detecting whether or not the reel 31 has passed a predetermined position, whether or not it has made one rotation, and the like. Then, each index is detected by the reel sensor 33. The signal of the reel sensor 33 is electrically connected to the main control board 50. Then, when the index detects (turns off) 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. As a result, it is possible to detect the symbol on the reference position at the moment when the index is detected.

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

The medals that have been maintained and received from the medal slot 43 are formed so as to be housed in the hopper 35 through a predetermined passage (also referred to as a “shoot portion”).
The payout sensor 37 is a pair of optical sensors arranged at a predetermined distance, and is configured to be detected by the other payout sensor 37 after a predetermined time has elapsed from the detection of the medal by the payout sensor 37. Has been done. Then, based on the timing at which the pair of payout sensors 37 are turned on / off, it is determined whether or not the medals are correctly paid out.

For example, when the signals of both payout sensors 37 are off even though the hopper motor 36 is driven, it is determined that no medal has been paid out, and a hopper error (no medal) is detected. Will be done.
On the other hand, when at least one of the signals of the payout sensor 37 remains ON, it is detected that the medal is jammed.

Further, the power switch 11 is a switch for turning on / off the power of the slot machine 10.
The setting key switch 12 is a switch that is turned on when the setting key is inserted from the setting key insertion slot and is rotated 90 degrees to the right (clockwise), and is turned on when the setting is confirmed or the setting is changed.

The setting switch 13 is a switch that is operated when changing the set value. For example, the set value is added by "1" each time the setting is changed. In this embodiment, the set value has settings 1 to 6, and during the setting change, each time the setting switch 13 is operated, the set value changes from "1" → "2" → ... → "6" → It switches from "1" to ... One of the set values is displayed during the setting change, and when the start switch 41 is operated, the displayed set value is confirmed.

Further, when the power switch 11 is turned on while the reset switch 14 is turned on, the reset, that is, the initialization process is performed, and the predetermined data stored in the RWM 53 is cleared.
Further, the door switch 15 is a switch that is turned on when the front door (not shown) of the slot machine 10 is opened, and is for detecting the open / closed state of the front door.

Furthermore, an external signal (outer end signal) to the external centralized terminal plate 100 is output from a part of the output port 52.
Here, the "external signal" is a signal to be output to the outside of the slot machine 10 (such as a hall computer 200 or a data counter installed in a hall) via the external centralized terminal plate 100. In the present embodiment, an external signal (1BB signal, RB signal, advantageous section signal), an external signal indicating that an error or power failure has occurred in the slot machine 10, and opening of the front door of the slot machine 10 are shown. External signals, medal insertion signals, medal payout signals, etc. are provided.

In FIG. 1, the sub-control board 80 controls the selection, output, and the like of an effect (information) during a game and a game standby.
Here, the main control board 50 and the sub control board 80 are electrically connected, and the main control board 50 (control command transmission means 71 described later) is unidirectionally connected to the sub control board 80 by parallel communication. Send the information (control command) required for the output of the production.
The main control board 50 and the sub control board 80 are not limited to being electrically connected, and may be connected by using an optical communication means. Further, both the electrical connection and the optical communication connection are not limited to parallel communication, but may be serial communication, and serial communication and parallel communication may be used in combination.

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

The effect lamp 21 is composed of, for example, an LED or the like, and when a predetermined condition is satisfied, the effect lamp 21 is lit in a predetermined pattern. The effect lamp 21 is a back lamp and reel 31 that are arranged on the inner peripheral side of each reel 31 and illuminate the symbols displayed on the reel 31 (three consecutive symbols that can be seen from the display window 17) from behind. A fluorescent lamp that illuminates the design on the reel 31 from the upper part of the reel 31, a frame lamp that is arranged in front of the front door of the slot machine 10 and blinks when a winning combination is won, 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 (correct answer pressing order, effects corresponding to the lottery result of the condition device, etc.) during the game, and It displays game information (the number of games played, the number of acquired cards, etc., when the character is operating or in an advantageous section).
Further, the cross key 24 and the menu button 25 are used when displaying information intended by the player (including a two-dimensional code which is the player's game history), or when the hall manager (store manager, etc.) changes various settings. It is used when doing so.

Subsequently, the roles of the present embodiment, the combination of symbols, and the like will be described.
FIG. 5 is a diagram showing a symbol arrangement of the reels 31 in this embodiment. In FIG. 5, the symbol numbers are also shown. For example, in the left reel 31, the symbol number 0 is "bell A".
As shown in FIG. 5, in the present embodiment, each reel 31 is equally divided into 20 frames, and a predetermined symbol is displayed on each frame.
In the figure, "blank" does not mean that the symbol is not displayed at all, and a predetermined symbol corresponding to the "blank" is displayed.
The "bell A", "bell B", and "bell C" are symbols having similar appearances, but different symbols.

Further, FIG. 6A shows the positional relationship between the display window (transparent window) 17 provided on the front door (front door; not shown) of the slot machine 10 and each reel 31, and the effective line (design). It is a figure which shows (a display line which displays a combination).
In this embodiment, three reels 31 are provided in parallel in the horizontal direction (left reel 31, middle reel 31, and right reel 31). Further, each reel 31 is arranged so that three consecutive symbols can be seen from the display window 17. Therefore, a total of nine symbols (frames) are arranged so as to be visible from the display window 17 of the slot machine 10. The number at the bottom right of each symbol indicates the symbol number.

Further, FIG. 6B illustrates the title of the symbol position in the present specification. In the present specification, for each reel 31, the symbol positions at the time of stop that can be seen from the display window 17 are referred to as "upper", "middle", and "lower" in order from the top, and if it is the left reel 31, each is "upper left". , "Left middle row", "Left lower row".
Furthermore, as shown in FIG. 6A, effective lines are set for the nine symbols that can be seen from the display window 17.

Here, the "effective line" is a symbol combination line (display line) that is an arrangement line of symbols when the reel 31 is stopped and forms a combination of symbols, and is a symbol corresponding to any combination. When the combination stops at that line, it is the line that wins the role. In this embodiment, one valid line (a straight line passing through "lower left"-"middle middle"-"upper right") is defined, and all other symbol combination lines are invalid lines. There is.

The invalid line is a line that is not set as a valid line among the symbol combination lines, and even if the combination of symbols corresponding to any combination stops at that line, the profit is given according to the combination. This is a line that does not pay out medals. That is, the invalid line is a line that is not the target of establishing the combination of symbols in the first place.

Further, conventionally, slot machines in which the number of effective lines differs depending on the number of medals inserted have been known. For example, when the number of medals inserted is 1, the number of effective lines is 1, when the number of medals inserted is 2, the number of effective lines is set to 3, and when the number of medals inserted is 3, the number of effective lines is set to 5. And so on. On the other hand, in the present embodiment, as described above, three or two medals are inserted to play the game, and in all the games, one line shown in FIG. 6 (A) becomes an effective line. There is no change in the number of effective lines depending on the number of medals inserted. Therefore, in the present specification, the term "effective line" refers to the line shown in FIG. 6 (A).

7 to 12 are diagrams showing the types of combinations (combinations included in the condition device drawn by the combination lottery means 61 described later), the number of payouts, and the combination of symbols in the present embodiment. In addition, although it is not a combination, FIG. 12 shows pattern symbols 01 to 03 as a combination of symbols displayed when the winning combination is missed when a specific condition device is won (numbers "101" to "101" to "120").

The roles of the present embodiment are roughly classified into a special role, a replay (replaying role), and a small role.
Then, the combination of symbols corresponding to each combination and the number of payouts at the time of winning are determined. When all reels 31 are stopped, if the combination of symbols corresponding to any of the winning combinations is stopped at the effective line (the winning combination is won, the same applies hereinafter), the number of medals corresponding to the winning combination is paid out.
However, the number of payouts at the time of winning a special role is set to 0. In the replay, medals are automatically inserted (replay).

In FIGS. 7 to 12, the "specified number 3" displayed on the number of payouts and the like indicates the number of payouts and the like when the specified number is 3 (when the accessory is not operating, that is, the number of inserts during the normal game). , "Specified number 2" indicates the number of payouts when the specified number is 2 (when the accessory is activated, that is, the number of inserted cards during the special game). For example, the replay 01 of the number "3" indicates that the replay is performed with the specified number of 3 cards, and the "-" of the specified number of 2 cards indicates that the lottery is not performed.

In FIG. 7, the numbers "1" and "2" correspond to special roles (roles). In the present embodiment, only 1BB is provided as a special role, and 1BB has two types (1BBA and 1BBB).
The special role is a role that shifts from a normal game to a special game.
If you win 1BB, you will not be paid out medals in this game, but from the next game, you will shift to the 1BB game, which is equivalent to a special game (operation of the character).
During the 1BB game (when the character is activated), the ball output rate is set to exceed "1", so that medals can be expected to be obtained more than when the character is not activated, which is an advantageous game for the player. ..

In addition, the replay (replay role) is a role that enables the replay to maintain the number of medals inserted in the game this time (automatically bet the medals).
As shown in FIG. 7, the replay of the present embodiment includes replays 01 to 06 (numbers "3" to "13").
Replays 02 and 03 are replays that, if a prize is won in a specific RT, will be transferred to another RT. Therefore, these replays are also referred to as transitional replays.

More specifically, when the replay 02 wins in RT2, the game shifts to RT3 (RT advantageous to the player) from the next game. Therefore, the replay 02 is also referred to as a promotion replay.
Further, when the replay 03 wins in RT3, the game is shifted to RT2 (RT which is more disadvantageous to the player than the previous RT) from the next game. Therefore, the replay 03 is also referred to as a fall (demotion) replay.

Further, the replays 04 and 05 are firstly used as control replays for the purpose of increasing the types of condition devices by winning a plurality of replays in duplicate. Replay A replay included in B2, B3, C2, C3, or E. When the replays B2, B3, C2, or C3 are won, the replay 04 or 05 as the control replay does not stop at the effective line.

Further, the replays 04 and 05 are secondly used as a rare replay and are included in the replay E of the condition device described later. When Replay E is won during the advantageous section, the addition of the advantageous section is executed. It should be noted that the addition may not always be executed, but the addition lottery may be performed.
Further, the replay 06 is a replay drawn by lottery during the operation of 1BB, and is included in the replay D of the condition device described later. When Replay D is won during the advantageous section, the addition of the advantageous section is executed. It should be noted that the addition may not always be executed, but the addition lottery may be performed.

Further, as shown in FIGS. 7 to 11, the small combination includes small combinations 01 to 40 (numbers “14” to “100”). Small wins 01 and 02 are small wins (small wins corresponding to higher bells) that win a prize in the correct push order when the push order bell is won, which will be described later. In addition, the small wins 03 to 34 are small wins (small wins corresponding to the cheap bells) that can be won (PB ≠ 1) in the incorrect push order when the push order bell is won.
Furthermore, the small wins 35 to 38 are rare small wins (small wins corresponding to watermelons or cherries).
Further, the small winning combinations 39 and 40 are small winning combinations that can be won only when the specified number is two, that is, when the accessory is operated.

As described above, the pattern symbols 01 to 03 are not the winning combination itself, but appear when the winning combination is missed (when the winning combination is not won) when the pressing order is incorrect when the push order bell is won. It is a combination of symbols. Further, the pattern symbol is a symbol that shifts RT (shifts to RT2 in this embodiment) when the combination of the symbols stops at the effective line at a specific RT (non-RT, RT1, or RT3 in this embodiment). It is a combination. In the present embodiment, the pattern symbols 01 to 03 always appear when the winning combination is missed (when the winning combination is not won) when the push order is incorrect when the small combination B group is won. However, other combinations of symbols (not the combination itself) may appear.

In each of the above-mentioned roles, if the combination of symbols corresponding to the combination does not stop at the effective line in the game in which the combination is won, the combination that is carried over to the next game and the combination that is not carried over is defined. ..
The carry-over role is 1BB in this embodiment. When 1BB is won, the winning information of the 1BB is controlled to be carried over to the next game or later in the game until the 1BB wins.

On the other hand, the winning of 1BB is carried over, while the small roles and replays other than 1BB are not carried over. When a small winning combination or replay is won in the lottery of the conditional device, the winning combination is valid only in this game, and the winning is not carried over to the next game or later. That is, in the game in which these winning combinations are won, the reel 31 is stopped and controlled so that the combination of symbols corresponding to the winning 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 the winning combination will be extinguished.

When starting the game, the player inserts the medals stored in advance by operating the bet switch 40 (storage bet), or takes care of the medals from the medal insertion slot 43 (care bet). When the start switch 41 is operated with a specified number of medals bet, a signal generated at that time is input to the main control board 50. When the main control board 50 (specifically, the reel control means 65 described later) receives this signal, the winning combination lottery means 61 draws a winning combination, and all the motors 32 are driven and controlled to drive and control all the reels. It is controlled to rotate 31. By rotating the reel 31 by the motor 32 in this way, the symbol on the reel 31 is moved and displayed in the vertical direction in the display window 17 at a predetermined speed.

Then, by pressing the stop switch 42, the player stops 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 the main control board 50 (specifically, the reel control means 65 described later) receives this signal, it drives and controls the motor 32 corresponding to the stop switch 42 to correspond to the winning combination lottery result of the winning combination lottery means 61. The stop control of the reel 31 related to the motor 32 is performed so as to be performed.

Then, the game result of this game is displayed by the combination of the symbols when all the reels 31 are stopped. Further, when the combination of symbols corresponding to any of the winning combinations stops at the valid line (when the winning combination is won), the medals corresponding to the winning winning combination are paid out.

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 includes the following combination lottery means 61 and the like. The following means in the present embodiment are examples, and are not limited to the means shown in the present embodiment.

The combination lottery means 61 draws (determines, selects) a condition device (winning combination). Therefore, the winning combination lottery means 61 is also referred to as a condition device determination (lottery or selection) means, a winning combination determination (lottery or selection) means, and the like.
Further, "winning of the condition device" is also referred to as a winning combination lottery result, a lottery result, a winning number, a winning result, and the like.

The combination lottery means 61 is based on, for example, a random number generating means (hardware random number or the like) for lottery, a random number extracting means for extracting random numbers generated by the random number generating means, and a random number value extracted by the random number extracting means. It is provided with a determination means for determining whether or not the condition device has been won and the winning condition device.

The random number generation means generates random numbers in a predetermined region (for example, "0" to "65535" in decimal). The random number is, for example, a random number that the counter that counts 1 in 200 n (nano) sec keeps counting in the range of "0" to "65535" as one cycle, and is a random number while the power of the slot machine 10 is turned on. Keep counting.

The random number extraction means extracts the random numbers generated by the random number generation means at a predetermined time, in the present embodiment, when the start switch 41 is operated (on) by the player. The determination means determines the condition device corresponding to the region to which the random number value belongs by collating the random number value extracted by the random number extraction means with the condition device lottery table described later. For example, if the extracted random number value belongs to the area of the winning and replay condition device number "1" (replay A), it is determined that the replay A is won.

13 to 16 are diagrams showing the types of condition devices drawn by the combination lottery means 61 and the contents of the winning combination included in each condition device.
In the following description, the condition device will be mainly described, and the details of the stop control of the reel 31 based on the pressing order of the stop switch 42 and the operation timing at the time of winning each condition device will be described in the reel control means 65. do.

As described above, the condition device of the present embodiment is a "character condition device" which is a condition device including any of the special roles that can carry over the winning information to the next game, and the winning information is not carried over to the next game. It consists of a "winning and replay condition device" which is a condition device including either a small win or a replay.
The winning of the accessory condition device corresponds to the winning of 1BB in the present embodiment, and includes the accessory condition device numbers "1" and "2".
The character condition device number "0" corresponds to the non-winning of the special role, the character condition device number "1" corresponds to the winning of 1 BBA, and the character condition device number "2" corresponds to the winning of 1 BBB. Equivalent to.

Further, for example, when the replay A is won, the accessory condition device number is "0", and the winning and replay condition device numbers are "1".
On the other hand, when 1BBA alone is won, the accessory condition device number is "1", and the winning and replay condition device number is "0".

Furthermore, in the present embodiment, there is a case where 1BB and the small winning combination are duplicated. For example, when 1BBA and the small winning combination D are duplicated, the accessory condition device number is "1", and the winning and replay condition device number. Is "26".
If 1BB and a small win or replay are won in duplicate, the prize for the small win or replay is prioritized in this game (the priority can be set arbitrarily). In addition, since the winning of a small role or replay is valid only in this game, the winning is not carried over to the next game, but the winning information of 1BB is carried over to the next game unless a prize is won.

Hereinafter, the winning and replay condition devices will be described.
The condition device number "0" corresponds to a non-winning combination (so-called loss).
Further, the replay A of the condition device number "1" is a single winning of the replay 01. When Replay A is won, Replay 01 wins regardless of the push order (in any push order).

Replays B1 to B3 of condition device numbers "2" to "4" (hereinafter collectively referred to as "replay B group"), replays C1 to C3 of condition device numbers "5" to "7" (hereinafter collectively referred to as "replay B group"). Each of the above is referred to as "replay C group"), which is a duplicate winning of a plurality of types of replays, and is a duplicate winning including at least one of replays 01 or 02. Then, the type of replay to be won is set to be different according to the pressing order of the stop switch 42.
For example, in the replay B1 of the condition device number "2", the replay 02 wins in the push order of the left first stop, and the replay 01 wins in the case other than the left first stop (middle or right first stop).

In the case of duplicate replay winning, the replay (replaying role) wins regardless of the push order, so there is no concept of high / low medals. However, for example, when the replay B1 is won in RT2, the RT is promoted (shifted from RT2 to RT3) by winning the replay 02 in the left first stop. On the other hand, except for the first stop on the left, RT2 is maintained by winning the replay 01.
Further, when the replay C1 is won in the RT3, the RT3 is maintained by winning the replay 01 at the first left stop. On the other hand, except for the first stop on the left, the RT is dropped (demoted) (shifted from RT3 to RT2) by winning the replay 03.

The replay D of the condition device number "8" is a single winning of the replay 06. When Replay D is won, Replay 06 wins regardless of the push order.
Similarly, the replay E of the condition device number "9" is a duplicate winning of the replays 04 and 05. When Replay E is won, Replay 04 or 05 wins regardless of the push order. These replays 04 and 05 have a role as rare replays. In particular, in the present embodiment, if a lottery is drawn at RT1 and Replay E is won during RT1 and the advantageous section, the advantageous section is added. It should be noted that the addition may not always be executed, but the addition lottery may be performed.

In FIG. 14, the small winning combination A of the condition device number “10” is attached to the so-called common bell, and the small winning combination 01 is independently elected. Then, when the small winning combination A is won, the small winning combination 01 always wins regardless of the order in which the stop switch 42 is pressed (PB = 1).
Further, in FIGS. 14 to 15, the small combinations B1 to B12 (hereinafter collectively referred to as "small combination B group") of the condition device numbers "11" to "22" correspond to so-called push order bells. , Small win 01 (9 bells, 9 wins) and at least one of small wins 03-34 (1 win).

When these conditional devices are won, a small winning combination 01, which is a high bell (9 bells, 9 winning combination), is awarded with "PB = 1" in the correct pressing order according to the pressing order of the stop switch 42. On the other hand, when the order is incorrect, the small winning combination 03, which is a cheap bell (single combination), depends on the operation timing of the stop switch 42 (the position of the reel 31 at the moment when the stop switch 42 is operated). There are cases where ~ 34 wins a prize and cases where none of the small wins wins (when a pattern symbol is displayed due to omission).

In FIG. 16, the small combinations C1 to C3 (hereinafter collectively referred to as “small combination C group”) of the condition device numbers “23” to “25” are so-called pushes, as in the above small combination B group. It corresponds to a forward bell, and is a duplicate winning including a small winning combination 02 (3 bells, 3 playing cards) and a small winning combination 03-10 (1 card winning combination).
When these conditional devices are won, a small winning combination 02, which is a high bell (three bells, three winning combination), wins a prize according to the pressing order of the stop switch 42 with "PB = 1" when the correct answer is pressed. On the other hand, in the case of incorrect answering order, "PB = 1" and one of the small winning combinations 03 to 10 which is a low-pitched bell (one-card winning combination) wins a prize. Therefore, when the small winning combination C group is won, unlike when the small winning combination B group is won, there is no case where the pattern symbol is displayed (missing). Not limited to this, there may be a case where none of the small wins is won.

When the small role B group is won, 9 cards will be paid out when the high bell is won, so when the push order is correct, 3 cards will be put in and 9 cards will be paid out. The number of sheets is "+6". Therefore, the condition device is such that the number of medals increases when the push order is correct, and the number of medals decreases when the push order is incorrect (the number of payouts is 1 or 0).
On the other hand, in the small role C group, 3 cards will be paid out when the high bell is won, so when the push order is correct, 3 cards will be paid out (number of cards inserted) and 3 cards will be paid out (number of cards to be paid out). The difference in the number of sheets is "± 0 sheets". Therefore, when the push order is correct, the number of medals is maintained as it is, and when the push order is incorrect (the number of payouts is one), the number of medals is reduced.

It should be noted that the reason why both the push order bells for paying out 9 pieces and the push order bells for paying out 3 pieces in the correct push order are provided in order to adjust the payout rate. In particular, in the present embodiment, as shown in FIGS. 14 and 15, when the push order is incorrect when the small winning combination B is won, the probability that one winning combination is won is 25%, and the other 75% is a pattern symbol. Is set to be displayed (no payout when the pattern pattern is displayed). On the other hand, as shown in FIG. 16, when the push order is incorrect when the small winning combination C group is won, one winning combination is won with "PB = 1". In this way, by providing two types of push order bells with different numbers of payouts depending on whether the push order is correct or incorrect, and setting the winning probability appropriately, the payout rate can be set in an appropriate range. become.

The small winning combination D of the condition device number "26" corresponds to a rare small winning combination (watermelon). The small winning combination D is a single winning of the small winning combination 35, and is set to "PB ≠ 1".
Further, the small combination E1 of the condition device number "27" and the small combination E2 of the condition device number "28" correspond to the rare small combination (cherry) as in the above small combination D1. The small winning combination E1 is a duplicate winning of the small winning combination 36 and 38, and the small winning combination E2 is a duplicate winning combination including the small winning combination 37 in addition to the above small winning combination 36 and 38. When the small winning combination E1 or E2 is won, the two-card winning combination (small winning combination 36 or 38) wins regardless of the push order.

The small winning combination F of the condition device number "29" is a winning combination that is drawn only during the operation of 1BB (during the 1BB game), and is a duplicate winning of the small winning combination 01 to 39. When the small role F is won, the small role 39, which is a 10-card role, wins with "PB = 1".
The small winning combination G of the condition device number "30" is a winning combination that is drawn only during 1BB operation (during 1BB game), and is a single winning of the small winning combination 40. When the small role G is won, the small role 40, which is a 9-card role, wins with "PB = 1".

17 and 18 are winning probabilities determined by the lottery table when the condition device is drawn by the combination lottery means 61, and show the number of the accessory condition devices and the winning and replay condition devices for each RT. It is a figure. Dividing the numerical values shown in FIGS. 17 and 18 by "65536" gives the winning probability. For example, the number of units for which 1 BBA is independently won is set to "20" and "10" ("30" in total) in both non-RT and RT1 to RT3. Therefore, the single winning probability of 1BBA is "30/65536".

FIG. 17 is a table of number of condition devices that are common to the settings and that can be determined to shift to the advantageous section, or that the addition of the advantageous section is executed (or the additional lottery can be performed).
Here, "common setting" means that there is no setting difference, that is, the setting 1 to the setting 6 have the same numerical value.
Then, when the condition device common to the settings is won, it may always be decided to shift to the advantageous section (decision to add during the advantageous section), or whether or not to shift to the advantageous section ( Whether or not to add during the advantageous section) may be decided by lottery. Alternatively, a conditional device that decides to shift to the advantageous section (decides to add during the advantageous section) and a conditional device that decides not to shift to the advantageous section (decides not to add during the advantageous section). It may be provided.

In the present embodiment, the condition device common to the settings shown in FIG. 17 is provided with a condition device that determines to shift to the advantageous section and a condition device that determines not to shift to the advantageous section. Further, during the advantageous section, the condition device is always set to determine to add the advantageous section.
In FIG. 17, in the normal section, “◯” means that it is decided to shift to the advantageous section, and “x” means that it is decided not to shift to the advantageous section. Further, in the advantageous section, "Δ" means that the advantageous section is decided to be added, and "x" means that the advantageous section is not added.
In FIG. 17, “○” determines to shift to the advantageous section, and “Δ” determines to add the advantageous section, but the present invention is not limited to this, and “○” indicates It may mean that a lottery is performed whether or not to shift to an advantageous section, and “Δ” may mean a lottery whether or not to add an advantageous section.

Further, FIG. 18 shows a conditional device and a number thereof that are not determined to shift to the advantageous section and are not determined to add the advantageous section.
In the present embodiment, the condition device that decides to shift to the advantageous section or decides to add the advantageous section is limited to the time when the condition device shown in FIG. 17 is won, and the condition device shown in FIG. 18 In the winning, neither of them decides to shift to the advantageous section and does not decide to add the advantageous section.
Although the number of settings 1 and 6 is typically shown in FIG. 18, in reality, as described above, the set value has 6 stages of setting 1 to setting 6 and is set. The number of places for each value is specified.

In FIGS. 17 and 18, since the condition device including 1BBA or 1BBB is drawn only in the non-internal part, it is drawn in the non-RT, RT1 to RT3. Further, 1BBA and 1BBB have a case of winning alone and a case of winning multiple times with the small winning combination D, E1 or E2. On the other hand, the small winning combination D, E1 or E2 may be elected independently. The condition device including 1BBA or 1BBB drawn by RT4 is treated as a single winning of the small winning combination D, E1 or E2. Therefore, the total number of small wins D in RT4 is "580" to "585", and the total number of small wins E1 in RT4 is "1030". The total number of small winning combinations E2 in RT4 is "310" to "370".
Further, 1BBB is set as a winning combination when a condition device having a setting difference is won, and it is decided to shift to an advantageous section or add an advantageous section based on the winning of 1BBB. There is nothing.

In addition, Replay D is drawn only while 1BB is in operation. Furthermore, Replay E is drawn only at RT1. Details will be described later, but in the present embodiment, after the operation of 1BBB is completed, the process shifts to RT1. Then, if Replay E is won in this RT1, an advantageous section is added (limited to the advantageous section). Therefore, in order to set it so that it does not appear in other RTs, the replay E is drawn only in RT1.
Further, the small winning combination D and E1 are drawn only when the accessory is not activated, and are not drawn when the accessory is activated.
On the other hand, the small winning combination F and G are not drawn when the accessory is not activated, and are drawn only when the accessory is activated.

Further, in FIG. 17, the total number of single winnings of 1BBA is "30", but in the present embodiment, the number of placements "20" determined to shift to the advantageous section in the normal section and the advantageous section It is divided into the number "10" that decides not to shift. That is, in the case of a single winning of 1BBA, if the number "20" is won, when the game is a normal section, the advantageous section is also won at the same time. On the other hand, in the case of a single winning of 1BBA, if the number "10" is won, the advantageous section will not be won.

In addition, when 1BBA is won alone during the advantageous section, it is decided that the advantageous section will be added regardless of whether the number is "20" or "10".
Similarly, the number of single winnings of the small winning combination E1 is "1000" in total, but in the present embodiment, the number "250" determined to shift to the advantageous section in the normal section and the advantageous section It is divided into the number "750" that decides not to shift to.

Not limited to this, when the single winning number of the small winning combination E1 is set to one placement number "1000" (not divided into the placement number "250" and the placement number "750") and the small winning combination E1 is won. In addition, it may be decided whether or not to shift to the advantageous section by a separate lottery. For example, there is a 25% chance of deciding to move to an advantageous section and a 75% chance of not deciding to move to an advantageous section. In this way, a number that wins the advantageous section and a number that does not win the advantageous section may be provided from the beginning, but the number itself is set to one value, and when the number is won, the section shifts to the advantageous section. A lottery (two-stage lottery) may be held to decide whether or not to do so.
Further, as described above, in the present embodiment, in the case of RT4 (inside the inside), it is not determined to shift to the advantageous section, and the advantageous section is not added. Therefore, even when the small winning combination D or E1 is won, when it is RT4, it is not decided to shift to the advantageous section and the advantageous section is not added (“* 3” in FIG. 17). ..

In FIG. 18, when 1 BBB is won alone or when 1 BBB and small winning combination D are won in duplicate, no decision is made regarding the advantageous section. However, as will be described later, an opportunity to add an advantageous section is provided after the operation of 1BBB is completed (after the transition to RT1).
The small winning combination E2 has a case where the winning is duplicated with 1BBB and a case where the winning is single, but neither of them makes a decision regarding the advantageous section. On the other hand, as shown in FIG. 17, when the small winning combination E1 is won, a decision regarding the advantageous section may be made for both the single winning of the small winning combination E1 and the overlapping winning with 1BBA.

Further, as shown in FIG. 18, the condition devices of the replay A, the replay B group, and the replay C group have the same settings, but they are not determined to shift to the advantageous section and are added in the advantageous section. I don't decide.
However, not limited to the examples of FIGS. 17 and 18, when the condition devices for these replays are won, it is decided to shift to an advantageous section (including a lottery) or to add an advantageous section (including a lottery). ) May be provided. Alternatively, in FIG. 18, in the replay A, the replay B group, and the replay C group, the number of settings is slightly different between the setting 1 and the setting 6 (for example, "1" is different), and the replay A, the replay B group, And the replay C group may be set separately.

In FIG. 18, the replay A is drawn at all RTs when the accessory is not activated. In addition, the replay B1 group is drawn only at RT2. Furthermore, the replay group C is drawn only at RT3. The small winning combination A, the small winning combination B group, and the small winning combination C group all have a setting difference between the setting 1 and the setting 6, but the number is the same in all RTs.

Further, as shown in the table of "special combination and small combination" in FIG. 18, in the setting 1 and the setting 6, the winning probability of 1BB and the small combination is set higher in the setting 6. Therefore, in this respect, setting 6 is more advantageous than setting 1.
Furthermore, as shown in the "Replay" table, RT3 has the highest probability of winning a replay. Then, in the advantageous section, since it is basically set to stay at RT3, not only the number of medals is increased by the operation of the instruction function when the push order bell is won, but also the number of medals is small due to the replay winning. ..

Further, the small winning combination A, the small winning combination B group, and the small winning combination C group are all set in the condition device having a setting difference. Here, the difference in the number of the small winning combination A between the setting 1 and the setting 6 is "250", and the difference in the number of the small winning combination B group (overall) between the setting 1 and the setting 6 is "240 (20 x 12)". ". Therefore, the small winning combination A has a larger difference in number than the small winning combination B group. As a result, by setting the number of small winning combinations A having no winning difference according to the pushing order to a larger value, it is possible to surely provide a difference in the payout rate according to the set value.
Further, since the combination of the symbols that can be won when the small winning combination A is won and the combination of the symbols that can be won when the push order is correct when the small winning combination B is won are set to be the same (described later), the small winning combination A is set. The set value cannot be estimated by counting the number of winnings (winnings).

Further, as shown in FIG. 18, the probability of winning the small winning combination B group is set higher than the probability of winning the small winning combination C group. Here, the maximum number of payouts is 9 when the specified number is 3, and at least 1 instruction function operating game in which the number of payouts is 9 (maximum number of payouts with the specified number of 3) during the advantageous section. Need to run twice. Therefore, in the advantageous section, it is necessary to execute the instruction function operating game at least once when the small winning combination B group is won. Therefore, by setting the winning probability of the small winning combination B group higher than the winning probability of the small winning combination C group, one instruction function operating game (small winning combination C group, replay B group, and replay C group is won). It is possible to reduce the expected number of games in the advantageous section that ends only with (excluding the games played). Furthermore, even though it is an advantageous section that ends after executing a predetermined number of games, it is less likely that the advantageous section cannot be ended because the small winning combination B group was never won during the predetermined number of times. be able to.

The explanation is returned to FIG.
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 combination for all the combinations. Then, when any of the conditional devices is won in the lottery by the winning combination lottery means 61, the winning flag of the winning combination included in the conditional device is turned on (the winning flag is set).

For example, in the non-internal middle game, when the replay B1 is won, the two winning flags of the replay 01 and the replay 02 included in the condition device are turned on, and the winning flags of the other combinations are turned off.
Similarly, in the non-internal medium game, when the small winning combination B1 is won, the small winning combination 01, the small winning combination 03, the small winning combination 10, the small winning combination 11, the small winning combination 18, the small winning combination 19, and the small winning combination are included. The seven winning flags of the winning combination 26 are turned on, and the winning flags of the other winning combinations are turned off.

Furthermore, as described above, the winning of small roles and replays other than 1BB is not carried over, so even if the small role or replay is won in this game and the winning flag of these roles is turned on, the game ends this time. Sometimes the winning flag is turned off.
On the other hand, since the winning of 1BB is carried over, when the winning flag of 1BB is won in this game and the winning flag related to the winning 1BB is turned on once, the on state is maintained until the 1BB is won, and the winning state is maintained. It will be turned off when 1BB wins.

Further, for example, when the winning combination lottery means 61 wins 1BBA and the small winning combination D more than once, the winning flag of the small winning combination 35 corresponding to the 1BBA and the small winning combination D is turned on, and both winning combinations may not be won in the game. Therefore, for example, when 1BBA does not win, the winning flag of 1BBA is kept on and the winning flag of the small winning combination 35 is turned off regardless of whether the small winning combination 35 wins or does not win.

Furthermore, for example, when 1BBA is won alone by the role lottery means 61, the 1BBA winning flag is turned on in this game, and when 1BBA is not won in this game, the 1BBA winning flag is kept on. ..
Furthermore, when the small role A1 is won in the next game, in addition to the 1BBA that has carried over the winning, the winning flag of the small role 01 is turned on, and if 1BBA does not win at the end of this game, 1BBA The winning flag of is kept on, and the winning flag of the small winning combination 01 is turned off.

The push order instruction number selection means 63 selects the push order instruction number based on the lottery result of the condition device by the combination lottery means 61. FIG. 19 is a diagram showing a push order instruction number table.
In either the advantageous section or the normal section, the push order instruction number selection means 63 may select the push order instruction number, but the present invention is not limited to this, and only during the advantageous section, for example. The push order instruction number may be selected. In such a case, the push order instruction number is always "A0" during the normal section.
Further, the selected push order instruction number can be transmitted to the sub control board 80 only during the advantageous section (except for transmitting the push order instruction number "A0" during the normal section). Therefore, even if the push order instruction number is selected by the push order instruction number selection means 63 in the normal section, the push order instruction number is not transmitted to the sub control board 80.
In the present embodiment, as shown in FIG. 19, each condition device is provided with a unique push order instruction number. For example, the push order instruction number corresponding to the replay A is "A0", and the push order instruction number corresponding to the replay C3 is "A3". The push order instruction number includes "A0" to "A3".

FIG. 20 is a diagram showing the relationship between the push order instruction number, the push order corresponding to the push order instruction number, and the display contents 1 and 2. The push order instruction number "A0" does not have a push order that is advantageous to the player (the push order does not cause an advantage / disadvantage, that is, the push order does not matter).
Further, the push order instruction numbers "A1" to "A3" each have a push order that is advantageous to the player. For example, the advantageous push order corresponding to the push order instruction number "A2" is the middle first stop.

The push order corresponding to the push order instruction number in the replay B group is set to the push order for winning the replay 02 (the push order for promoting RT).
Further, the push order corresponding to the push order instruction number in the replay C group is set to the push order in which the replay 01 is won (maintains RT).
Similarly, the push order corresponding to the push order instruction number in the small win B group is set to the push order in which the small win 01 (9 sheets) is won.
Further, the pushing order corresponding to the pushing order instruction number in the small winning combination C group is set to the pushing order in which the small winning combination 02 (3 sheets) is won.

Further, in FIG. 20, “display content 1” indicates the content displayed by the operation of the instruction function (control of the main control board 50), and in the present embodiment, the push order instruction information to be displayed on the acquired number display LED 78 is displayed. Shown. In the present embodiment, the push order instruction numbers "A" and "0" to "3" correspond to the display of "=" and "0" to "3" of the LED (7-segment), respectively. When "=" is displayed, the segments D and G in FIG. 4 of the 7-segments are turned on (see FIG. 26 described later). Further, when the push order instruction number is "A0", no display may be made (no segment is lit).

Furthermore, "display content 2" indicates the content displayed by the control of the sub control board 80, and in the present embodiment, it is the correct answer pressing order to be displayed on the image display device 23.
The "operation of the instruction function" means the display using the acquired number display LED 78 by the main control board 50, and the display by the control of the sub control board 80 is the "operation of the instruction function" of the present invention. Is not included.
For example, when the winning and replay condition device "11" is won in the advantageous section, the push order instruction number "A1" is selected, and when the instruction function is activated, "= 1" is displayed on the acquisition number display LED 78. NS. Further, the image display device 23 displays an image of a content such as "1 ○○" that the player can understand that the left first stop is performed.

In FIG. 19, the push order instruction number (* 1) at the time of winning the small winning combination A is as follows.
When the small winning combination A is won, the small winning combination 01 wins regardless of the pushing order, so there is no advantageous pushing order. However, during the advantageous section, any one of "A1" to "A3" is selected as the dummy push order instruction number. The selectivity is "1/3" respectively. By setting in this way, when the small winning combination A is won in the advantageous section, the instruction function is activated and the push order instruction information is displayed. As a result, the player cannot determine whether the small winning combination A has been won or the small winning combination B group has been won in the game. This setting is for the following reasons.

As shown in FIG. 18, the winning probability (number of places) of the small winning combination A is higher in the setting 6 than in the setting 1. Therefore, the set value can be estimated by counting the number of times the small winning combination 01 has won a prize in the game in which the instruction function does not operate during the advantageous section. In order to avoid such a capture, when the small winning combination A is won in the advantageous section, the instruction function is activated and the dummy push order instruction information is displayed. Of course, it is not impossible to guess the set value by counting the number of times the small winning combination 01 won a prize in the game in which the instruction function is activated, but the number of times the small winning combination 01 won in the game in which the instruction function is not activated. More trials are required than when counting and guessing the set value.

Furthermore, in FIG. 19, the push order instruction information (* 2) at the time of winning the small winning combination E1 and E2 is as follows.
As shown in FIG. 17, when the small winning combination E1 is won in the advantageous section, the advantageous section is added. However, as described above, when 1BB is won during the advantageous section and the inside is inside, the advantageous section is not added. Therefore, in the advantageous section and inside (during the game section in which the advantageous section is not added), the small winning combination E1 is won, and the combination of the symbols corresponding to the small winning combination E1 (the combination of the symbols expected to be added in the advantageous section). When a certain middle cherry) stops, it may give the player the impression of wasting money. Therefore, when the small winning combination E1 is won in the advantageous section and inside, the push order instruction number "A3" is selected, the instruction function is activated, and "right first stop" is displayed.

When the stop switch 42 is operated at the first right stop when the small winning combination E1 is won, the so-called middle cherry does not stop as shown in FIG. This makes it difficult to notice the winning of the small role E1. Since the number of small winning combinations 36 or 38 that can be won when the small winning combination E1 is won is two, there is no disadvantage to the player even if the right first stop is instructed.

Further, as described above, the advantageous section has a maximum number of games set, and is set within 1500 games in the present embodiment. Therefore, even if there is a remaining number of games in the advantageous section, when the number of games from the start of the advantageous section reaches 1500 games, the advantageous section is forcibly terminated unconditionally.
In the case of having such playability, for example, if the small winning combination E1 is won when the game is close to 1500 games in the advantageous section and the middle cherry is displayed, the player expects the addition of the advantageous section. Therefore, in the present embodiment, after 1400 games or more have been reached since the start of the advantageous section, even if the small winning combination E1 is won, the middle-tier cherry is not displayed as in the case of winning inside. , Activate the instruction function and display the right first stop.

When the small winning combination E2 is won, as shown in FIG. 18, no decision is made regarding the advantageous section. However, when the small winning combination E2 is won, if the stop switch 42 is operated at the left or middle first stop, the middle cherry may be displayed. Therefore, if the middle-tier cherry is displayed when the game is 1400 or more in the inside or from the start of the advantageous section, the player may be misunderstood. Therefore, in this case as well, the instruction function is activated. , Right first stop is displayed.
However, not limited to this, when the small winning combination E2 is won, since the determination regarding the advantageous section is not made in the first place, the middle-stage cherry may be displayed without operating the above-mentioned instruction function.

In FIG. 1, the effect group number selection means 64 is an effect group number corresponding to the winning condition device, and selects a number to be transmitted to the sub control board 80.
As a result of drawing the condition device, it is also conceivable to transmit the winning prize and the replay condition device number itself to the sub control board 80. However, in the present embodiment, the winning prize and the replay condition device number itself are not transmitted to the sub control board 80. As a result, the sub-control board 80 side cannot know the winning and replay condition device numbers won in this game.

On the other hand, on the main control board 50 side, the effect group number corresponding to the winning condition device is predetermined. Then, after the lottery of the condition device, the effect group number corresponding to the winning condition device is selected, and the effect group number is transmitted to the sub control board 80. When the sub control board 80 receives the effect group number selected in the game this time, the sub control board 80 can select and output the effect corresponding to the effect group number.

FIG. 21 is a diagram showing an effect group number table.
In the present embodiment, as shown in FIG. 21, each condition device is provided with a unique effect group number. For example, the production group number corresponding to the winning of the small winning combination A, the small winning combination B group, and the small winning combination C group is defined as "5". The production group numbers corresponding to the winning of the small winning combination A, the small winning combination B group, and the small winning combination C group may be different, such as "5", "6", and "7", respectively.

Therefore, when the main control board 50 wins the small winning combination A, the small winning combination B group, or the small winning combination C group as a result of the lottery of the condition device, "5" is selected as the effect group number. Then, the information of the selected effect group number "5" is transmitted to the sub control board 80.
When the sub-control board 80 receives the information that the effect group number is "5", it can know that in this game, it has won any of the small winning combination A, the small winning combination B group, or the small winning combination C group. can. As a result, the winning effect of the bell can be output.

However, even if the sub-control board 80 receives the information that the production group number "5" has been won, or even when the sub-control board 80 has won any of the small winning combination B groups in the game, the correct answer is pushed. You can't know the order. Then, in the present embodiment, the push order instruction number corresponding to the correct push order is transmitted to the sub control board 80 during the advantageous section, but is not transmitted during the normal section or the standby section. Therefore, during the advantageous section, the sub-control board 80 may output the fact that the small winning combination A, the small winning combination B group, or the small winning combination C group has been won and the correct push order corresponding to the push order instruction number as an effect. can. On the other hand, in the normal section and the standby section, the sub-control board 80 only produces the effect that the small winning combination A, the small winning combination B group, or the small winning combination C group (bell) is won, and the correct answer is pushed in order. Cannot be output as a production.

Further, even if the same push order instruction number is transmitted to the sub control board 80, different effects can be output because the effect group numbers are different. For example, the push order instruction number when the replay B1 is won is "A1" (left first), and the push order instruction number when the small winning combination C1 is won is "A1" (left first). In each case, the same push order instruction number is transmitted to the sub control board 80.

However, when the replay B1 is won, the production group number "2" is transmitted, and when the small winning combination C1 is won, the production group number "5" is transmitted. Therefore, when the production group number "2" is transmitted, it is possible to notify the correct answer pressing order using, for example, the blue color indicating the replay, and when the production group number "5" is transmitted, for example, the bell. It is possible to notify the correct answer pressing order using the yellow color indicating.

In FIG. 1, the reel control means 65 starts the rotation of all (three) reels 31 when the rotation start command of the reels 31 is received, particularly when the start switch 41 is operated in the present embodiment. Control to. Further, the reel control means 65 refers to the on / off of the winning flag in the game this time after the lottery of the condition device is performed by the winning combination lottery means 61, and the stop position determination table corresponding to the on / off of the winning flag. Is selected, and 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 stop switch 42 is operated, and the motor 32 is driven. It is controlled to stop the reel 31 at the determined position.

For example, in the game in which at least one winning flag is turned on, the reel control means 65 sets a combination of symbols corresponding to the winning combination (the winning combination with the winning flag 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 effective line, and the reel 31 is stopped and controlled so that the combination of symbols corresponding to the winning combination other than the winning combination (the winning combination with the winning flag turned off) is not stopped on the effective line. ..

Here, "within the range of stop control 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 frames (designs)). Means within range.
In the present embodiment, the reel 31 is rotated at a speed of about 80 rotations in one minute at a constant speed.
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 set within 190 ms. As a result, in the present embodiment, the maximum number of moving frames from the symbol at the moment when the stop switch 42 is operated until the reel 31 is stopped is set to 4 frames.

For example, in FIG. 5, when the left stop switch 42 is operated at the moment when the first "replay" of the left reel 31 is located in the lower left stage (on the effective line), it is four frames ahead, that is, the fifth "bell". Up to "B" is a symbol that can be stopped in the lower left row. Therefore, at the above operation timing, the symbols No. 1 (stopping bitterness) to No. 5 (4 frames) are symbols that can be stopped in the lower left row.

However, not limited to the above, it is also possible to set the maximum number of moving frames to 4 from the next symbol of the symbol located on the effective line at the moment when the stop switch 42 is operated. In this case, for example, when the left stop switch 42 is operated at the moment when the first "replay" of the left reel 31 is located at the lower left stage, the next symbol, that is, the second "blank" is started. Up to the 6th "replay", which is the symbol 4 frames ahead, is the symbol that can be stopped in the lower left row. Therefore, at the above operation timing, the symbols 2 to 6 are symbols that can be stopped in the lower left row.
In the following description, the maximum number of moving frames from the symbol located on the effective line at the moment when the stop switch 42 is operated will be described as 4 frames.

First, at the moment when the operation of the stop switch 42 is detected, when any of the symbols within the range of the stop control of the reel 31 is a symbol to be stopped at a predetermined effective line, when the stop switch 42 is operated. The symbol is controlled to stop at a predetermined effective line.

That is, if the reel 31 is stopped immediately at the moment when the stop switch 42 is operated, and the symbol related to the winning combination does not stop at the predetermined effective line, the stop control of the reel 31 is performed until the reel 31 is stopped. By controlling the rotation and movement of the reel 31 within the range of, the design related to the winning combination is controlled to be stopped at a predetermined effective line as much as possible (pull-in stop control).

On the contrary, if the reel 31 is stopped immediately at the moment when the stop switch 42 is operated, when the combination of symbols corresponding to the winning combination stops at the effective line, the reel is stopped when the reel 31 is stopped. By controlling the rotation and movement of the reel 31 within the range of the stop control of 31, it is controlled so that the combination of symbols corresponding to the winning combination is not stopped on the effective line (kicking stop control).
Further, in the game in which a plurality of winning combinations are won, the priority order of the winning combination is predetermined according to the pressing order of the stop switch 42 and the operation timing of the stop switch 42. Controls the pull-in stop of the symbol with the highest priority.

Further, the reel control means 65 detects the pressing order (operation order) of the stop switch 42. The reel control means 65 detects which of the left, middle, and right stop switches 42 is operated when the stop switch 42 is operated by the player.
When the stop switch 42 is operated, a signal indicating that the stop switch 42 is operated is input to the reel control means 65. By discriminating this signal, the reel control means 65 detects which stop switch 42 has been operated. Then, the stop control of the reel 31 corresponding to the operated stop switch 42 is executed.

Further, the reel control means 65 includes a stop position determination table for each condition device. The 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. Then, in each stop position determination table, for example, when the stop switch 42 is operated at the moment when the first symbol (“replay” in the case of the left reel 31) passes through the lower left stage (on the effective line), what is it? The stop position is predetermined, such as controlling the movement of only the symbol (with how many frames) and stopping the symbol at the lower left.

Here, the symbol arrangement in the present embodiment will be described.
First, as shown in FIG. 5, four "replays" are arranged at intervals of five symbols on all reels 31. As a result, the "replay" of all reels 31 is in the "PB = 1" arrangement.
Similarly, on the left reel 31, four "bell A" or "bell B" are arranged at intervals of five symbols. As a result, the total arrangement of these two symbols is "PB = 1".
Further, in the middle reel 31, four "bells C" are arranged at intervals of five symbols. As a result, the "bell C" of the middle reel 31 is arranged at "PB = 1".
Furthermore, on the right reel 31, four "bell A" or "bell B" are arranged at intervals of five symbols. As a result, the total arrangement of these two symbols is "PB = 1".

Further, on the right reel 31, four "cherries" are arranged at intervals of five symbols. As a result, the "cherry" on the right reel 31 has a "PB = 1" arrangement.
Further, on the left reel 31, four "black 7" or "watermelon" are arranged at intervals of 5 symbols. As a result, the total arrangement of these two symbols is "PB = 1".
Similarly, on the middle reel 31, four "blue 7" or "cherry" are arranged at intervals of five symbols. As a result, the total arrangement of these two symbols is "PB = 1".
Similarly, on the right reel 31, four "black 7", "blue 7", "blank", or "red 7" are arranged at intervals of 5 symbols. As a result, the total of these four symbols is "PB = 1".

On the other hand, in the left reel 31, "cherries" are arranged at Nos. 3, 8 and 13, so they are not arranged at "PB = 1".
Similarly, for the "watermelon", the left and middle reels 31 have a "PB ≠ 1" arrangement, and the right reel 31 has a "PB = 1" arrangement.

Hereinafter, the stop position determination table corresponding to each condition device will be described with reference to FIGS. 13 to 16 described above.
First, the stop position determination table at the time of winning and winning the replay condition device will be described.
The non-winning table is used in the game when the winning combination is not won, and the combination of symbols when the reel 31 is stopped is defined so that the combination of symbols corresponding to any winning combination does not stop at the effective line.

The replay A table is used at the time of replay A winning (single winning of replay 01), and the reel is used so that the replay 01 is stopped at the effective line within the range of the stop control of the reel 31 regardless of the pressing order of the stop switch 42. The stop position of 31 is defined. The symbols of the reels 31 related to the replay 01 and the replays 02 to 06 described later are all the reels 31 in the “PB = 1” arrangement. Therefore, when a replay is won, the winning replay (when a plurality of replays are duplicately won, one of the duplicate winning replays) is always won.

The replay B1 table is used in the game when the replay B1 is won, and within the range of the stop control of the reel 31, when the left first stop (when the push order is correct), the replay 02 is stopped at the effective line and the left first stop. Other than the time (when the push order is incorrect), the stop position of the reel 31 is determined so that the replay 01 is stopped at the effective line (see FIG. 13).

First, in a game in which the replay B1 table is used, "Black 7" or "Watermelon" is stopped in the lower left row at the time of the first left stop ("PB = 1" as described above). In this case, "replay" stops at the upper left.
Next, at the time of the second middle stop, the "replay" is stopped in the middle middle stage. Then, at the time of the third stop on the right, "cherry" is stopped in the upper right row. In this case, "replay" stops at the lower right. As a result, "Black 7 / Watermelon"-"Replay"-"Cherry" stops on the effective line, and Replay 02 wins. Further, "replay"-"replay"-"replay" is stopped in "upper left"-"middle middle"-"lower right".

On the other hand, in the game in which the replay B1 table is used, "blue 7" or "cherry" is stopped in the middle middle stage at the time of the first middle stop ("PB = 1"). In this case, "replay" stops in the upper middle row. After that, when the left reel 31 is stopped, "black 7" or "watermelon" is stopped in the lower left stage ("PB = 1"). At this time, as described above, "replay" stops at the upper left.
When the right reel 31 is stopped, "replay" is stopped in the upper right row ("PB = 1"). As a result, "Black 7 / Watermelon"-"Blue 7 / Cherry"-"Replay" stops on the effective line, and Replay 01 wins. Further, "replay"-"replay"-"replay" is stopped in "upper left"-"middle upper"-"upper right".

In the game in which the replay B1 table is used, the control is the same at the time of the first right stop as at the time of the first stop at the middle.
Further, with respect to the replay B2 table when the replay B2 is won and the replay B3 table when the replay B3 is won, the replay 02 is won when the push order is correct and the replay 01 is won when the push order is incorrect by the same control as described above.

The replay C1 table is used in the game when the replay C1 is won, and within the range of the stop control of the reel 31, when the left first stop (when the push order is correct), the replay 01 is stopped at the effective line and the left first stop. Other than the time (when the push order is incorrect), the stop position of the reel 31 is determined so that the replay 03 is stopped at the effective line (see FIG. 13).

First, in the game in which the replay C1 table is used, the control of stopping the replay 01 at the effective line at the time of the first left stop is the same as that of the replay B1 table, so the description thereof will be omitted.
Further, in the game in which the replay C1 table is used, the "replay" is stopped in the middle middle stage at the time of the first middle stop ("PB = 1"). After that, when the left reel 31 is stopped, "Bell A" or "Bell B" is stopped in the lower left stage ("PB = 1"). In this case, "replay" stops in the middle left. When the right reel 31 is stopped, the "watermelon" is stopped in the upper right row ("PB = 1"). In this case, "replay" stops in the middle right. As a result, "Bell A / Bell B"-"Replay"-"Watermelon" stops on the effective line, and the replay 03 is won. Further, "replay"-"replay"-"replay" is stopped at "left middle stage"-"middle middle stage"-"right middle stage".

In the game in which the replay C1 table is used, the control is the same at the time of the first right stop as at the time of the first stop at the middle.
Furthermore, for the replay C2 table when the replay C2 is won and the replay C3 table when the replay C3 is won, the replay 01 is won when the push order is correct and the replay 03 is won when the push order is incorrect by the same control as above. ..

The replay D table is used in the game when the replay D is won, and the stop position of the reel 31 is set so as to stop the replay 06 on the effective line within the range of the stop control of the reel 31 regardless of the pressing order of the stop switch 42. It is a fixed one. Replay 06 is "PB = 1".
Further, the replay E table is used in the game at the time of winning the replay E, and the reel is used so that the replay 04 or 05 is stopped at the effective line within the range of the stop control of the reel 31 regardless of the pressing order of the stop switch 42. The stop position of 31 is defined. In this case, either Replay 04 or 05 can be stopped at "PB = 1".

The small winning combination A table is used in the game when the small winning combination A is won, and the small winning combination 01 is stopped at the effective line within the range of the stop control of the reel 31 regardless of the pressing order of the stop switch 42. It defines the stop position. The combination of the symbols of the small winning combination 01 is "black 7 / watermelon"-"bell C"-"replay", and "PB = 1" on all reels 31. When "Black 7 / Watermelon" stops in the lower left row, "Bell A / Bell B" stops in the middle left row. Furthermore, when "Replay" stops in the upper right row, "Bell A / Bell B" stops in the middle right row. Therefore, when the small winning combination 01 is won, "Bell A / Bell B"-"Bell C"-"Bell A / Bell B" stops at "Left middle tier"-"Middle middle tier"-"Right middle tier".

The small winning combination B1 table is used in the game when the small winning combination B1 is won, and within the range of the stop control of the reel 31, when the left first stop (when the push order is correct), the small winning combination 01 is stopped at the effective line and left. Except for the first stop (when the push order is incorrect), the one-card combination included in the winning combination (when the small combination B1 is won, one of the small combination 03, 10, 11, 18, 19, 26) is played. The stop position of the reel 31 is determined so as to stop at the effective line or stop any of the pattern symbols 01 to 03.

In the game in which the small winning combination B1 table is used, the left first stop (when the push order is correct) is the same as that of the small winning combination A table, so the explanation is omitted.
Even when the following small winning combination B2 table to small winning combination B12 table are used, the same stop control as the small winning combination A table is performed when the push order is correct.
As a result, when the small win A is won and when the push order is correct when the small win B group is won, the small win 01 always wins, and the "left middle"-"middle middle"-"right middle" is displayed. "Bell A / Bell B"-"Bell C"-"Bell A / Bell B" stops. Therefore, even if the small winning combination 01 wins in a game in which the instruction function is not activated, the player does not know whether the small winning combination A is won or the push order is correct when the small winning combination B group is won.

Further, even during the advantageous section, when the small winning combination A is won, if the instruction function is activated by the dummy as described above, the player can determine whether the small winning combination A is won or the small winning combination B group is won. I don't know.
As described above, in the present embodiment, since there is a setting difference in the number of winnings of the small winning combination A, it is possible to estimate the set value by counting the number of winnings of the small winning combination A. However, if the stop rolls are the same when the small role A is won and when the push order is correct when the small role B group is won, it is not possible to count only the number of winnings of the small role A, so the set value. Can no longer be guessed.

Further, more specifically, in the game in which the small winning combination B1 table is used, the following stop control is executed.
First, when the small winning combination B1 is won, as shown in FIG. 14, seven small winning combinations 01, 03, 10, 11, 18, 19, and 26 are won, and the combinations of the symbols are as follows.
Small role 01: "Black 7 / Watermelon"-"Bell C"-"Replay" (9 sheets)
Small role 03: "Bell A"-"Bell A"-"Bell A" (1 sheet)
Small role 10: "Bell B"-"Bell B"-"Bell B" (1 sheet)
Small role 11: "Bell C"-"Bell A"-"Blue 7" (1 sheet)
Small role 18: "Red 7"-"Bell B"-"Red 7" (1 sheet)
Small role 19: "Bell C"-"Blue 7"-"Bell A" (1 sheet)
Small role 26: "Red 7"-"Red 7"-"Bell B" (1 sheet)

Then, the following method can be mentioned as the stop control of the reel 31 when a plurality of small winning combinations having different payout numbers are elected in duplicate.
As a first priority, when all the symbols (of the reel 31) constituting the winning symbol combination can be stopped at the effective line, the reel 31 is stopped at that position.

Next, when it is not possible to "stop all the symbols that make up the winning combination of symbols on the effective line" (when the first priority cannot be adopted), the second priority is "number of sheets priority". , Or "number priority" to stop and control the reel 31.
Here, "number of sheets priority" means that among the combinations of symbols that have been won in duplicate, the symbols of the reel 31 that constitutes the combination of the symbols with the largest number of payouts are preferentially stopped (pulled in) to the effective line. To say. Therefore, when the small winning combination B group is won, the small winning combination 01 corresponds to the combination of the symbols with the largest number of payouts (9).
On the other hand, "number priority" means that the symbols of the reel 31 are stopped at the effective line so that the number of combinations of symbols that can be stopped at the effective line is the largest.

For example, when the small winning combination B1 is won and the middle first stop is made, all the middle reels 31 related to the winning winning combination cannot be stopped at the effective line at the same time. This is because there are a plurality of types of symbols of the winning small winning medium reel 31, whereas there is only one effective line, so only one type of symbol can be stopped at the effective line.

Therefore, when the small winning combination B group is won, the reel 31 is stopped and controlled by either the number priority or the number priority. In the present embodiment, when the push order is correct, the reels are stopped and controlled by giving priority to the number of sheets, and when the push order is incorrect, the reels 31 are stopped and controlled by giving priority to the number of sheets. When the reels are stopped and controlled by giving priority to the number of reels, the small winning combination 01 (9-card winning combination) is configured so that one winning combination can be won without winning (so that it may be missed).
In this way, the operation mode of the stop switch 42 is such that the number of sheets is prioritized in a specific pressing order (correct answer pressing order in the present embodiment), and the number is prioritized in another pressing order (incorrect answer pressing order in the present embodiment). Depending on the number of sheets, priority is given to the number of sheets or the number of sheets.

In the above example, when the number is prioritized at the time of the middle first stop (when the push order is incorrect), if either "Bell A" or "Bell B" is stopped at the effective line, the number is stopped at the effective line. The maximum number of possible combinations of symbols is two each. For example, if "Bell A" is stopped at the effective line when the middle reel 31 is stopped, the small winning combination 03 or 11 can be won. Since "Bell A" or "Bell B" of the middle reel 31 is "PB = 1" in the sum of the two symbols, either "Bell A" or "Bell B" is always stopped when the middle reel 31 is stopped. Can be made to.
Here, it is assumed that the "bell A" is stopped when the middle reel 31 is stopped. In this case, at this point, the small winning combination 03 or 11 can be won.

Next, when stopping the left reel 31, priority is given to stopping "bell A" or "bell C" at the effective line. As shown in FIG. 5, in the left reel 31, "bell A" is arranged at Nos. 15 and 0, and "Bell C" is arranged at Nos. 18. Therefore, when the symbols of the left reel 31 at the moment when the stop switch 42 is operated are the 11th to the 19th and the 0th, the "bell A" or the "bell C" can be stopped at the effective line. When the numbers are 1 to 10, "Bell A" or "Bell C" cannot be stopped at the effective line.

Therefore, when the left reel 31 is stopped at random (without aiming at a specific symbol), "Bell A" or "Bell C" is stopped at the effective line with a probability of "1/2". In particular, in the present embodiment, since the "bell A" can be stopped without stopping the "bell C", the symbols of the left reel 31 at the moment when the stop switch 42 is operated are the 11th to 19th and the 0th. When is, "Bell A" is always stopped at the effective line.
In this way, stopping "Bell A" without stopping "Bell C" makes it possible to display the pattern symbol described later when the winning combination is missed at the time of the third stop. This is because the pattern symbol cannot be displayed if "Bell C" is stopped when the left reel 31 is stopped).

On the other hand, when the "bell A" cannot be stopped at the effective line when the left reel 31 is stopped, control is performed so that one of the pattern symbols is stopped at the effective line. As shown in FIG. 12, among the pattern symbols in which the symbol of the middle reel 31 is "bell A", the symbol of the left reel 31 is "black 7" or "watermelon". Since the "black 7" or "watermelon" of the left reel 31 is "PB = 1" in the sum of the two symbols, any one of these symbols can always be stopped.

Therefore, at the time of the middle first stop and the left second stop, it becomes "bell A"-"bell A"-"rotating", or "black 7 / watermelon"-"bell A"-"rotating". ..
Further, when "Bell A"-"Bell A"-"Rotating" is set before the third stop on the right, "Bell A" can be stopped on the effective line when the right reel 31 is stopped. Stop "Bell A". As shown in FIG. 5, in order to stop "Bell A" at the effective line, "Bell A" is stopped if the design of the effective line at the moment when the stop switch 42 is operated is in the range of 4 to 13. It can be made to stop, and "Bell A" cannot be stopped in other ranges. Therefore, when the right reel 31 is stopped at random, the "bell A" is stopped at the effective line with a probability of "1/2". When "Bell A" is stopped on the effective line when the right reel 31 is stopped, "Bell A"-"Bell A"-"Bell A" is obtained, and the small winning combination 03 is won.

On the other hand, in the case of "Bell A"-"Bell A"-"Rotating", if "Bell A" cannot be stopped on the effective line when the right reel 31 is stopped, "Cherry" is set as the effective line. Stop ("PB = 1"). As a result, the combination of symbols on the effective line becomes "bell A"-"bell A"-"cherry", and the pattern symbol 03 is stopped.
Further, in the case of "Black 7 / Watermelon"-"Bell A"-"Rotating", when the right reel 31 is stopped, "Bell A" or "Bell B" is stopped on the effective line ("PB = 1"). ). As a result, the combination of symbols on the effective line becomes "black 7 / watermelon"-"bell A"-"bell A / bell B", and the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped on the effective line at the time of the first stop (when the push order is incorrect) when the small winning combination B1 is won. In this case, at this point, the small winning combination 10 or 18 can be won.
Next, when stopping the left reel 31, priority is given to stopping the symbol "bell B" or "red 7" related to the small winning combination 10 or 18 at the effective line. As shown in FIG. 5, in the left reel 31, "Bell B" is arranged at Nos. 5 and 10, and "Red 7" is arranged at Nos. 7. Therefore, when the design of the left reel 31 at the moment when the stop switch 42 is operated is No. 1 to No. 10, "Bell B" or "Red 7" can be stopped at the effective line, and other than that. At some times, "Bell B" or "Red 7" cannot be stopped at the effective line.

Therefore, when the left reel 31 is stopped randomly (without aiming at a specific symbol), "Bell B" or "Red 7" is stopped at the effective line with a probability of "1/2". In particular, in the present embodiment, since "Bell B" can be stopped without stopping "Red 7", when the design of the left reel 31 at the moment when the stop switch 42 is operated is No. 1 to No. 10. Always stops "Bell B" on the effective line.

On the other hand, when the "bell B" cannot be stopped at the effective line when the left reel 31 is stopped, control is performed so that one of the pattern symbols is stopped at the effective line. As shown in FIG. 12, the pattern symbol in which the symbol of the middle reel 31 is "bell B" is "black 7" or "watermelon". Since the "black 7" or "watermelon" of the left reel 31 is "PB = 1" in the sum of the two symbols, any one of these symbols can always be stopped.

Therefore, at the time of the middle first stop and the left second stop, it becomes "bell B"-"bell B"-"rotating", or "black 7 / watermelon"-"bell B"-"rotating". ..
Further, when "Bell B"-"Bell B"-"Rotating" is set before the third stop on the right, "Bell B" can be stopped on the effective line when the right reel 31 is stopped. Stop "Bell B". As shown in FIG. 5, in order to stop "Bell B" at the effective line, the design of the effective line at the moment when the stop switch 42 is operated should be in the range of 14 to 18 or 19 to 3. For example, "Bell B" can be stopped, and "Bell B" cannot be stopped in other ranges. Therefore, when the right reel 31 is stopped at random, the "bell B" is stopped at the effective line with a probability of "1/2". When "Bell B" is stopped on the effective line when the right reel 31 is stopped, "Bell B"-"Bell B"-"Bell B" is obtained, and the small winning combination 10 is won.

On the other hand, in the case of "Bell B"-"Bell B"-"Rotating", if "Bell B" cannot be stopped on the effective line when the right reel 31 is stopped, "Cherry" is set as the effective line. Stop ("PB = 1"). As a result, the combination of symbols on the effective line becomes "bell B"-"bell B"-"cherry", and the pattern symbol 03 stops.
Further, in the case of "Black 7 / Watermelon"-"Bell B"-"Rotating", when the right reel 31 is stopped, "Bell A" or "Bell B" is stopped on the effective line ("PB = 1"). ). As a result, the combination of symbols on the effective line becomes "black 7 / watermelon"-"bell B"-"bell A / bell B", and the pattern symbol 01 is stopped.

From the above, at the time of the first stop at the time of winning the small winning combination B1, the middle reel 31 can stop the symbol related to the one-card combination at "PB = 1", and the left and right reels 31 are both "1". With a probability of "/ 2", the symbol related to the 1-card combination can be stopped. Further, when the symbol related to the single card combination cannot be stopped, the pattern symbol can be stopped at any time. Therefore, at the time of the first stop at the time of winning the small role B1 (when the push order is incorrect),
1-card combination: Winning with a probability of 1/4 Pattern pattern: Stops with a probability of 3/4.
Furthermore, when winning a single role,
"Bell A"-"Bell A"-"Bell A" (small role 03)
"Bell B"-"Bell B"-"Bell B" (small role 10)
Will be one of.

Next, the case where the small winning combination B1 is won and the right first stop is described will be described. When giving priority to the number when the right reel 31 is stopped, if either "Bell A" or "Bell B" is stopped at the effective line, the number of combinations of symbols that can be stopped at the effective line is two each. Becomes the maximum. For example, if "Bell A" is stopped at the effective line when the right reel 31 is stopped, the small winning combination 03 or 19 can be won. Since the "bell A" or "bell B" of the right reel 31 is "PB = 1" in the sum of the two symbols, the "bell A" or "bell B" can always be stopped when the right reel 31 is stopped. can.
First, it is assumed that "Bell A" is stopped on the effective line when the right reel 31 is stopped. In this case, at this point, the small winning combination 03 or 19 can be won.

Next, when stopping the left reel 31, priority is given to stopping the symbol "bell A" or "bell C" related to the small winning combination 03 or 19 at the effective line. Here, as in the above, priority is given to stopping "Bell A". "Bell A" can be stopped with a probability of "1/2". If "Bell A" cannot be stopped, "Black 7" or "Watermelon" is stopped ("PB = 1" in total of 2 symbols).

Therefore, at the time of the first right stop and the second left stop, it is either "Bell A"-"Rotating"-"Bell A", or "Black 7 / Watermelon"-"Rotating"-"Bell A". ..
Further, in the case of "Bell A"-"Rotating"-"Bell A" before the middle third stop, when "Bell A" can be stopped on the effective line when the middle reel 31 is stopped, "Bell A" is " Stop "Bell A". As shown in FIG. 5, in order to stop "Bell A" at the effective line, "Bell A" is stopped if the design of the effective line at the moment when the stop switch 42 is operated is in the range of 5 to 14. It can be made to stop, and "Bell A" cannot be stopped in other ranges. Therefore, when the middle reel 31 is stopped at random, the "bell A" is stopped at the effective line with a probability of "1/2". When "Bell A" is stopped on the effective line when the middle reel 31 is stopped, it becomes "Bell A"-"Bell A"-"Bell A", and the small winning combination 03 is won.

On the other hand, in the case of "Bell A"-"Rotating"-"Bell A", if "Bell A" cannot be stopped on the effective line when the middle reel 31 is stopped, "Blue 7" or "Cherry" Is stopped at the effective line (“PB = 1” in the sum of the two symbols). As a result, the pattern symbol 02 stops at the effective line.
Further, in the case of "black 7 / watermelon"-"rotating"-"bell A", when the middle reel 31 is stopped, "bell A" or "bell B" is stopped on the effective line ("PB = 1"). ). As a result, the pattern symbol 01 stops at the effective line.

Further, it is assumed that "Bell B" is stopped at the effective line at the first stop of the right reel 31. In this case, at this point, the small winning combination 10 or 26 can be won.
Next, when stopping the left reel 31, priority is given to stopping the symbol "bell B" or "red 7" related to the small winning combination 10 or 26 at the effective line. Here, priority is given to stopping "Bell B". "Bell B" can be stopped with a probability of "1/2". If "Bell B" cannot be stopped, "Black 7" or "Watermelon" is stopped ("PB = 1" in total of 2 symbols).

Therefore, at the time of the first right stop and the second left stop, it is either "Bell B"-"Rotating"-"Bell B", or "Black 7 / Watermelon"-"Rotating"-"Bell B". ..
Further, in the case where "Bell B"-"Rotating"-"Bell B" is set before the middle third stop, when "Bell B" can be stopped on the effective line when the middle reel 31 is stopped, "Bell B" can be stopped. Stop "Bell B". Here, when the middle reel 31 is stopped at random, the "bell B" is stopped at the effective line with a probability of "1/2". When "Bell B" is stopped on the effective line when the middle reel 31 is stopped, "Bell B"-"Bell B"-"Bell B" is obtained, and the small winning combination 10 is won.

On the other hand, in the case of "Bell B"-"Rotating"-"Bell B", if "Bell B" cannot be stopped on the effective line when the middle reel 31 is stopped, "Blue 7" or "Cherry" Is stopped at the effective line (“PB = 1” in the sum of the two symbols). As a result, the pattern symbol 02 stops at the effective line.
Further, in the case of "black 7 / watermelon"-"rotating"-"bell B", when the middle reel 31 is stopped, "bell A" or "bell B" is stopped on the effective line ("PB = 1"). ). As a result, the pattern symbol 01 stops at the effective line.

From the above, at the time of the first right stop when the small winning combination B1 is won, the right reel 31 can stop the symbol related to the one-card combination at "PB = 1", and both the left and right reels 31 have "1". With a probability of "/ 2", the symbol related to the 1-card combination can be stopped. Further, when the symbol related to the single card combination cannot be stopped, the pattern symbol can be stopped at any time. Therefore, at the time of the first stop on the right when the small role B1 is won (when the push order is incorrect),
1-card combination: Winning with a probability of 1/4 Pattern pattern: Stops with a probability of 3/4.
Furthermore, when winning a single role,
"Bell A"-"Bell A"-"Bell A" (small role 03)
"Bell B"-"Bell B"-"Bell B" (small role 10)
Will be one of.
The winning rate and the stop rate of the pattern symbol are the same as those at the time of the first stop.
Therefore, when the small winning combination B1 is won, when the left first stop (when the push order is correct), the small winning combination 01 wins with "PB = 1". On the other hand, at the time of the first stop in the middle or the right (when the push order is incorrect), one card wins with a probability of "1/4", and the pattern symbol stops with a probability of "3/4". ..

When the small winning combination B2 is won, the small winning combination B2 table is provided as in the case where the small winning combination B1 is won. The winning roles included when the small role B2 is won are
Small role 01: "Black 7 / Watermelon"-"Bell C"-"Replay" (9 sheets)
Small role 04: "Bell A"-"Bell A"-"Bell B" (1 sheet)
Small role 09: "Bell B"-"Bell B"-"Bell A" (1 sheet)
Small role 12: "Bell C"-"Bell A"-"Red 7" (1 sheet)
Small role 17: "Red 7"-"Bell B"-"Blue 7" (1 sheet)
Small role 20: "Bell C"-"Blue 7"-"Bell B" (1 sheet)
Small role 25: "Red 7"-"Red 7"-"Bell A" (1 sheet)
Is.

Then, at the time of the first left stop (when the push order is correct), the small winning combination 01 is awarded.
Next, at the time of the first middle stop (when the push order is incorrect), "Bell A" or "Bell B" is stopped at the effective line by giving priority to the number.
First, when "Bell A" is stopped at the first middle stop, priority is given to stopping either "Bell A" or "Bell C" at the time of left stop. Here, when the "bell C" can be stopped, the "bell A" can be stopped, so the "bell A" is stopped without stopping the "bell C". If "Bell A" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell A"-"Bell A"-"Rotating" or "Black 7 / Watermelon"-"Bell A"-"Rotating".

When "Bell A"-"Bell A"-"Rotating", "Bell B" is stopped when the right stop is possible. As a result, the small role 04 is won. If "Bell B" cannot be stopped when stopped to the right, "Cherry" is stopped. As a result, the pattern symbol 03 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Bell A"-"Rotating" is set, "Bell A" or "Bell B" is stopped when the vehicle is stopped to the right. As a result, the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped at the time of the first middle stop. In this case, when stopping to the left, priority is given to stopping either "Bell B" or "Red 7". Here, since "Bell B" can be stopped when "Red 7" can be stopped, "Bell B" is stopped without stopping "Red 7". If "Bell B" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell B"-"Bell B"-"Rotating" or "Black 7 / Watermelon"-"Bell B"-"Rotating".

When "Bell B"-"Bell B"-"Rotating", "Bell A" is stopped when it is stopped to the right, and "Bell A" is stopped when it is possible to stop. As a result, a small role 09 is won. If "Bell A" cannot be stopped when stopping to the right, "Cherry" is stopped. As a result, the pattern symbol 03 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Bell B"-"Rotating" is set, "Bell A" or "Bell B" is stopped when the vehicle is stopped to the right. As a result, the pattern symbol 01 is stopped.

Next, at the time of the first right stop when the small winning combination B2 is won (when the push order is incorrect), "Bell A" or "Bell B" is stopped at the effective line by giving priority to the number.
First, when "Bell A" is stopped at the first right stop, priority is given to stopping either "Bell B" or "Red 7" at the time of left stop. Here, since "Bell B" can be stopped when "Red 7" can be stopped, "Bell B" is stopped without stopping "Red 7". If "Bell B" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell B"-"Rotating"-"Bell A" or "Black 7 / Watermelon"-"Rotating"-"Bell A".

When "Bell B"-"Rotating"-"Bell A", "Bell B" is stopped when "Bell B" can be stopped at the middle stop. As a result, a small role 09 is won. If "Bell B" cannot be stopped during the middle stop, "Blue 7 / Cherry" is stopped. As a result, the pattern symbol 02 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Rotating"-"Bell A" is reached, "Bell A" or "Bell B" is stopped at the time of middle stop. As a result, the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped at the first right stop. In this case, when stopping to the left, priority is given to stopping either "Bell A" or "Bell C". Here, when the "bell C" can be stopped, the "bell A" can be stopped, so the "bell A" is stopped without stopping the "bell C". If "Bell A" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell A"-"Rotating"-"Bell B" or "Black 7 / Watermelon"-"Rotating"-"Bell B".

When "Bell A"-"Rotating"-"Bell B", "Bell A" is stopped when "Bell A" can be stopped at the middle stop. As a result, the small role 04 is won. If "Bell A" cannot be stopped during the middle stop, "Blue 7 / Cherry" is stopped. As a result, the pattern symbol 02 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Rotating"-"Bell B", "Bell A" or "Bell B" is stopped at the middle stop. As a result, the pattern symbol 01 is stopped.

From the above, when the small role B2 is won, when the push order is incorrect,
1-card combination: Winning with a probability of 1/4 Pattern pattern: Stops with a probability of 3/4.
Furthermore, when winning a single role,
"Bell A"-"Bell A"-"Bell B" (small role 04)
"Bell B"-"Bell B"-"Bell A" (small role 09)
Will be one of.

When the small winning combination B3 is won, the small winning combination B3 table is provided as in the case where the small winning combination B1 is won. The winning roles included when the small role B3 is won are
Small role 01: "Black 7 / Watermelon"-"Bell C"-"Replay" (9 sheets)
Small role 05: "Bell A"-"Bell B"-"Bell A" (1 sheet)
Small role 08: "Bell B"-"Bell A"-"Bell B" (1 sheet)
Small role 13: "Bell C"-"Bell B"-"Blue 7" (1 sheet)
Small role 16: "Red 7"-"Bell A"-"Red 7" (1 sheet)
Small role 21: "Bell C"-"Red 7"-"Bell A" (1 sheet)
Small role 24: "Red 7"-"Blue 7"-"Bell B" (1 sheet)
Is.

Then, at the time of the first left stop (when the push order is correct), the small winning combination 01 is awarded.
Next, at the time of the first middle stop (when the push order is incorrect), "Bell A" or "Bell B" is stopped at the effective line by giving priority to the number.
First, when "Bell A" is stopped at the first middle stop, priority is given to stopping either "Bell B" or "Red 7" at the time of left stop. Here, in the same manner as above, "Bell B" is stopped without stopping "Red 7". If "Bell B" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell B"-"Bell A"-"Rotating" or "Black 7 / Watermelon"-"Bell A"-"Rotating".

When "Bell B"-"Bell A"-"Rotating", "Bell B" is stopped when "Bell B" can be stopped when stopped to the right. As a result, a small role 08 will be won. If "Bell B" cannot be stopped when stopped to the right, "Cherry" is stopped. As a result, the pattern symbol 03 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Bell A"-"Rotating" is set, "Bell A" or "Bell B" is stopped when the vehicle is stopped to the right. As a result, the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped at the time of the first middle stop. In this case, when stopping to the left, priority is given to stopping either "Bell A" or "Bell C". Here, in the same manner as described above, "Bell A" is stopped without stopping "Bell C". If "Bell A" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell A"-"Bell B"-"Rotating" or "Black 7 / Watermelon"-"Bell B"-"Rotating".

When "Bell A"-"Bell B"-"Rotating", "Bell A" is stopped when it is possible to stop "Bell A" when it is stopped to the right. As a result, the small role 05 will be awarded. If "Bell A" cannot be stopped when stopping to the right, "Cherry" is stopped. As a result, the pattern symbol 03 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Bell B"-"Rotating" is set, "Bell A" or "Bell B" is stopped when the vehicle is stopped to the right. As a result, the pattern symbol 01 is stopped.

Next, at the time of the first right stop when the small winning combination B2 is won (when the push order is incorrect), "Bell A" or "Bell B" is stopped at the effective line by giving priority to the number.
First, when "Bell A" is stopped at the first right stop, priority is given to stopping either "Bell A" or "Bell C" at the time of left stop. Here, the "bell A" is stopped in the same manner as described above. If "Bell A" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell A"-"Rotating"-"Bell A" or "Black 7 / Watermelon"-"Rotating"-"Bell A".

When "Bell A"-"Rotating"-"Bell A", "Bell B" is stopped when "Bell B" can be stopped at the middle stop. As a result, the small role 05 will be awarded. If "Bell B" cannot be stopped during the middle stop, "Blue 7 / Cherry" is stopped. As a result, the pattern symbol 02 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Rotating"-"Bell A" is reached, "Bell A" or "Bell B" is stopped at the time of middle stop. As a result, the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped at the first right stop. In this case, when stopping to the left, priority is given to stopping either "Bell B" or "Red 7". Here, the "bell B" is stopped in the same manner as described above. If "Bell B" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell B"-"Rotating"-"Bell B" or "Black 7 / Watermelon"-"Rotating"-"Bell B".

When "Bell B"-"Rotating"-"Bell B", "Bell A" is stopped when "Bell A" can be stopped at the middle stop. As a result, a small role 08 will be won. If "Bell B" cannot be stopped during the middle stop, "Blue 7 / Cherry" is stopped. As a result, the pattern symbol 02 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Rotating"-"Bell B", "Bell A" or "Bell B" is stopped at the middle stop. As a result, the pattern symbol 01 is stopped.

From the above, when the small role B3 is won, when the push order is incorrect,
1-card combination: Winning with a probability of 1/4 Pattern pattern: Stops with a probability of 3/4.
Furthermore, when winning a single role,
"Bell A"-"Bell B"-"Bell A" (small role 05)
"Bell B"-"Bell A"-"Bell B" (small role 08)
Will be one of.

When the small winning combination B4 is won, the small winning combination B4 table is provided as in the case where the small winning combination B1 is won. The winning roles included when the small role B4 is won are
Small role 01: "Black 7 / Watermelon"-"Bell C"-"Replay" (9 sheets)
Small role 06: "Bell A"-"Bell B"-"Bell B" (1 sheet)
Small role 07: "Bell B"-"Bell A"-"Bell A" (1 sheet)
Small role 14: "Bell C"-"Bell B"-"Red 7" (1 sheet)
Small role 15: "Red 7"-"Bell A"-"Blue 7" (1 sheet)
Small role 22: "Bell C"-"Red 7"-"Bell B" (1 sheet)
Small role 23: "Red 7"-"Blue 7"-"Bell A" (1 sheet)
Is.

Then, at the time of the first left stop (when the push order is correct), the small winning combination 01 is awarded.
Next, at the time of the first middle stop (when the push order is incorrect), "Bell A" or "Bell B" is stopped at the effective line by giving priority to the number.
First, when "Bell A" is stopped at the middle first stop, priority is given to stopping either "Bell B" or "Red 7" at the time of left stop, but here, the same as above. Stop "Bell B". If "Bell B" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell B"-"Bell A"-"Rotating" or "Black 7 / Watermelon"-"Bell A"-"Rotating".

When "Bell B"-"Bell A"-"Rotating", "Bell A" is stopped when it is possible to stop "Bell A" when it is stopped to the right. As a result, a small role 07 will be won. If "Bell B" cannot be stopped when stopped to the right, "Cherry" is stopped. As a result, the pattern symbol 03 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Bell A"-"Rotating" is set, "Bell A" or "Bell B" is stopped when the vehicle is stopped to the right. As a result, the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped at the time of the first middle stop. In this case, when stopping to the left, priority is given to stopping either "Bell A" or "Bell C". Here, the "bell A" is stopped in the same manner as described above. If "Bell A" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell A"-"Bell B"-"Rotating" or "Black 7 / Watermelon"-"Bell B"-"Rotating".

When "Bell A"-"Bell B"-"Rotating", "Bell B" is stopped when "Bell B" can be stopped when stopped to the right. As a result, the small role 06 will be won. If "Bell B" cannot be stopped when stopped to the right, "Cherry" is stopped. As a result, the pattern symbol 03 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Bell B"-"Rotating" is set, "Bell A" or "Bell B" is stopped when the vehicle is stopped to the right. As a result, the pattern symbol 01 is stopped.

Next, at the time of the first right stop when the small winning combination B4 is won (when the push order is incorrect), "Bell A" or "Bell B" is stopped at the effective line by giving priority to the number.
First, when "Bell A" is stopped at the first right stop, priority is given to stopping either "Bell B" or "Red 7" at the time of left stop. Here, the "bell B" is stopped in the same manner as described above. If "Bell B" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell B"-"Rotating"-"Bell A" or "Black 7 / Watermelon"-"Rotating"-"Bell A".

When "Bell B"-"Rotating"-"Bell A", "Bell A" is stopped when "Bell A" can be stopped at the middle stop. As a result, a small role 07 will be won. If "Bell A" cannot be stopped during the middle stop, "Blue 7 / Cherry" is stopped. As a result, the pattern symbol 02 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Rotating"-"Bell A" is reached, "Bell A" or "Bell B" is stopped at the time of middle stop. As a result, the pattern symbol 01 is stopped.

Next, it is assumed that "Bell B" is stopped at the first right stop. In this case, when stopping to the left, priority is given to stopping either "Bell A" or "Bell C". Here, the "bell A" is stopped in the same manner as described above. If "Bell A" cannot be stopped, "Black 7 / Watermelon" is stopped. Therefore, it is either "Bell A"-"Rotating"-"Bell B" or "Black 7 / Watermelon"-"Rotating"-"Bell B".

When "Bell A"-"Rotating"-"Bell B", "Bell B" is stopped when "Bell B" can be stopped at the middle stop. As a result, the small role 06 will be won. If "Bell B" cannot be stopped during the middle stop, "Blue 7 / Cherry" is stopped. As a result, the pattern symbol 02 is stopped.
On the other hand, when "Black 7 / Watermelon"-"Rotating"-"Bell B", "Bell A" or "Bell B" is stopped at the middle stop. As a result, the pattern symbol 01 is stopped.

From the above, when the small role B4 is won, when the push order is incorrect,
1-card combination: Winning with a probability of 1/4 Pattern pattern: Stops with a probability of 3/4.
Furthermore, when winning a single role,
"Bell A"-"Bell B"-"Bell B" (small role 06)
"Bell B"-"Bell A"-"Bell A" (small role 07)
Will be one of.

Hereinafter, detailed description of each of the small winning combination B5 table to the small winning combination B12 table at the time of winning the small winning combination B5 to B12 will be omitted, and only the outline thereof will be described.
In the small winning combination B5 table used when the small winning combination B5 is won, the small winning combination 01 wins at the middle first stop, which is the correct answer in the pushing order, and the small winning combination 03 or the small winning combination has a probability of "1/4" when the pushing order is incorrect. The winning combination 10 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B1 is won.
Further, in the small winning combination B6 table used when the small winning combination B6 is won, the small winning combination 01 wins at the first stop in the middle when the pushing order is correct, and the small winning combination 04 has a probability of "1/4" when the pushing order is incorrect. Alternatively, the small winning combination 09 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B2 is won.

Furthermore, in the small winning combination B7 table used when the small winning combination B7 is won, the small winning combination 01 wins at the first stop in the middle when the push order is correct, and there is a probability of "1/4" when the push order is incorrect. 05 or small winning combination 08 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B3 is won.
Furthermore, in the small winning combination B8 table used when the small winning combination B8 is won, the small winning combination 01 wins at the first stop in the middle when the push order is correct, and when the push order is incorrect, there is a probability of "1/4" for the small win 06. Alternatively, the small winning combination 07 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B4 is won.

In the small winning combination B9 table used when the small winning combination B9 is won, the small winning combination 01 wins when the right first stop is the correct answer in the pushing order, and the small winning combination 03 or small winning combination has a probability of "1/4" when the pushing order is incorrect. The winning combination 10 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B1 is won.
Further, in the small winning combination B10 table used when the small winning combination B10 is won, the small winning combination 01 wins at the first right stop when the pushing order is correct, and the small winning combination 04 has a probability of "1/4" when the pushing order is incorrect. Alternatively, the small winning combination 09 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B2 is won.

Furthermore, in the small winning combination B11 table used when the small winning combination B11 is won, the small winning combination 01 wins when the right first stop is when the push order is correct, and when the push order is incorrect, there is a probability of "1/4" for the small win. 05 or small winning combination 08 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B3 is won.
Furthermore, in the small winning combination B12 table used when the small winning combination B12 is won, the small winning combination 01 wins when the right first stop is when the push order is correct, and when the push order is incorrect, there is a probability of "1/4" for the small win 06. Alternatively, the small winning combination 07 wins, and the pattern symbol stops with a probability of "3/4". That is, the small winning combination that can be won when the push order is incorrect is the same as when the small winning combination B4 is won.

As is clear from the above, the one-card winning combination that can be won when the push order is incorrect at the time of winning the small winning combination B group is the small winning combination 03 to the small winning combination 10. Therefore, small wins other than the above included in each condition device will not win a prize. The setting in this way is related to the one-card combination that can be won when the small combination C group, which will be described later, is won.

The small winning combination C1 table is used in the game when the small winning combination C1 is won, and within the range of the stop control of the reel 31, when the left first stop (when the push order is correct), the small winning combination 02 is stopped at the effective line and left. Except for the first stop (when the push order is incorrect), the one-card combination included in the winning combination (when the small combination C1 is won, any of the small combination 03 to 10) is stopped at the effective line. The stop position of the reel 31 is defined.

When the small winning combination C1 (same for the small winning combination C2 and C3 described later) is won, when the push order is correct, the small winning combination 02 (three-card combination) is awarded by giving priority to the number of sheets, as in the case of winning the small winning combination B group. Control. As shown in FIG. 7, the combination of symbols corresponding to the small winning combination 02 is "bell A / bell B"-"blue 7 / cherry"-"watermelon", and "PB = 1" on all reels 31. .. Therefore, when the push order is correct, the small winning combination 02 can always be won.

Further, when the small winning combination C1 is won, when the pushing order is incorrect (at the time of the first stop in the middle or the right), the number of winning winning combination (small winning combination 03 to 10) is controlled by giving priority to the number of pieces. Here, as shown in FIG. 8, the combination of the symbols of the small combinations 03 to 10 is a combination of the symbols of "bell A" or "bell B" for each reel 31. Further, among the combinations of the symbols of the small winning combinations 03 to 10, there are four "bell A" and four "bell B" in each reel 31, and either "bell A" or "bell B" can be used. Even if it is stopped, the condition of quantity priority is satisfied. In particular, when the small winning combination C2 and the small winning combination C3 are won, the small winning combination 21 and the small winning combination 22 are included, respectively. Further, in all reels 31, "bell A" or "bell B" is "PB = 1" in total of the two symbols. Therefore, any one of the small winning combinations 03 to 10 can always be won.

From the above, when the small winning combination C1 is won, the small winning combination 02 (3 cards) wins when the pushing order is correct (“PB = 1”), and when the pushing order is incorrect, either small winning combination 03 to 10 (1). The card combination) wins (“PB = 1”), and there is no omission (stopping of the pattern pattern) as in the case of winning the small combination B group.

The small winning combination C2 table and the small winning combination C3 table used at the time of winning the small winning combination C2 and the small winning combination C3 are the same as those of the small winning combination C1 table. As shown in FIG. 16, when the small winning combination C2 is won, the middle first stop is the correct answer pushing order, and when the small winning combination C3 is won, the right first stop is the correct answer pushing order. Since the stop control for winning the small winning combination 02 or the small winning combination 03 to 10 is the same as when the small winning combination C1 is won, the explanation is omitted.

Therefore, a 1-card combination (small combination 03 to 10) that can be stopped when the push order is incorrect when the small combination B group is won, and a 1-card combination (small combination 03 to 10) that can be stopped when the push order is incorrect when the small combination C group is won. Small roles 03 to 10) are the same. As a result, it is not possible to determine whether the small winning combination B group or the small winning combination C group has been won in the game just by looking at the winning of the small winning combination 03-10.

The small winning combination D table is used in the game when the small winning combination D is won, and the stop position of the reel 31 is determined so as to stop the small winning combination 35 on the effective line within the range of the stop control of the reel 31. In the small winning combination D table, the pressing order of the stop switch 42 does not matter. As shown in FIG. 9, the combination of the symbols of the small winning combination 35 is a set of "watermelons". The "watermelon" has a "PB ≠ 1" arrangement on the left and middle reels 31 and a "PB = 1" arrangement on the right reel 31. Therefore, in the game in which the small winning combination D table is used, in the left and middle reels 31, if the stop switch 42 is operated at the timing when the "watermelon" stops at the effective line, the "watermelon" stops at the effective line. When the stop switch 42 is operated at a timing when the "watermelon" does not stop at the effective line, the "watermelon" does not stop at the effective line and the small winning combination 35 is missed.

The small winning combination E1 table is used in the game when the small winning combination E1 is won, and the stop position of the reel 31 is determined so as to stop the small winning combination 36 or 38 on the effective line within the range of the stop control of the reel 31. Is. Here, as shown in FIG. 16, when the stop switch 42 is operated at the left or middle first stop, it becomes a so-called middle-stage cherry stop type (so that the "cherry" stops at the left middle stage). The stop position of the reel 31 is determined. On the other hand, when the stop switch 42 is operated at the first right stop, the stop position of the reel 31 is determined so that the middle cherry does not stop.

It should be noted that the winning of the small winning combination E1 includes the small winning combination 36 and 38 (furthermore, the small winning combination 37 is included when the small winning combination E2 is won, which will be described later). The number / number priority is not applied, and the reel 31 can be stopped by an arbitrary stop control determined in advance. Therefore, it is controlled to give priority to the winning of the small winning combination 36 at the time of the left or middle first stop, and to give priority to the winning of the small winning combination 38 at the time of the first right stop.

In FIG. 5, the “cherries” on the left reel 31 are Nos. 3, 8, and 13 (“PB ≠ 1”). Then, when "cherry" is stopped in the middle left row, "blank" or "red 7" is stopped in the effective line in the lower left row. Therefore, in this case, the symbol related to the small winning combination 36 is stopped for the left reel 31.

For example, when the 7th "Red 7" is stopped in the lower left row at the first left stop ("Cherry" is stopped in the middle left row), "Blue 7" or "Cherry" is valid when the middle reel 31 is stopped. Stop at the line ("PB = 1"), and when the right reel 31 is stopped, either "Black 7", "Blue 7", "Red 7", or "Blank" (4 symbols combined, "PB =" 1 ”) is stopped at the effective line. As a result, the small role 36 is won.
Further, when the 2nd or 12th "blank" is stopped in the lower left stage when the left reel 31 is stopped ("cherry" is stopped in the middle left stage), the same as above, when the middle reel 31 is stopped, "" Stop "Blue 7" or "Cherry" at the effective line, and when the right reel 31 is stopped, stop either "Black 7", "Blue 7", "Red 7", or "Blank" at the effective line. .. As a result, the small role 36 is won.

Stop control is also performed at the time of the first middle stop in the same manner as described above. Therefore, the middle and right reels 31 have a case where the symbol related to the small winning combination 36 stops at "PB = 1", and the left reel 31 has a case where "red 7" or "blank" stops and a case where it does not stop (for the left reel 31). "PB ≠ 1").
However, if "Red 7" or "Blank" cannot be stopped in the lower left row at the time of the first stop on the left or middle, "Bell A" or "Bell B" is stopped. "Bell A" or "Bell B" can be stopped at "PB = 1". In this case, the stop type is "Bell A / Bell B"-"Blue 7 / Cherry"-"Black 7 / Blue 7 / Red 7 / Blank", and the small winning combination 38 wins.

On the other hand, in the game in which the small winning combination E1 table is used, the winning of the small winning combination 38 is prioritized at the time of the first right stop. Therefore, in this case, "Bell A / Bell B"-"Blue 7 / Cherry"-"Black 7 / Blue 7 / Red 7 / Blank" stops, and the small winning combination 38 wins with "PB = 1". ..
Further, at the time of the first right stop, even if the "cherry" can be stopped at the left middle stage when the left reel 31 is stopped, the "cherry" is not stopped at the left middle stage, and the "bell A" or "bell" at the lower left stage. Stop "B" (in this case, "cherry" is not stopped in the middle left).

The small winning combination E2 table is used in the game when the small winning combination E1 is won, and the reel 31 is used so as to stop the small winning combination 36 or 38 (or the small winning combination 37) on the effective line within the range of the stop control of the reel 31. It defines the stop position of.
Therefore, since the small combination E2 table can perform the same stop control as the small combination E1 table, it is possible to use the same stop position determination table.

Alternatively, in the case of the first left stop, only when "Red 7" or "Blank" can be stopped in the lower left row (when the middle row cherry is stopped), "Replay" is set to the effective line for the middle reel 31. It may be stopped (“PB = 1”), and any one of “black 7”, “blue 7”, “red 7”, or “blank” may be stopped for the right reel 31. As a result, the small role 37 wins a prize. If the stop control is performed in this way, it is possible to determine whether the small winning combination E1 is won or the small winning combination E2 is won when the middle cherry is stopped.

The small winning combination F table is used in the game when the small winning combination F is won, and the stop position of the reel 31 is set so as to stop any of the small winning combination 01 to 39 on the effective line within the range of the stop control of the reel 31. It is a fixed one.
In the present embodiment, the small winning combination F is drawn only during 1BB operation.
Further, the small winning combination F table performs stop control by giving priority to the number of sheets regardless of the pressing order of the stop switch 42. As a result, the small role 39 is always won. In addition, in the left reel 31, since the arrangement of "PB = 1" is the sum of the two symbols of "cherry" or "bell C", the small winning combination 39 wins with "PB = 1".

The small winning combination G table is used in the game when the small winning combination G is won, and the stop position of the reel 31 is determined so as to stop the small winning combination 40 on the effective line within the range of the stop control of the reel 31. .. Since the small winning combination 40 is composed of a combination of symbols arranged with "PB = 1" for all reels 31, the small winning combination 40 can always be won in the game.

The 1BBA table is used when the game when the accessory condition device number "1" is won (1BBA alone is won), or when the 1BBA is won before the previous game and is not won in the game this time, and the stop control of the reel 31 is used. Within the range of, the combination of symbols corresponding to 1BBA is stopped at the effective line, and the combination of symbols corresponding to the combinations other than 1BBA is determined so as not to stop at the effective line. It is a thing.
Since the symbol of 1BBA is "Red 7" on all reels 31 (PB ≠ 1), "Red 7" cannot be stopped at the effective line unless it is pressed.

Similarly, the 1BBB table is used when the game is won when the accessory condition device number "2" is won (1BBB is won alone), or when the 1BBB is won before the previous game and is not won in the game this time, and the reel 31 is used. Within the range of the stop control of, the combination of symbols corresponding to 1BBB is stopped at the effective line, and the combination of symbols corresponding to the combinations other than 1BBB is not stopped at the effective line. The combination is defined.
Since the symbol of 1BBB is "PB ≠ 1" for all reels 31 as in 1BBA, "red 7" and "black 7" cannot be stopped at the effective line unless the eyes are pressed.

Although detailed explanation is omitted, in a game in which 1BB and a small role or replay are duplicated, or in a game in which 1BB is won before the previous game and the small role or replay is won in this game, the following stop control is performed. Can be mentioned.

For example, first, priority is given to stopping both the winning 1BB and the small winning combination or replay symbol on the effective line, and when both symbols cannot be stopped on the effective line, the winning small symbol. A stop control that gives priority to stopping the combination or replay symbol on the effective line can be mentioned. The stop control for stopping both the 1BB and the small win or replay symbol on the effective line is up to the second stop, and at the time of the third stop, 1BB or the small win or replay is controlled to win a prize, and a plurality of stops are controlled. The role of is not duplicated.
Secondly, priority is given to stopping both the winning 1BB and the small winning combination or replay symbol on the effective line, and when both symbols cannot be stopped on the effective line, the winning 1BB There is a stop control (opposite to the above) that gives priority to stopping the symbol of.

Thirdly, although priority is given to stopping the winning small winning combination or replay symbol on the effective line, when stopping the winning small winning combination or replay symbol on the effective line, When the winning 1BB symbol can be stopped at the effective line at the same time, stop control for stopping at that position can be mentioned.

When 1BB (“PB ≠ 1”) and the small winning combination or replay of “PB = 1” are won in duplicate (when they are winning at the same time), the winning 1BB symbol and the small winning combination or replay It is not necessary to control to stop both the symbol and the symbol on the effective line, and it is also possible to control so that only the small winning combination of "PB = 1" or the symbol of the replay is stopped on the effective line. Therefore, since the small winning combination E1 and E2 are "PB = 1", only the small winning combination E1 or E2 is obtained when the 1BBA and the small winning combination E1 of the present embodiment are duplicated or when the 1BBB and the small winning combination E2 are duplicated. It is also possible to execute stop control to win a prize.

The explanation is returned to FIG.
When the reel 31 is stopped, the winning determination means 66 determines whether or not the combination of the symbols of the reel 31 stopped on the effective line matches the combination of the symbols corresponding to any combination (whether any combination has won a prize). Whether or not) is judged. The winning determination means 66 determines a symbol on the effective line by detecting, for example, the angle at which the motor 32 is stopped, the number of steps, and the like.

When the winning determination means 66 determines that the combination of symbols stopped on the effective line when the reel 31 is stopped matches the combination of symbols corresponding to any of the winning combinations, the payout means 67 wins the winning combination. , A predetermined number of medals are paid out to the player according to the winning combination, or processing such as addition of credits is performed. In addition, when the replay wins a prize, the number of medals inserted in the game this time is controlled to be automatically inserted without paying out the medals.

The RT control means 68 determines whether or not the RT transition condition is satisfied at each game and when all reels 31 are stopped, and if it is determined that the RT transition condition is satisfied, the RT control means 68 controls to perform the RT transition. It is a thing.
FIG. 22 is a diagram showing an RT transition diagram in the present embodiment. As described above, the RT of the present embodiment includes non-RT, RT1 to RT4, 1BBA operation (1BBA game), and 1BBB operation (1BBB game). Then, as shown in FIGS. 17 and 18, the type (number) of the condition devices to be drawn and the winning probability thereof are different for each RT.

In the present embodiment, the RT transition timing is set at the time of stop display of the symbol combination or at the time of winning the RT transition combination, that is, at the time of all stops (when all reels 31 are stopped). Therefore, for example, when the pattern symbol is stopped when all reels 31 are stopped during RT1, RT shifts from RT1 to RT2 when all reels are stopped. The transition from non-RT, RT1 to RT3 to RT4 may be performed based on the winning of 1BB, or based on the fact that 1BB did not win in the game of winning 1BB. May be good. In the present embodiment, the game shifts to RT4 based on the fact that 1BB did not win in the game in which 1BB was won.

Non-internal medium games correspond to non-RT, RT1, RT2, RT3. In addition, the internal medium game corresponds to RT4.
Further, during the advantageous section, the slot machine 10 is basically controlled to stay at RT3, but when a player makes a mistake in pressing the stop switch 42, he / she may stay at RT2. be. In the case of an advantageous section that ends with only one instruction function operating game (excluding the game in which the small winning combination C group, the replay B group, and the replay C group are won), it is not necessary to stay at RT3. That is, in RT2, one instruction function operation game (excluding the game in which the small winning combination C group, the replay B group, and the replay C group are won) may be performed to end the advantageous section. Of course, you may basically stay at RT3.

In the non-RT, RT1 to RT3 non-internal middle games, a lottery of the character condition device is performed. Then, when 1BB is won in these RTs and 1BB is not won, the RT control means 68 determines that the transition condition of RT is satisfied, and shifts to RT4 corresponding to the internal middle game.
Further, when 1BB is won in the game in which 1BB is won, the operation of 1BBA or 1BBB is started at the time when the game is completely stopped this time, so in this case, RT4 (internal middle game) is not passed.

RT4 will continue until the winning 1BB wins. When the RT control means 68 determines that 1BBA or 1BBB has won a prize in RT4, it determines that the transition condition of RT is satisfied, and shifts to 1BBA operation (1BBA game) or 1BBB operation (1BBB game), respectively.
When 1BBA is in operation, it is continued until the operation end condition of 1BBA is satisfied. In the present embodiment, the operation end condition of 1BBA is set so that the number of payouts exceeds 150.

The RT control means 68 determines whether or not more than 150 medals have been paid out during each game and 1BBA operation, and when it is determined that more than 150 medals have been paid out, the termination condition of the 1BBA operation It is determined that the condition is satisfied, and control is performed so that the game shifts to non-RT from the next game.

The same applies to 1BBB operation. If the transition is made during the operation of 1BBB, it is continued until the operation end condition of 1BBB is satisfied. In the present embodiment, the termination condition of the 1BBB operation is set to pay out more than 200 medals.
The RT control means 68 determines whether or not more than 200 medals have been paid out for each game, and if it determines that more than 200 medals have been paid out, it determines that the operation termination condition of 1BBB is satisfied. From the next game, it is controlled to shift to RT1.

Replay is not included in the count of 150 or 200 sheets during 1BB operation. As shown in FIG. 17, while 1BB is in operation, the replay D may be won, but the automatic bet at the time of winning the replay is not counted in the number of payouts. Therefore, the more the replay D is won, the more the number of games during 1BB operation increases. In particular, in the present embodiment, as shown in FIG. 17, the winning probability of the replay D during 1BBA operation is set to 10 times that during 1BBB operation, so that the expected value of the number of games during 1BBA operation is 1BBB operation. It will be more than the expected value of the number of games in.

During the operation of 1BBA and 1BBB, as described above, the RB is continuously operated. The RB ends when either the winning of two wins or the two games is satisfied, and after the end, the RB is operated again on condition that the end condition of the 1BB operation is not satisfied.
Further, as shown in FIG. 18, the winning probability of the small winning combination E2 during the operation of 1BBA is set higher in the setting 6 than in the setting 1. When the small winning combination E2 is won and the small winning combination 36 or 38 wins, the number of payouts is two. As a result, the number of games played in setting 6 is larger than that in setting 1 until the end condition (more than 150 cards) is reached during 1BBA operation. Therefore, during the operation of 1BBA in the advantageous section, the expected value of winning the replay D is higher in the setting 6 than in the setting 1, so that the probability that the advantageous section is added is higher. Details on this point will be described in the control of the advantageous section described later.

When the RWM53 is initialized, the game is started from a non-RT. However, the present invention is not limited to this, and RT may be maintained even when the RWM53 is initialized. Here, for example, when the RWM53 is initialized while the 1BB winning is carried over, the 1BB winning is also maintained (carried over).

In non-RT, the RT control means 68 continues non-RT until the pattern symbol is displayed. In the non-RT, the small winning combination B group is drawn, and if any of the small winning combination B groups is won and the winning small winning combination is missed, the pattern pattern is displayed. When the pattern symbol is displayed in the non-RT, the RT control means 68 determines that the RT transition condition is satisfied, and shifts to RT2 from the next game.
In RT1, as in the case of non-RT, RT1 is maintained until the pattern symbol is displayed. Then, when the pattern symbol is displayed in RT1, the process shifts to RT2.

RT2 is the RT with the highest stay rate in the normal section. In RT2, when the replay B group is won and the replay 02 wins, it is judged that the RT transition condition is satisfied, and the game shifts to RT3 from the next game.
On the other hand, in RT3, the pattern symbol is displayed or the replay C group is won and the replay 03 is continued until the prize is won. When the pattern symbol is displayed or the replay 03 wins in RT3, it is determined that the RT transition condition is satisfied, and the game shifts to RT2 from the next game.

As described above, in the normal section (and non-internal), most of them go back and forth between RT2 and RT3, but the probability of staying at RT2 is the highest. When 1BB is won in RT2 and RT3 (including non-RT and RT1), the transition to RT4 (internal) from the next game is as described above.

In addition, when it is decided to shift to the advantageous section during the normal section and the game decided to shift to the advantageous section is RT3, in order to maintain RT3, the instruction function at the time of winning the replay C group Is activated, and the correct answer pressing order for winning the replay 01 is displayed. This prevents the vehicle from falling to RT2. In addition, when the small winning combination B group is won, the correct answer pressing order for winning the small winning combination 01 is displayed by activating the instruction function. Similarly, when the small winning combination C group is won, the correct answer pressing order for winning the small winning combination 02 is displayed by activating the instruction function.

On the other hand, when the game decided to shift to the advantageous section is RT2, the correct answer is to activate the instruction function at the time of winning the replay B group while activating the instruction function as described above to win the replay 02. The push order is displayed and it is controlled to shift to RT3.
Further, when it is decided to shift to the advantageous section when it is non-RT or RT1, it shifts to the advantageous section even during non-RT or RT1, but the instruction function is displayed until the pattern symbol is displayed. In a game in which the operation is possible (for example, when the small winning combination B group is won), the instruction function is not activated and the pattern symbol is displayed. Then, when the pattern symbol is displayed in non-RT or RT1 and the pattern shifts to RT2, the instruction function is activated in the same manner as described above.

The advantageous section control means 69 is a means for executing transition from a normal section to an advantageous section (including a standby section), determination of whether or not to end the advantageous section, addition in the advantageous section, operation control of an instruction function, and the like. be.
First, the advantageous section control means 69 determines whether or not to shift to the advantageous section in the normal section and the non-internal middle game.
Further, the advantageous section control means 69 determines whether or not to add the number of games in the advantageous section in the advantageous section and the non-internal middle game.

Whether or not to shift to the advantageous section during the normal section is determined in the present embodiment, as shown in FIG. 17, when the specific condition device is won in the lottery by the winning combination lottery means 61, at the same time, the advantageous section is selected. Decide to migrate. Further, when deciding to shift to the advantageous section, it is limited to being in the non-internal section, and it is not decided to shift from the normal section to the advantageous section in the internal section.

Further, as described above, when the transition to the advantageous section is determined according to the winning combination lottery result (winning conditional device), the winning of the conditional device having a setting difference cannot be a condition.
Therefore, in the present embodiment, as shown in FIG. 17, there is a case where the normal section shifts to the advantageous section on condition that the condition device having a common setting is won.

As shown in FIG. 17, for example, when 1BBA is won alone, there are cases where it is decided to shift to an advantageous section and cases where it is not decided to shift. When a random number value included in the range of the number "20" is extracted from the number "30" assigned to the single winning of 1BBA, it is decided to shift to the advantageous section and the number "10". When the random number value included in the range of is extracted, it is decided not to shift to the advantageous interval. The same applies to the single winning of "1BBA + small winning combination D", "1BBA + small winning combination E1", and small winning combination E1.

Further, when the condition device shown in FIG. 17 is won during the advantageous section, the advantageous section is added in each case. In addition, when these condition devices are won, it is possible to perform an additional lottery instead of uniformly adding an advantageous section, or to draw a lottery as to whether or not to perform an additional lottery. However, in the present embodiment, in order to simplify the explanation, the advantageous sections are uniformly added.

When it is decided to shift to the advantageous section in the normal section, the advantageous section with a predetermined number of games may be set, or the number of games in the advantageous section may be determined by lottery or the like. Alternatively, instead of determining the end condition of the advantageous section by the number of games, the end conditions other than the number of games (for example, the number of payouts, the difference number, the number of winnings of the small winning combination B group, the number of times the instruction function is operated, etc.) may be set. good. In the present embodiment, when the condition device shown in FIG. 17 is won in the normal section, the section shifts to the advantageous section in which the end conditions are set as described below.
Specifically, for example, the following can be defined.
When 1BBA alone is won (number of places "20"): Initial value is counted after the end of 1BB game and shifts to the advantageous section of 100 games. Counting after the end of the game and shifting to the advantageous section of 250 games 1BBA + small winning combination E1 duplicate winning (number "20"): Initial value counts after the end of 1BB game and shifts to the advantageous section of 200 games Small When the combination D is won alone (number of placements "50"): Advantageous section of 150 games with an initial value Small role E1 When the single winning combination is won (number of placements "250"): Advantageous section of 100 games with an initial value, or one small combination Any of the advantageous sections ending by the operation of the instruction function at the time of winning the group B (which may be decided by lottery, or included in the range of the number "120" out of the number "250" When the random value is extracted, the initial value is set as an advantageous section of 100 games, and when the random value included in the range of the number "130" is extracted, the instruction function at the time of winning the small winning combination B once. It may be an advantageous section that ends with operation)

Since the winning probability of the small role D is lower than the winning probability of the small role E1, in order to give a premier feeling when the small role D is won, the number of games in the advantageous section when the small role D is won is set to a small number. It is set more than when the role E1 is won. The number of games in the advantageous section when the small winning combination E1 is won may be set to be larger than that when the small winning combination D is won.
Also, when the condition device shown in FIG. 17 is won during the advantageous section, for example, when 1BBA alone is won, the number of games played in the advantageous section is added by "30", and when the small winning combination E1 is won alone (number of positions "250"). ) Adds "50" to the number of games, and "20" is added to the number of games when the small winning combination E1 is won alone (number of places "750"), and so on.

Furthermore, as shown in FIG. 17, in the normal section, when the small winning combination E1 is won alone, it is decided to shift to the advantageous section with a probability of "1/4"("250" out of the total number of "1000"). do.
On the other hand, as shown in FIG. 18, the single winning probability of the small winning combination E2 is set higher in the setting 6 than in the setting 1.

Therefore, the higher the setting, the higher the appearance ratio of the middle cherry, but the probability that the middle cherry will be determined to shift to the advantageous section when the middle cherry appears is higher in the setting 1 than in the setting 6.
That is, although there is no setting difference in the probability of deciding to shift to the advantageous section, it is possible to give the player the impression that there is a setting difference.
Contrary to the present embodiment, the setting 1 may be higher than the setting 6 for the single winning probability of the small winning combination E2 in FIG.
In this way, the lower the setting, the higher the probability of appearance of the middle cherry, but the lower the probability of being determined to shift to the advantageous section when the middle cherry appears.
In addition, during the advantageous section, when the small winning combination E1 is won alone, the advantageous section is always added. On the other hand, when the small winning combination E2 alone is won in the advantageous section, the advantageous section is not added. Therefore, the higher the setting, the higher the appearance ratio of the middle cherry, but the probability that the advantageous section is added when the middle cherry appears is higher in the setting 1 than in the setting 6. Therefore, although there is no setting difference in the probability that the advantageous section is added, it is possible to give the player the impression that there is a setting difference.

Further, 1BBA is a special combination in which the number of winnings is common to the setting (excluding the case where 1BBA and the small combination D are duplicated), and 1BBB is a special combination having a setting difference in the number of winnings.
In this case, when the 1BBA common to the setting is won during the advantageous section and the 1BBA is in operation, the advantageous section can be added during the operation of the 1BBA. On the other hand, when 1BBB having a setting difference during the advantageous section is won and 1BBB is in operation, it is stipulated that the advantageous section cannot be added during the operation of 1BBB. It is stipulated that when 1BBA and small winning combination D, which have a setting difference in the advantageous section, are elected in duplicate and 1BBA is in operation, the advantageous section cannot be added during the operation of 1BBA.

On the other hand, when setting 1 and setting 6 are compared while 1BBA is operating, the winning probability of the small winning combination A is lower in the setting 6 than in the setting 1, and the winning probability of the small winning combination E2 is set in the setting 6. Higher than. Therefore, since the operation end condition of 1BBA is set to pay out more than 150 sheets, the number of games (expected value) during 1BBA operation is larger in setting 6 than in setting 1.
Therefore, for example, if it is set to add an advantageous section when replay D is won, the expected value of the number of times replay D is won during 1BBA operation is higher in setting 6 than in setting 1, so the higher the setting, the higher the expected value. It is possible to make it easier for advantageous sections to be added.

Further, during the operation of 1BBA, when the number of games reaches a predetermined number, the advantageous section may be added.
As described above, during 1BBA operation, the expected value of the number of games during 1BBA operation is higher in setting 6 than in setting 1.
As described above, the operation termination condition of 1BBA is set that more than 150 sheets have been paid out. On the other hand, the expected value of the number of payouts per game during 1BBA operation is about "8.664" in setting 1 and about "8.557" in setting 6. Therefore, the expected value of the number of games in which the number of payouts reaches 150 is about "17.3" in setting 1 and about "17.5" in setting 6.
Therefore, when the number of games reaches, for example, the 18th game during 1BBA operation, if it is decided to unconditionally add the advantageous section, the higher the set value, the easier it is to add the advantageous section. be able to.
Further, during the operation of 1BBA, it may be set to add an advantageous section every time a certain number of games have elapsed. Even in this way, the higher the set value, the easier it is to add the advantageous section.

On the other hand, since 1BBB is a special role having a setting difference, it is not possible to add an advantageous section while 1BBB is operating.
Further, as shown in FIG. 22, after the operation of 1BBA is completed, it shifts to non-RT, and when it shifts to non-RT, it stays in non-RT until the pattern symbol is displayed, and when the pattern symbol is displayed. Moves to RT2. That is, it does not go through RT1 after the operation of 1BBA is completed.

On the other hand, after the operation of 1BBB is completed, the process shifts to RT1 and stays in RT1 until the pattern symbol is displayed. In RT1, the replay E is drawn by lottery, and as shown in FIG. 17, if the RT1 is in the advantageous section, the advantageous section is added when the replay E is won. As a result, after the end of the 1BBB operation, the probability of adding the advantageous section is higher than that after the end of the 1BBA operation. Then, if the number of additional games in the advantageous section at the time of winning the replay E is set to an appropriate value, it is possible to balance after the end of the 1BBA operation and after the end of the 1BBB operation.

Then, when the advantageous section is maintained and the transition to RT1 is performed, the instruction function is not activated in a game in which the instruction function can be activated (for example, when the small winning combination B group is won) until the pattern symbol is displayed, and the pattern symbol is not activated. Wait until is displayed. Then, when the pattern symbol is displayed in RT1 and the pattern shifts to RT2, the instruction function is activated. When the advantageous section is maintained and the transition to RT1 is performed, the small winning combination 01 wins a prize by activating the instruction function when the small winning combination B group is won, and the pattern (unless there is a mistake in the pushing order). No design is displayed. Therefore, when the user shifts to RT1 during the advantageous section, he / she can continue to stay at RT1 until the advantageous section ends. A game in which the instruction function is activated when the small winning combination B group is won, and after the predetermined number of games, the instruction function can be activated until the pattern symbol is displayed, not until the end of the advantageous section. For example, when the small winning combination B group is won), the instruction function may not be activated and the pattern may be waited until the pattern is displayed.

Further, when the advantageous section control means 69 decides to shift from the normal section to the advantageous section, the advantageous section control means 69 controls so as to light the advantageous section display LED 77 by the time when a predetermined timing arrives, and is other than the advantageous section (normally). When it is a section or a standby section), the advantageous section display LED 77 is controlled to be turned off.
First, when the advantageous section control means 69 decides to shift to the advantageous section, after the end of the game determined to shift to the advantageous section (when all reels 31 are stopped and there is a payout, a medal is awarded. Turn on the advantageous section display LED 77 until the medal insertion (bet) for the next game (after payout) becomes possible, and until the settlement switch 46 can be operated (settlement processing operation) when holding a stored medal. To control.

Secondly, when it is decided to shift to the advantageous section based on the winning of the conditional device including the 1BB that can carry the winning information after the next game, the combination of the symbols corresponding to the 1BB is stopped. The advantageous section display LED 77 is controlled to be turned on.
Therefore, if the transition to the advantageous section is decided based on the winning of the conditional device including the special role, the special role is a special role that carries the winning information to the next game, for example, 1BB, 2BB, and RB. In a certain case, the advantageous section display LED 77 may be turned on (only when a standby section is provided) until the combination of symbols corresponding to the special combination is stopped.

On the other hand, if the special role is a special role such as SB or CB that is valid only in the winning game and the winning information is not carried over to the next game, the winning of the conditional device including only the small role or the replay is selected. Similar to when the transition to the advantageous section is decided based on the above, it is necessary to turn on the advantageous section display LED 77 until the medal insertion (bet) of the next game becomes possible and the settlement switch 46 can be operated. be.

FIG. 23 is a diagram showing timing 1 and timing 2 as timings for turning on the advantageous section display LED 77.
In the present embodiment, when it is decided to shift to the advantageous section, as the lighting timing of the advantageous section display LED 77, first, "from the time when it is decided to shift to the advantageous section, after the end of this game (all). Until the reel 31 is stopped and the medal of the next game can be inserted (bet) and the settlement switch 46 can be operated (hereinafter, this timing is referred to as "predetermined timing"). The advantageous section display LED 77 is turned on. Then, when the start switch 41 of the next game is operated, the advantageous section starts. That is, in the present embodiment, as a general rule, the advantageous section display LED 77 is turned on before the advantageous section starts. As a result, it is possible to prevent the player from stopping the game without knowing it after deciding to shift to the advantageous section.

In FIG. 23, timing 1 shows an example in this case. In this example, when the small winning combination E1 is (independently) won and it is decided to shift to the advantageous section based on the winning of the small winning combination E1, the advantageous section display LED 77 is turned on by a predetermined timing. As in this example, when it is decided to shift the winning information to the advantageous section based on the winning of the conditional device that does not include 1BB that can be carried over to the next game or later, it is always applied.

Secondly, when it is decided to shift to the advantageous section based on the winning of the conditional device including 1BB that can be carried over to the next game or later, the combination of symbols corresponding to 1BB is displayed. By then, the advantageous section display LED 77 is turned on. Then, when the start switch 41 of the next game of the game in which the combination of symbols corresponding to 1BB is displayed is operated, the advantageous section starts. In the present embodiment, the advantageous section display LED 77 is turned on before the advantageous section starts.
In FIG. 23, timing 2 shows an example in this case. In this example, when 1BBA and small winning combination E1 are won in duplicate and it is decided to shift to an advantageous section based on this duplicate winning, the advantageous section is displayed by the time the combination of symbols corresponding to 1BBA is displayed. The LED 77 is turned on. Therefore, as long as the combination of symbols corresponding to 1BBA is displayed, the lighting timing may be before that, for example, timing 1 (for example, when a standby section is not provided).

Therefore, when it is decided to shift the winning information to the advantageous section based on the winning of the conditional device including the special combination that can be carried over to the next game or later, the combination of symbols corresponding to the special combination is uniformly displayed. When this is done, the advantageous section display LED 77 may be turned on. Alternatively, even if the transition to the advantageous section based on the winning of the conditional device including the special combination is performed, it is uniformly decided to shift to the advantageous section based on the winning of the conditional device not including the special combination. As in the case, the advantageous section display LED 77 may be turned on by a predetermined timing.

Alternatively, when it is decided to shift the winning information to the advantageous section based on the winning of the conditional device including the special combination that can be carried over to the next game or later, the lighting timing may be decided by lottery or the like.
Further, when it is decided to shift the winning information to the advantageous section based on the winning of the conditional device including the special combination that can be carried over to the next game or later, for example, other than the timing 1 and timing 2 shown in FIG. 23, for example. In the next game of the game in which the special role is won, when the start switch 41 is operated, at least a part of the reels 31 is rotating, or when the third stop switch 42 is operated (regardless of whether or not the winning combination is won), etc. It may be.

In that case, when the start switch 41 of the next game of the game is operated, the advantageous section starts (the waiting section ends in the next game of the game in which the special role is won). In addition, when the start switch 41 is operated in a game in which the special role can be won after the next game of the game in which the special role is won, at least a part of the reels 31 is rotated. It may be in the middle or when the third stop switch 42 is operated (regardless of whether or not the winning combination is won). In that case, when the start switch 41 of the next game of the game is operated, the advantageous section starts (the waiting section ends in the game in which the special role can be won. ).

Here, for example, when the small winning combination E1 is won, the 59th "Red 7"-"Cherry"-"Red 7" (FIG. 9) of the small winning combination 36 can be stopped. Then, it is assumed that "Red 7"-"Rotating"-"Red 7" has stopped as a result of pinching in the game at the time of winning 1BBA. Next, when the player aimed at the "cherry" when the middle reel 31 was stopped, but the "cherry" did not stop at the effective line (kicking control was controlled), the small winning combination E1 was won in the game. You can see that it is not. Then, in this case, if the advantageous section display LED 77 is turned on by a predetermined timing, the player knows that the 1BBA is a single winning, and the 1BBA symbol is used in the next game of the game when the 1BBA is won. It becomes possible to push the combination of. That is, the lighting of the advantageous section display LED 77 functions as a winning notification of 1BBA. This is because it is not decided to shift to an advantageous section at the time of loss (when not winning). Conventionally, when 1BB is won, there is a tendency to perform continuous production (a production that incites whether or not 1BB has been won) and then to notify the winning of 1BB, but the advantageous section display LED77 is displayed by a predetermined timing. If it is turned on, such continuous production will be wasted.
Therefore, when it is decided to shift to the advantageous section based on the winning of the conditional device including the 1BB that can be carried over to the next game or later, the case where the advantageous section display LED 77 is not turned on until the winning 1BB wins the prize. To have.

On the other hand, when it is decided to shift to the advantageous section based on the winning of "1BBA + small winning combination E1", if the winning of the small winning combination E1 is prioritized in the game, 1BBA will not be won in the game.
On the other hand, when it is decided to shift to the advantageous section based on the single winning of the small winning combination E1, it is necessary to turn on the advantageous section display LED 77 by a predetermined timing (because the standby section cannot be provided). ).
Therefore, when it is decided to shift to the advantageous section based on the winning of "1BBA + small winning combination E1", if the advantageous section display LED 77 is not turned on until the winning 1BBA wins, the small winning combination E1 At the time of winning the prize, the advantageous section display LED 77 lights up by a predetermined timing, so that the player knows that 1 BBA has not been won twice.

Therefore, when it is decided to shift to the advantageous section based on the winning of "1BBA + small winning combination E1", the case where the advantageous section display LED 77 is turned on by a predetermined timing (timing 1 shown in FIG. 23) and the predetermined A case where the advantageous section display LED 77 is not turned on even after the timing has passed (timing 2 shown in FIG. 23) is provided. Which one to use is, for example, sorted according to the number of "1BBA + small winning combination E1" at the time of winning, or when "1BBA + small winning combination E1" is won (only when it is decided to shift to the advantageous section). A lottery (two-stage lottery) for whether or not to turn on the display LED 77 immediately (whether or not to provide a standby section) can be mentioned. As a result, even if the advantageous section display LED 77 is turned on by a predetermined timing, it does not mean that 1BBA has not been won twice, and the player's expectation can be continuously fueled.

Further, in the present embodiment, since the small winning combination E1 is set to "PB = 1", the small winning combination E1 is always the same regardless of whether the "1BBA + small winning combination E1" is won or the small winning combination E1 is won alone. The small winning combination E1 (small winning combination 36 or 38) wins the game.
However, it is also possible to set the small combination included in the condition device of the small combination E1 to "PB ≠ 1". Then, when the small winning combination included in the condition device of the small winning combination E1 is set to "PB ≠ 1" and it is decided to shift to the advantageous section at the time of winning "1BBA + small winning combination E1", the small winning combination E1 At the time of winning, the advantageous section display LED 77 is turned on by a predetermined timing, but when the small winning combination E1 is not won, it is possible to control that the advantageous section display LED 77 is not turned on even after the predetermined timing has passed.

However, not limited to the above, when it is decided to shift to the advantageous section based on the winning of the conditional device including the special combination that can be carried over to the next game or later, the advantageous section display LED77 is always used by the predetermined timing. May be turned on (always timing 1 shown in FIG. 23), or the advantageous section display LED 77 may not always be turned on even after a predetermined timing has elapsed (always shown in FIG. 23). Timing 2).

Further, when it is decided to shift to the advantageous section at the time of the single winning of the small winning combination D and the single winning of the small winning combination E1, it is necessary to turn on the advantageous section display LED 77 by a predetermined timing (a standby section is provided). Because it cannot be done), it becomes a so-called immediate notification, and the player's expectations cannot be fueled.
Therefore, as described above, when the small winning combination E1 is won alone, there are two advantageous sections: an advantageous section that continues until the predetermined number of games is exhausted, and an advantageous section that ends with the operation of the instruction function when one small winning combination B group is won. Set the type. Then, after turning on the advantageous section display LED 77, until the first small winning combination B group is elected, an effect that incites the degree of expectation (as a final result, whether or not it is an advantageous section that continues until the predetermined number of games is exhausted). By outputting (such as a continuous effect indicating the above), even if the advantageous section display LED 77 is turned on by a predetermined timing, it is possible to fuel the expectations of the player even after that. This is because even if the advantageous section display LED 77 is turned on, it is not known at the time when the advantageous section is turned on whether or not the advantageous section continues until the predetermined number of games is exhausted.

Even when the small winning combination E1 is won alone, if the advantageous section is not transferred, the advantageous section display LED77 does not light in the first place, so it is necessary to output a continuous effect (such as an effect that encourages whether or not to shift to the advantageous section). No.
Further, when the above-mentioned condition device is won, the instruction function at the time of winning the small winning combination B group is not set as one winning of the small winning combination B group (one instruction function operating game) or a predetermined number of games. It is also possible to determine the number of operations of the above by lottery, for example, within the range of 1 to 50 times.

As a specific process for turning on the advantageous section display LED 77, the 8th bit of the segment data for displaying the digit 2 is changed from "0" to "1". Since the segment data for displaying the digit 2 is stored in the RWM 53, the segment data is changed. For example, the segment data up to that point and the data obtained by OR-calculating "10000000" can be stored in the RWM 53 as new data. As a result, the value corresponding to the segment DP becomes "1" in the segment data of the digit 2.

Further, as described above, the digits of the present embodiment include a total of nine digits 1 to 9, and as a method of lighting these digits, control as follows can be mentioned.
The main control board 50 executes "interrupt processing" every 2.235 ms in parallel with this main process, in addition to the "(game progress) main process" which is a process of repeating each game. In this interrupt process, LED lighting control, reel 31 drive control, external signal transmission processing, and the like are performed. Then, in the present embodiment, dynamic lighting is executed for the digits 1 to 9 so that one digit is lit for each interrupt process. For example, in the current interrupt processing, only digit 1 is lit, and in the next interrupt processing, digit 2 is lit. By repeating this, one digit is turned on at a rate of once in nine interrupt processes. In addition to such dynamic lighting, static lighting in which signal lines are connected for each digit may be executed.

Therefore, when it is time to turn on the advantageous section display LED 77, the segment data is changed as described above. After the change, the advantageous section display LED 77 lights up when the lighting timing of the digit 2 arrives due to the interrupt processing.

Further, in the game in which the instruction function should be activated during the advantageous section, the advantageous section control means 69 obtains the number of acquisitions by operating the instruction function separately from the notification of the correct answer pressing order by the sub control board 80 described later. The push order instruction information is displayed on the display LED 78. For example, when the small winning combination B1 is won, the push order instruction information "= 1" corresponding to the push order instruction number "A1" is displayed on the acquired number display LED 78. This control corresponds to the "operation of the instruction function" in the present embodiment.

It is the instruction function operation game during the advantageous section
1) Non-RT and RT1: When the small winning combination C group is won (When the small winning combination B group is won, the pattern pattern is displayed, so the instruction function does not operate.)
2) RT2: When replay B group is won, when small role B group is won, and when small role C group is won 3) RT3: When replay C group is won, small role B group is won, and small role C group is won. ..

Further, as described above, when the small winning combination A is won, the instruction function is operated as a dummy. When the small role A is won, the small role 01 wins regardless of the push order, so no matter which push order is specified, there is no disadvantage to the player, so even if a specific push order is displayed, the game is played. It does not harm the justice of.
Specifically, when the small winning combination A is won, one of the push order instruction numbers "A1" to "A3" may be selected by a lottery using a random number or the like.

Further, when the small winning combination E1 is won while approaching the upper limit of the advantageous section, the advantageous section control means 69 selects the push order instruction number "A3" and displays the push order of the right first stop. As a result, it is possible to prevent the middle cherry from appearing when the upper limit of the advantageous section is approaching.

In the present embodiment, in the advantageous section, the advantageous section is added when the small winning combination E1 is won, and the advantageous section is not added when the small winning combination E2 is won. Therefore, when the small winning combination E2 in the advantageous section is won, it is always added. , Displaying the right first stop so that the middle cherry is not displayed. In particular, since the advantageous section is always added when the small winning combination E1 is won in the advantageous section, it is possible to give the player the impression that the advantageous section is added by displaying the middle cherry. Therefore, when it is not desired to display the middle cherry in a game (when the small winning combination E2 is won) in which the advantageous section is not added, the right first stop is displayed.

Further, for example, when the upper limit of the advantageous section is approaching (when the advantageous section cannot be added), in order to prevent the middle cherry from being displayed, either the small winning combination E1 or the small winning combination E2 is won. However, when the instruction function is activated, the right first stop is displayed and the middle cherry is not displayed.

In the present embodiment, the maximum number of games in the advantageous section is set to "1500 games". Therefore, for example, when the number of games from the start of the advantageous section becomes "1400 games" or more and the small winning combination E1 (and E2) is won, the right first stop is displayed by activating the instruction function. ..
As described above, the "operation of the instruction function" in the present invention refers to the display of the operation mode of the stop switch 42 which is advantageous to the player, but in the present embodiment, the appearance of the middle-stage cherry is avoided. The display of the pressing order is also included in the "operation of the instruction function". Of course, such a case may not be included in the "operation of the instruction function", and the pressing order may be displayed only on the image display device 23.

In the present embodiment, an advantageous section counter 69a and an upper limit counter 69b are provided as counters for counting the number of games played for the advantageous section (see FIG. 1).
When it is decided to shift to the advantageous section, the advantageous section counter 69a sets the initial value of the number of games (for example, "100") determined at that time. Then, the count value is decremented every time one game is digested, and when it becomes "0", the advantageous section ends. In addition, some decrements are performed from the game that has shifted to the advantageous section, and some are performed after the end of the 1BB game. Further, when the advantageous section counter 69a is determined to shift to the advantageous section, it is not necessary to set the initial value of the number of games (for example, "100") determined at that time, and after the end of the 1BB game. It may be the one that sets the initial value.
Further, when an advantageous section is added during the advantageous section, a value corresponding to the added value is added to the current count value of the advantageous section counter 69a.

For example, when the count value of the advantageous section counter 69a is "55", it is determined to add the advantageous section, and when the number of additional games is "30", the count value is changed from "55" to "55". Update to "85". Then, each time one game is digested, "84", "83", and so on are decremented one game at a time.

Further, when 1BBA is in operation (excluding those based on the duplicate winning of 1BBA and small winning combination D), the counting by the advantageous section counter 69a is continued, but when 1BBB is in operation, the advantageous section counter 69a is continued. Suspend counting by. In this embodiment, the setting in this way enables the addition of the advantageous section during the operation of 1BBA (excluding the one based on the duplicate winning of 1BBA and the small winning combination D), but the addition of the advantageous section is possible during the operation of 1BBB. Since the addition is not executed, it is set as described above in order to balance both sides (so that the operation of 1BBBA in the advantageous section is not extremely disadvantageous to the player than the operation of 1BBBA). However, the present invention is not limited to this, and the counting by the advantageous section counter 69a may be continued even when either 1BBA or 1BBB is operating, or the advantageous section counter may be continued even when either 1BBA or 1BBB is operating. The counting by 69a may be interrupted.

On the other hand, after winning 1BBA or 1BBB during the advantageous section, until 1BBA or 1BBB wins, respectively (inside), the counting by the advantageous section counter 69a is continued. When 1BB is won, or when it is notified that 1BB has been won, the counting by the advantageous section counter 69a may be interrupted at that time. Even if the count by the advantageous section counter 69a is interrupted when 1BB is won, the remaining number of games in the advantageous section displayed on the image display device 23 is until it is notified that 1BB has been won. You may try to decrement one game at a time.

In addition, there is a case where a conditional device including 1BB is won in a normal section (such as a duplicate winning of 1BBA and a small winning combination E1), and the section shifts to an advantageous section based on the winning of this conditional device. In this case, the waiting section is started from the next game (only when the waiting section is provided), and it is inside 1BB.
On the other hand, when the condition device including 1BB in the advantageous section is won, it is in the advantageous section and inside the 1BB, and the addition of the advantageous section is not performed in the inside of the 1BB in the advantageous section.

Therefore, if the condition device including 1BB is won in the normal section and the shift to the standby section has not yet been made to the advantageous section, a long fanning effect (whether or not the 1BB has been won is notified. It is considered that it is not so disadvantageous to the player even if the output (for example, continuous production over a plurality of games) is output. This is because the advantage section counter 69a does not count (decrement) or the upper limit counter 69b, which will be described later, does not count (decrement) during the standby section because it is not in the advantageous section.
On the other hand, when the condition device including 1BB in the advantageous section is won and the inside is inside, the count (decrement) by the advantage section counter 69a and the upper limit counter 69b described later are performed even after the inside is inside. Count (decrement) is performed. In this case, since it is not possible to add an advantageous section, it is preferable to notify the winning of 1BB at an early stage without performing an unnecessarily long fanning effect.
Specifically, for example, the average number of games played by the former fanning effect is set to 4 games, and the average number of games played by the latter fanning effect is set to 2 games.

On the other hand, when it is decided to win the small winning combination E1 independently and shift to the advantageous section in which the instruction function is activated when the small winning combination B group is won once, in the present embodiment, the advantageous section counter 69a counts. Do not set the value. In this case, regardless of the count value of the advantageous section counter 69a, the advantageous section is continued until the small winning combination B group is won. Then, when the small winning combination B group is elected and the instruction function is activated, it is determined that the end condition of the advantageous section is satisfied in this game, and the advantageous section is ended.

If the number of times the instruction function is operated when the small winning combination B group is won is set in advance as the end condition of the advantageous section, a counter (decrement counter) for counting the number of games played when the small winning combination B group is won is provided in this counter. You may set "1". Then, when the instruction function is activated once when the small winning combination B group is won, the count value becomes "0", and it may be determined that the end condition of the advantageous section is satisfied.

By providing something like an advantageous section flag and setting it to "on" during the advantageous section, it is possible to determine whether or not the game is an advantageous section this time.
However, in the present embodiment, the 8th bit of the segment data of the digit 2 serves as an advantageous section flag. As described above, when it is determined that the end condition of the advantageous section is satisfied in this game, or when the count value of the advantageous section counter 69a becomes "0", the 8th bit in the segment data of digit 2 is set to "0". Execute the process to change to.

If the small winning combination E1 is won independently and it is decided to shift to the advantageous section, either the small winning combination E1 is transferred to the advantageous section with a fixed number of games, or the instruction function is activated when the small winning combination B group is won once. A lottery will be held to determine whether to shift to an advantageous section that ends (so-called fake advantageous section). Here, how to allocate the probabilities between the former and the latter is arbitrary.

Then, for example, when the small winning combination E1 is independently won and it is decided to shift to the advantageous section, the advantageous section display LED 77 is turned on by a predetermined timing, and an effect of inciting which advantageous section has been shifted is output. (You may continue until you win the small role B group). Next, when the small winning combination B group is won, if the instruction function is activated in the game and then the advantageous section ends with one operation of the instruction function, the advantageous section ends with this game (advantageous). The section display LED 77 is turned off). On the other hand, when the interval is shifted to the advantageous section of the predetermined number of games, the advantageous section is continued even after the next game (the lighting of the advantageous section display LED 77 is maintained).
In the above example, it is assumed that the small winning combination B group is won before the predetermined number of games is reached from the start of the advantageous section.

Further, the upper limit counter 69b always starts counting when the advantageous section is started (when it is determined to shift to the advantageous section, or "1500" is set at the start of the advantageous section), and then the advantageous section is started. Until the end of the section, the count is not interrupted under any circumstances, and the count value is decremented by "1" for each game. Further, for example, counting is continued even during 1BB operation. This point is different from the advantageous section counter 69a. The advantageous section counter 69a and the upper limit counter 69b may increment the count value by "1" from "0" for each game.

Then, when the value of the upper limit counter 69b becomes "0", the advantageous section control means 69 sets the advantageous section in the game this time even if the count value of the advantageous section counter 69a exceeds "0". Forcibly) ends (updates the count value of the advantageous section counter 69a to "0"), turns off the advantageous section display LED 77 (updates the 8th bit to "0" in the segment data of digit 2). As described above, the count value of the upper limit counter 69b has the highest priority in the advantageous section, and when the count value of the upper limit counter 69b becomes "0", the advantageous section ends even if 1BB is in operation.

Further, during the advantageous section, it is necessary to execute the instruction function operating game in which the number of payouts is 9 (the maximum number of payouts when the specified number is 3) at least once. Therefore, in the advantageous section, it is necessary to execute the instruction function operating game at least once when the small winning combination B group is won, but when the value of the upper limit counter 69b becomes "0", the small winning combination B is never performed. Even if the instruction function operating game is not executed at the time of winning the group, or even if the small winning combination B group has never been won, the advantageous section is (forced) ended in this game, and the advantageous section display LED77 Turns off.
Further, the image display device 23 may display the number of remaining games, the number of digested games, or the like as an image with reference to the values of the advantageous section counter 69a and the upper limit counter 69b.

In FIG. 1, the external signal transmitting means 70 transmits an external signal to the external centralized terminal plate 100. This external signal is a signal indicating the start of the advantageous section, the end of the advantageous section, the start of the 1BB operation, the end of the 1BB operation, or the like.
The main control board 50 executes each game and game end check process, and updates the external signal control number at the time of this game end check process.
In the present embodiment, the "external signal control number" is a number that takes different values depending on the start of the advantageous section, the end of the advantageous section, the start of the 1BB operation, and the end of the 1BB operation.

Further, when the start switch 41 is operated, the external signal flag is updated so that the value corresponds to the external signal control number. Then, after updating the external signal flag, the external signal transmitting means 70 transmits an external signal corresponding to the external signal flag from the output port 52. When this external signal is input to the external centralized terminal plate 100, it is transmitted to the hall computer 200. Then, the external signal is output to, for example, a data counter.

The control command transmission means 71 transmits information (control command) necessary for the effect output by the sub control board 80 to the sub control board 80.
The control command includes, for example, a first control command and a second control command. Both the first control command and the second control command are, for example, 8-bit 1-byte data. One control command is a pair of a first control command and a second control command. Further, the first control command is data indicating the type of control command, and the second control command is data indicating parameters (variables).

For example, in the case of a control command indicating RT, the first control command is "33 (H)" (00110011 (B)) in this embodiment. Further, when the RT parameter is, for example, RT1, it is "00000001 (B)" in this embodiment. Therefore, the 2-byte data "0010011/00000001"("/" indicates between the first control command and the second control command, which is not actually present), which is a combination of these, is the RT control command. Is transmitted from the main control board 50 to the sub control board 80.
As for the push order instruction number (only during the advantageous section), the effect group number, and the accessory condition device number, the first control command is the type data and the second control command is RWM53, as in the case of the above RT. It is the data stored in.

The control command transmitting means 71 does not transmit the winning and replay condition device numbers to the sub control board 80. For example, when the push order bell is won, there is a risk that the correct push order will be known based on the winning and replay condition device numbers due to fraudulent acts. On the other hand, there is no risk of fraudulent activity as described above for the accessory condition device number. Therefore, for example, when 1BBA is won, the accessory condition device number "1" is transmitted to the sub control board 80.

Further, when the condition device having the correct answer pressing order is won in the advantageous section, the pressing order instruction number corresponding to the correct answer pressing order is acquired and stored in the RWM 53. On the other hand, when the conditional device that is in the advantageous section and does not have the correct push order is won, the push order instruction number is not acquired or stored in the RWM53. Here, at the start of each game, the data of the push order instruction number of RWM53 is cleared, but the data after clearing is "A0". Therefore, the data of the push order instruction number of the RWM 53 is "A0" except when the condition device having the correct push order is won in the advantageous section.
Further, during the normal section or the standby section, even if the condition device having the correct push order is won, the push order instruction number is not acquired or stored in the RWM 53.

Then, when the condition device having the correct push order is won in the advantageous section, the control command transmission means 71 transmits the push order instruction number to the sub control board 80.
Further, the control command transmission means 71 transmits the information of "A0" as the push order instruction number except when the condition device having the correct push order is won in the advantageous section.
Furthermore, when not in the advantageous section, the control command transmitting means 71 does not transmit the push order instruction number to the sub control board 80. It is conceivable that the control command transmitting means 71 uniformly transmits the push order instruction number of "A0" when it is not in the advantageous section, but in the present embodiment, when it is not in the advantageous section, the push order instruction is given. The number is not transmitted to the sub control board 80.

In FIG. 1, the sub CPU 85 of the sub control board 80 includes an effect output control means 91.
As described above, the effect output control means 91 controls each control command transmitted from the main control board 50, specifically, the RT number, the push order instruction number, the effect group number, the accessory condition device number, and the like. Based on the command, at what timing (when operating the start switch 41, when operating each stop switch 42, etc.), what kind of effect is output (how to turn on, blink, or turn off the lamp 21). , What kind of sound is output from the speaker 22, what kind of image is to be displayed on the image display device 23, etc.), and the specific production contents are determined by lottery.

Then, the effect output control means 91 controls the output of the effect lamp 21, the speaker 22, and the image display device 23 according to the determination. In addition, during the operation of 1BB or in the advantageous section, the number of acquired cards, the number of games (the number of remaining games or the number of digested games), and the like are displayed as images. Further, in the advantageous section, when the instruction function is activated, the correct answer pressing order is notified (image display). For example, when a small winning combination B1 is won in a game in an advantageous section and a control command corresponding to the push order instruction number "A1" is received, the correct answer push order is "left first stop" or "1- ○". -○ ”etc., to notify the content that the player can easily know the correct answer pressing order. When the push order instruction number of "A0" is received in the advantageous section, the push order is not notified.

Furthermore, it can be said that the control command of the effect group number does not include information on which condition device was actually won, but includes rough winning information. For example, when the control command corresponding to the effect group number "5" is received, it is not possible for the sub control board 80 side to know whether the small winning combination A, the small winning combination B group, or the small winning combination C group is won. .. However, it is possible to know whether or not the small winning combination A, the small winning combination B group, or the small winning combination C group has been won. Therefore, it is possible to display an effect such as displaying a "bell" pattern or lighting a frame lamp in "yellow", which is the corresponding color of "bell".

Here, when the small winning combination A is won, the small winning combination 01 always wins regardless of which pressing order the stop switch 42 is operated. Therefore, immediately after the start switch 41 is operated, that is, the first stop switch. It is possible to perform a bell (yellow) effect before the is operated.
On the other hand, when the small winning combination B group or the small winning combination C group is won in the normal section, the bell (yellow) effect can be performed when the winning of the small winning combination 01 is confirmed, that is, after the operation of the first stop switch 42. preferable. Of course, it may be after the operation of the second stop switch 42 or after the operation of the third stop switch 42.

However, if the output timing of the effect when the small role A is won and the output timing of the effect when the small role B group or the small role C group is won are different, the small role A is assigned based on the difference in the timing. Since it is possible to determine whether the player has won the small winning combination B group or the small winning combination C group, it is possible to count the number of times the small winning combination A has been won, and by extension, it is possible to estimate the set value.
Therefore, when the small winning combination A is won in the normal section, the output of the bell effect is started at the same timing as when the pressing order is correct when the small winning combination B group or the small winning combination C group is won, for example, immediately after the operation of the first stop switch 42. By doing so, it is possible to make it impossible to determine which of the small winning combination A, the small winning combination B group, and the small winning combination C group has been won. In particular, in the present embodiment, when any of the small winning combination A, the small winning combination B group, or the small winning combination C group is won, the control command corresponding to the same effect group number "5" is transmitted. .. In this way, the effect group numbers of the small combination A, the small combination B group, and the small combination C group are made the same (“5”), and on the sub control board 80 side that receives the effect group number, for example, the first stop switch. If it is designed so that the effect is output at the timing immediately after the operation of 42, the effect group numbers of the small combination A, the small combination B group, and the small combination C group are different ("5" to "7"). Designed to be more efficient than the previous case (in the latter case, when any of the production group numbers "5" to "7" is received, the production is output at the timing immediately after the operation of the first stop switch 42, for example. It is inefficient because it has to be designed to do so).

24 and 25 show the timing of transmitting the control command of the push order instruction number, the effect group number, and the accessory condition device number, and the display of the push order instruction information by the acquired number display LED 78 (operation of the instruction function (on the main side). (Display)), is a time chart showing notification of the correct answer pressing order (notification on the sub side) by the image display device 23. 24 and 25 show four examples 1 to 4.
In FIGS. 24 and 25, first, when the start switch 41 is operated by the player, the combination lottery means 61 draws the condition device, and the effect group number corresponding to the winning condition device is determined. Further, when the section is in the advantageous section, the push order instruction number corresponding to the winning condition device is determined.

Furthermore, the main control board 50 transmits control commands of the push order instruction number (only during the advantageous section), the effect group number, and the accessory condition device number to the sub control board 80. When the sub-control board 80 is in the advantageous section, the sub-control board 80 notifies the correct push order based on the received push order instruction number. On the other hand, when the main control board 50 is in the advantageous section, the push order instruction information corresponding to the push order instruction number is displayed by the operation of the instruction function.

In "Example 1" of FIG. 24, when the push order instruction number is determined, the push order instruction information is first displayed by the operation of the instruction function by the main control board 50. After that, the push order instruction number is transmitted, and then the effect group number and the accessory condition device number are transmitted. Next, the sub-control board 80 determines that the start switch 41 has been operated when the accessory condition device number is received, and notifies the correct push order based on the received push order instruction number. Both the display of the push order instruction information and the notification of the correct push order are performed until the reel 31 reaches the constant speed rotation.

Further, as in the present embodiment, when the correct answer pressing order is so-called three choices (first stop), the first (first) stop switch 42 is operated to notify the correct answer pressing order by the image display device 23. Until then. On the other hand, for example, when the correct answer pressing order is so-called 6 choices, the image display device 23 notifies the correct answer pressing order until the third (last) stop switch 42 is operated. Of course, even if the correct answer pressing order is so-called three choices as in the present embodiment, the correct answer pressing order may be continuously notified until the third (last) stop switch 42 is operated. be.

In the present embodiment, when the first stop switch 42 is operated, the control command is transmitted from the main control board 50 to the sub control board 80 as described above, so that the sub control board 80 receives this control command. Therefore, it can be determined that the first stop switch 42 has been operated. Then, when the first stop switch 42 is operated, the image display device 23 ends the notification of the correct answer pressing order. Of course, it is necessary to continue the production other than the correct answer pressing order, for example, the image display (character display, etc.) peculiar to the advantageous section.

Further, the push order instruction information is displayed by the acquired number display LED 78 until the winning determination is made on the main control board 50. However, the present invention is not limited to this, and when the correct answer pressing order is three choices as in the present embodiment, the pressing order instruction information may be displayed until the first stop switch 42 is operated.
The display of the acquired number display LED78 after the push order instruction information is displayed is "00" (the upper and lower digits display "0"), "* 0" (the upper digit is off (*), and the lower digit is "". 0 ”is displayed),“ ** ”(upper and lower digits are turned off),“ −− ”(both upper and lower digits are lit only in segment G), and the like.

In "Example 2" of FIG. 24, after the push order instruction number is transmitted to the sub control board 80 by the main control board 50, the push order instruction information is displayed on the acquired number display LED 78 by the operation of the instruction function, and then the effect group. Send the number and the accessory condition device number. After receiving the effect group number and the accessory condition device number, the sub control board 80 notifies the correct answer pressing order.

Further, in "Example 3" of FIG. 25, after the main control board 50 transmits the push order instruction number, the effect group number, and the accessory condition device number, the sub control board 80 sets the correct push order on the image display device 23. At the moment when the reel 31 rotates at a constant speed (or immediately before that), the main control board 50 displays the push order instruction information by the operation of the instruction function. In Examples 1 and 2 described above, the operation of the instruction function (display of the push order instruction information) by the main control board 50 is performed at an earlier timing than the notification of the correct answer push order by the sub control board 80. .. On the other hand, in Example 3, the notification of the correct answer pressing order by the sub control board 80 is performed at an earlier timing than the operation of the instruction function (display of the pressing order instruction information) by the main control board 50.

In "Example 4" of FIG. 25, the operation of the instruction function (display of the push order instruction information) by the main control board 50 and the notification of the correct answer push order by the sub control board 80 are performed at substantially the same timing. .. In the case of such control, for example, the instruction function is activated after "N" ms elapses after the push order instruction number or the accessory condition device number is transmitted from the main control board 50 to the sub control board 80 (push order instruction). The sub-control board 80 controls to start the notification of the correct answer pressing order after "N" ms has elapsed after receiving the pressing order instruction number or the accessory condition device number. Can be mentioned.

Although four examples are shown in FIGS. 24 and 25, it is preferable that the operation of the instruction function (display of the push order instruction information) is performed after the operation of the start switch 41 until the reel 31 rotates at a constant speed. .. Further, it is preferable that the push order notification is performed by the sub control board 80 side after the instruction function is operated by the main control board 50 side. By setting in this way, when the main control board 50 transmits an erroneous push order instruction number to the sub control board 80, or the sub control board 80 notifies the push order different from the received push order instruction number. Even in this case, since the push order instruction information is already displayed by the main control board 80, the player may notice an error in the notification by the sub control board 80, and the player may suffer a disadvantage. No.
Further, the operation of the instruction function (display of the push order instruction information) by the main control board 50 side is performed until the winning determination, but it may be until the third reel 31 is stopped.

Subsequently, a case where the operation of the instruction function (display of the push order instruction information) and the notification of the correct push order will be described more specifically. FIG. 26 is a diagram for explaining the flow of the game (flow from top to bottom in the figure), the display of the acquired number display LED 78, and the notification example of the image display device 23. The example of FIG. 26 is the timing corresponding to “Example 1” of FIG. 24.

In the instruction function operation game in the advantageous section, first, when the start switch 41 is operated, the main control board 50 activates the instruction function and displays the push order instruction information on the acquisition number display LED 78. In the example of FIG. 26, an example in which the small winning combination B1 is won is shown. Therefore, the acquired number display LED 78 displays the push order instruction information corresponding to the push order instruction number “A1”, that is, “= 1”.
Then, before the reel 31 reaches the constant speed rotation, the image display device 23 notifies the correct answer pressing order. In the example of FIG. 26, an example of displaying "1 ○○" is shown.

Next, when the first (first) stop switch 42 is operated and the left stop switch 42 is operated, that is, when the correct answer is in the pressing order, the image display device 23 indicates that the pressing order is correct. Is output (correct answer production). On the other hand, if the answer is incorrect, the image display in the correct push order is deleted.
In the present embodiment, the correct answer / incorrect answer is determined by the operation of the first stop switch 42. Therefore, when the first stop switch 42 is operated, the notification (image display) regarding the correct answer pressing order is terminated. For example, the pressing order is When there are six options, the correct answer pressing order may be continuously notified until the second stop switch 42 is operated or the third stop switch 42 is operated.

Further, in the example of FIG. 26, the operation of the instruction function (display of the push order instruction information) continues to be displayed until the winning determination is made (the same applies to the example 1 of FIG. 24). However, the present invention is not limited to this, and the operation of the instruction function (display of the acquired number display LED 78) may be terminated in the same manner as the notification of the correct answer pressing order by the image display device 23, for example, when the incorrect answer pressing order is reached. .. Further, as in the present embodiment, when the correct answer pressing order is three choices, an instruction is given when the first stop switch 42 is operated (even if the first stop switch 42 is operated in the correct answer pressing order). The operation of the function may be terminated.

However, it is desirable to end the operation of the instruction function after stopping the notification by the image display device 23. This is to prevent the push order notification from being performed on the sub control board 80 side even though the instruction function is not activated on the main control board 50 side. However, of course, the operation of the instruction function may be terminated at the same time as the end of the notification by the image display device 23, or the operation of the instruction function may be terminated before the end of the notification by the image display device 23.

Of course, even if the pressing order is incorrect, the image display device 23 may continue to notify the correct pressing order.
However, if the push order notification by the image display device 23 is stopped when the push order is incorrect, it is possible to switch to another effect.

When all reels 31 are stopped, a winning determination is made. Here, when the small winning combination 01 wins and 9 medals are paid out, the display of the acquired number display LED78 indicates that 9 medals have been paid out from the display of the push order instruction information "= 1". It changes to the indicated "09". If one winning combination is won due to a mistake in the pushing order or the like, "01" is displayed, and if the winning combination is missed, "00" (or "**") is displayed. From the display of the push order instruction information "= 1" to the display of the number of medals to be paid out "09", "= 1" → "00" (in order to reset the display once, "00" is displayed. ) → "09" may be displayed.

Alternatively, "= 1"->"**" (in order to reset the display once, the upper and lower digits are turned off)->"09" may be displayed.
Further, when the player operates the bet switch 40 or cares for the medal and the medal is bet, the displayed content is changed to "00" in order to clear the content of the acquired number displayed on the acquired number display LED 78. (It may be "**").

In FIG. 1, the management information control means 72 is a means for controlling (memory, calculation, display, etc.) the management information displayed on the management information display LED 74.
In the present embodiment, the information to be displayed on the management information display LED 74 is
(1) Advantageous section ratio (cumulative)
(2) Continuous character ratio (6000 games (15 sets total))
(3) Character ratio (6000 games (15 sets total))
(4) Continuous character ratio (cumulative)
(5) Character ratio (cumulative)
(See FIG. 38, which will be described later).

First, the "advantageous section ratio (stay ratio of the advantageous section)" is the ratio of the advantageous section to the total game section (normal section + standby section + advantageous section) (staying in the advantageous section with respect to the total game section). ). For example, in the game section with the number of games of "10000", when the number of games of the advantageous section is "7000", the ratio of the advantageous section is "70 (%)".
Further, in the present embodiment, one set is defined as "400" number of games. Then, the total of 15 sets, that is, the number of "6000" games is set as the "total", and each ratio in the number of "6000" games is calculated.

Furthermore, the "cumulative" refers to the sum of the numerical values that have been continuously counted up to that point, and in the present embodiment, the total number of games is counted for the purpose of at least "175,000" games. When the cumulative total is less than the number of "175000" games, the cumulative value is displayed by, for example, a blinking display, and when the total number of games is "175000" or more, the cumulative value is displayed by, for example, a lighting display. The cumulative total continues to be added until the value (upper limit value) that can be stored in the predetermined address of the RWM 53 is reached even after the number of games is "175000" or more.

The "continuous accessory ratio" refers to the ratio of the number of medals acquired when the first-class special accessory (RB) is activated to the total number of medals acquired. Therefore, in the present embodiment, "refers to the number of medals acquired during 1BB operation with respect to the total number of medals acquired.
For example, when the number of medals acquired in the number of "6000" games is "2000" and the number of medals acquired when the "Type 1 Special Character (RB)" is activated is "500", the "continuous combination" The object ratio (6000 games) is "25 (%)".

Further, the "role of the character" refers to the ratio of the number of medals acquired when the character is activated to the total number of medals acquired. Here, the "role" means, in addition to the above-mentioned first-class special accessory, the second-class special accessory (CB), 2BB (second-class accessory continuous operation device, CB continuously operates), SB. (Single bonus) is included.
Since CB, 2BB, and SB are not provided in the present embodiment, the bonus ratio is the same as the continuous bonus ratio.

27 to 31 (FIG. 31 shows a modification of FIG. 29) are diagrams showing a part of the storage area of the RWM 53 controlled by the management information control means 72. In the figure, the 4-digit numerical value starting with "F" indicates the address of RWM53. A 1-byte (8-bit) data buffer (storage area) is provided for each address.

First, FIG. 27 shows a buffer that stores data about advantageous intervals. As information regarding the advantageous section, it has three storage areas of a value corresponding to the number of games played in the advantageous section, a total number of games played, and a ratio of the advantageous section. The storage area of the value corresponding to the number of advantageous section games is 4 bytes ("F004" to "F001"), and the storage area of the total number of games is 3 bytes ("F007" to "F005"). The storage area of is 1 byte (“F008”).

In the present embodiment, the total number of games is updated so that the value of the total number of games is "+1" each time one game is digested.
On the other hand, during the advantageous section, the value obtained by multiplying the value of the number of advantageous section games by 100 (referred to as "value corresponding to the number of advantageous section games") is added every time one game is digested. Therefore, a storage area of 3 bytes is provided for the total number of games played, and a storage area of 4 bytes is provided for the value corresponding to the number of games played in the advantageous section.

In the present embodiment, it is an object to store at least "175,000" times or more as the total number of games played. This is to display the advantageous section ratio, the continuous bonus ratio, and the bonus ratio when the total number of games is "175,000" or more.
Here, since "175000 (D)" has "18" digits in binary, it can be stored in 3 bytes of "24" digits.

Further, assuming that all of the total number of games "175000 (D)" are advantageous sections, the value corresponding to the number of advantageous section games is "175000 x 100" (D), and this value is "25 digits" in binary. Therefore, 3 bytes of "24" digit is not enough, but 4 bytes of "32" digit can be stored.
For the above reasons, the storage area for the total number of games is set to 3 bytes, and the storage area for the value corresponding to the number of advantageous section games is set to 4 bytes.

Regarding the total number of games, "1" is added for each game, but the total number of games is not limited to this, and a numerical value other than "1" (value corresponding to the total number of games) is added. May be good.
On the other hand, since the advantageous section ratio is "100 (D)" at the maximum value, the value is "7" digits in binary, so that it can be stored with a storage capacity of 1 byte.

The total number of games is continuously updated for each game and the number of games, and when the 3-byte storage area reaches the upper limit (3 bytes full, that is, "FFFFFF (H)", about 16.78 million in decimal), the total number of games is changed. The count ends at that point, and the number of games is not updated from the next game.
As for the value corresponding to the number of advantageous section games, "+100" is added for each game during the advantageous section, but even if it is assumed that all the games are in the advantageous section, the value of the total number of games becomes 3 bytes full. Can be counted up to. Then, when the counting of the total number of games is completed, the counting of the value corresponding to the number of advantageous section games is also completed.

The advantageous section ratio is a value calculated by "value corresponding to the number of advantageous section games / total number of games played" (as will be described later, subtraction is actually performed, and division is not performed). Since the value corresponding to the number of advantageous section games is a value obtained by multiplying the number of advantageous section games by 100, the ratio itself can be calculated by the above calculation. Since the main CPU 55 of the present embodiment uses an assembler, cannot handle the decimal point, and cannot perform division using a value exceeding 2 bytes, the above calculation method is adopted. Allows calculation by.
In addition, for the advantageous section ratio, an integer is stored in this embodiment, and the fractional part is rounded down. For example, when the total number of games is "1100 (D)" and the value corresponding to the number of advantageous section games is "56000 (D)", the advantageous section ratio is "50 (D)", and "F008" is "F008". "0010010 (B)" is stored.

Further, the advantageous section ratio can be updated every game, but for example, when there is a request to display the advantageous section ratio, the advantageous section ratio is calculated from the value corresponding to the number of advantageous section games and the total number of games. It may be stored in "F008". Then, the numerical value of the decimal number based on the value stored in "F008" is displayed as the advantageous section ratio.

FIG. 28 is a diagram showing a buffer for storing data regarding the total number of payouts. When a medal is paid out by winning a small winning combination, the value stored in the predetermined storage area of the RWM53 is updated.
As shown in FIG. 28, the ring buffer is provided with 15 storage areas (01 sets to 15 sets) composed of 2-byte data (for example, “F012 (upper digit)” and “F011 (lower digit)”).
Then, in each 2-byte data, the number of payouts during 400 games is stored. For example, when 9 cards are won and 9 cards are paid out, "9 (D)" is added to the total number of cards paid out.
Here, in the slot machine according to the rules, the maximum number of cards to be paid out in one game is set to "15" or less, and assuming that 15 cards are paid out in each game, "6000" cards are paid out in 400 games. It becomes. Since "6000 (D)" has 13 digits in binary, it can be stored in 2 bytes (16 digits).

Further, from the first game to the 400th game, when a payout is made, the number of payouts is stored in the 01st set (“F012” and “F011”). From the next 401st game to the 800th game, the number of payouts is stored in the 02nd set ("F014" and "F013").
In this way, 400 games are set as one set, and the values are stored in different buffers for each set.

In addition, a storage area (3 bytes) for the total number of payouts of 15 sets (6000 games) is provided (“F031” to “F02F” in FIG. 28). This storage area is for storing 15 sets, that is, the total number of payouts during 6000 games.
Assuming that 15 cards have been paid out in all 6000 games, it is necessary to store up to the value of "90000 (D)", but since "90000 (D)" is 17 digits in binary, it is necessary to store it. It can be stored in 3 bytes (24 digits).

For example, up to the first 15th set, the total number of payouts for the number of games less than 6000 is stored in "F031" to "F02F".
Then, when the 6000th game is reached, the total number of payouts for the total of 15 sets (6000 games) is also stored because the number of payouts for 400 games is stored in all the buffers of the 01st to 15th sets (2 bytes each). In addition, it becomes the total value for 6000 games.
Next, when the game shifts to the 6001 game, the 2-byte data (“F012” and “F011”) of the 01st set is cleared, and the total number of payouts from the 6001 game to the 6400 game is stored in this buffer. go. From the 6000th game to the 6399th game, the total number of payouts (3 byte data) of the total of 15 sets is maintained unchanged.

Then, in the 6400th game, when the addition to the 2-byte data of the 01st set is completed, the total number of payouts for the 15 sets is calculated (adding each 2-byte data from the 01st set to the 15th set). Update the total number of payouts for the calculated 15 sets.
Similarly to the above, after the 6401 game, when the game shifts to the 6401 game, the 2-byte data ("F014" and "F013") of the 02nd set is cleared, and the 6401 game to the 6800 game are stored in this buffer. Memorize the total number of payouts up to.
The total number of payouts for 15 sets is updated every 400 games by the above method, but when all 15 sets are replaced with new data, the total number of payouts for 15 sets is calculated. You may update to that value.

The total number of payouts (cumulative) (“F034” to “F032”) is a 3-byte storage area for storing the cumulative number of payouts. The cumulative number of payouts is calculated in order to calculate each ratio (such as the continuous accessory operation ratio described later) when the number of games is 175,000 or more. However, the cumulative number of payouts continues to be stored even after 175,000 games have passed, and the update ends when the storage capacity of the three bytes reaches the upper limit value (three bytes full).
Assuming that 15 medals are paid out for each game of 175,000 times, the binary number is 22 digits, so that it can be stored with a storage capacity of 3 bytes.

FIG. 29 is a diagram showing a buffer for storing data regarding the number of payouts related to continuous accessories in RWM53.
As shown in FIG. 29, the 01st set includes a ring buffer provided with 15 storage areas composed of "F043 (highest digit)" to "F041 (lowest digit)"). ..

Then, in each of the 3-byte data, a value obtained by multiplying the number of medals to be paid out when the continuous accessory is operated by 100 (referred to as a “value corresponding to the number of payouts”) is stored. For example, when a continuous winning combination is activated, a winning combination of 10 cards is awarded and 10 cards are paid out, the value corresponding to the number of cards to be paid out is "+1000".
It should be noted that the reason why the value multiplied by 100 is stored instead of the value of the number of payouts itself is the same as the value corresponding to the number of games in the advantageous section. This is so that it can be calculated.

Further, each 3-byte data stores a value corresponding to the number of payouts when the continuous accessory is operated during 400 games. Specifically, from the first game to the 400th game, when there is a payout number when the continuous accessory is operated, the value corresponding to the payout number is stored in the 01st set ("F043" to "F041"). do. From the next 401st game to the 800th game, the value corresponding to the number of payouts is stored in the 02nd set ("F046" to "F044").
In this way, 400 games are set as one set, and the values are stored in different buffers for each set.
Assuming that 15 medals are paid out for each game in 400 games in a row, the value corresponding to the number of payouts is "600,000 (D)", which is 20 digits in binary, so 3 bytes. Can be memorized by.

In addition, a storage area (3 bytes) corresponding to the total number of payouts when the continuous accessory is operated for a total of 15 sets (6000 games) is provided (“F070” to “F06E”). This storage area is a storage area for storing 15 sets, that is, a value corresponding to the number of payouts between 6000 games.
Assuming that 15 medals are paid out in each game in 6000 games, the value corresponding to the number of payouts is "90000 (D)", which is 24 digits in binary, so it is 3 bytes. It is memorable.

For example, up to the first 15th set, "F070" to "F06E" store the value corresponding to the number of payouts when the continuous accessory is operated in the number of games less than 6000 games. Then, when the 6000th game is reached, the value corresponding to the number of payouts between the 400 games is stored in all the buffers of the 01st set to the 15th set (3 bytes each). In addition, the total number of payouts for 15 sets (6000 games) when the continuous accessory is activated is the total value for 6000 games.
Then, when the game shifts to the 6001 game, the 3-byte data ("F043" to "F041") of the 01st set is cleared, and the number of payouts in this buffer when the continuous characters from the 6001 game to the 6400 game are operated. Memorize the corresponding value. From the 6000th game to the 6399th game, the value corresponding to the number of payouts when the continuous accessory is operated, which is the total of 15 sets, is maintained unchanged.

Then, when it becomes the 6400th game and the 3-byte data of the 01st set is confirmed, the value corresponding to the number of payouts when the continuous accessory is operated for the total of 15 sets is calculated (each 3-byte data from the 01st set to the 15th set is calculated. Addition), update the value corresponding to the number of payouts when the continuous accessory is activated, which is the total of the calculated 15 sets.

Similarly to the above, after the 6401 game, when the game shifts to the 6401 game, the 3-byte data ("F046" to "F044") of the 02nd set is cleared, and the 6401 game to the 6800 game are stored in this buffer. Until, the 3 byte data of the 02nd set is updated.
In the above method, the value corresponding to the number of continuous payouts for 15 sets when the bonus is operated is updated every 400 games, but when all 15 sets are replaced with new data, the total of 15 sets is continuous. The value corresponding to the number of payouts when the accessory is activated may be calculated and updated.

The cumulative number of continuous bonus payouts (“F074” to “F071”) is a storage area for storing the cumulative total of the continuous payouts when the bonuses are operating, and the cumulative number of payouts is calculated. Is for calculating the continuous accessory operation ratio when the number of games is 175,000 or more. However, the cumulative value corresponding to the number of payouts when the continuous accessory is operated continues to be stored even after 175,000 games have passed, and the update is terminated when the storage capacity of 4 bytes reaches the upper limit value (4 bytes full).
Assuming that 15 medals are continuously paid out for each game, the game "1500 (D)" is continuously added, so that up to about 2.86 million games can be stored with 4 bytes.

Further, the continuous bonus operation ratio (6000 games) (“F075”) is the value corresponding to the number of payouts during continuous bonus operation of 6000 games (“F070” to “F06E”) / the total number of payouts of 6000 games (FIG. 28). Among them, it is a buffer for storing the values of "F031" to "F02F").

In addition, the continuous accessory operation ratio (cumulative) (“F076”) is the “cumulative value corresponding to the number of continuous accessories paid out (“F074” to “F071”) / cumulative total number of payouts (“F034” in FIG. 28). It is a buffer that stores the values of "to" F032 ").
Since the above ratio stores up to the maximum value "100 (D)" in decimal, it can be stored in 1 byte.
The continuous bonus operating ratio (6000 games) and the continuous bonus operating ratio (cumulative) can be updated every game, but for example, when there is a request to display these ratios, a calculation is performed. , The calculation result may be stored in each storage area (“F075” or “F076”), and the value may be displayed.

FIG. 30 is a diagram showing a buffer for storing data relating to the number of payouts of the accessory in the RWM 53. As is clear from the comparison between FIGS. 30 and 29, a buffer for storing the payout number-corresponding value of the accessory is provided as well as a buffer for storing the payout number-corresponding value of the continuous accessory. The buffer that stores the value corresponding to the number of payouts of the accessory has the same configuration as the buffer that stores the value corresponding to the number of payouts of the continuous accessory.

That is, for every 400 games, the storage area for 15 sets that can store each 3-byte data as the value corresponding to the number of payouts when the bonus is activated, and the value corresponding to the total number of payouts when the bonus is activated for 6000 games (15 sets). It is provided with a 3-byte buffer for storing and a 4-byte buffer for storing the value corresponding to the total number of payouts when the accessory is activated. Further, there are two types of buffers (1 byte) for storing the accessory operation ratio, one for 6000 games and the other for cumulative use.
Since the storage method in each of these buffers is the same as when the continuous accessory is operated, the description thereof will be omitted.

Since the continuous accessory corresponds to 1BB (including RB) of the present embodiment, if a medal is paid out during the operation of 1BB, it is stored in the value corresponding to the number of continuous accessories paid out when the continuous accessory is operated.
Further, when the medals are paid out during the operation of all the bonuses including the continuous bonus, the bonus is stored in the value corresponding to the number of payouts when the bonus is activated as shown in FIG.
Here, in the present embodiment, only 1BB (and RB), which is a continuous accessory, is provided as the accessory. Therefore, in such a case, the value stored in the buffer shown in FIG. 29 and FIG. 30 The value stored in the buffer shown in is the same value.

FIG. 31 is a diagram showing a modified example of the ring buffer, and in this example, a modified example of FIG. 29 is shown.
In FIG. 29, a ring buffer composed of 3 bytes for each of the 01st to 15th sets was provided, and the total value of the 15 sets was stored.
On the other hand, in the example of FIG. 31, the point of calculating the total value of 15 sets is the same as that of FIG. 29, but 16 sets are provided as the ring buffer.

In FIG. 31, the points corresponding to the number of payouts are stored in each of 3 bytes of 01 set to 15 sets from the first game to the 6000th game, which is the same as in FIG. 29.
Here, when it is desired to calculate the value corresponding to the total number of payouts from the first game to the 6000th game, each 3-byte data from 01 set to 15 sets is added and calculated.

Next, the value corresponding to the number of payouts from the 6001st game to the 6400th game is stored in the 16th set 3-byte buffer ("F070" to "F06E").
Then, when it comes to the 6401th game, the 3-byte data ("F043" to "F041") of the 01st set is cleared, and the value corresponding to the number of payouts from the 6401th game to the 6800th game is converted into the 3-byte data of the 01 set. I will remember.

When calculating the total payout number corresponding value of 6000 games (15 sets) between the 6401th game to the 6800th game, the calculation is made by adding the 3-byte data of each of the 02 sets to 16 sets.
Further, when the 6800th game is reached, the total payout number corresponding value of the 6000 games (15 sets) is calculated by adding 3 byte data of each of 1 set to 15 sets.
In this way, the 3-byte buffer of any one of the 16 sets is used as the 3-byte buffer currently being updated, and the other 15 sets of 3-byte buffers are used to calculate the value corresponding to the total number of payouts of the 15 sets. Used when doing.

The data stored in the storage area of the RWM 53 shown in FIGS. 27 to 30 is not initialized only by turning on / off the power switch 11, and the data is maintained.
Further, even when the predetermined storage area is initialized (when the RAM is cleared) when the setting is changed, the storage area of the RWM 53 shown in FIGS. 27 to 30 is an exception to the initialization, and the data is maintained without being initialized. NS. Here, in order to shift to the setting change mode, it is based on turning on the power switch 11 in the situation where the setting key switch 12 is turned on (rotated 90 degrees to the right) when the power switch 11 is off. Can be migrated. Further, the initialization of the predetermined storage area at the time of changing the setting described above is executed before the set value can be changed (setting change mode) based on the operation of the setting switch 13.

However, when an unrecoverable error occurs, the above data is initialized when the error is recovered. On the other hand, when a recoverable error occurs, the above data is not initialized and is maintained.
Here, the "unrecoverable error" refers to a serious error that cannot be recovered unless the power is turned off and the operation for shifting to the setting change mode described above is performed. for example,
1) When the read setting value is not within the range of settings 1 to 6 (setting value abnormality)
2) When a symbol that should not be displayed (kicking symbol) is displayed as a result of determining the stop symbol (symbol combination error)
3) Random number update error determined for each interrupt process,
4) For example, when the power failure / recovery data is not a normal value.

When an irreversible error occurs, the power switch 11 is turned off, the setting key is inserted and rotated 90 degrees clockwise to turn on the setting key switch 12, and then the power switch 11 is turned on. As a result, the predetermined range of RWM53 (data of each buffer of FIGS. 27 to 30, set value information, RT information, winning condition device information) is cleared. Then, the set value is set, and if there is no other error, the return process is performed.

On the other hand, the “recoverable error” refers to an error that can be recovered without turning on / off the power switch 11. For example, a medal jam error, a medal retention error, a medal illegal passage error, an abnormality of the passage sensor 43a, an abnormality of the insertion sensor 44, an abnormality of the payout sensor 37, an abnormality of the medal insertion error, and the like can be mentioned.
When a recoverable error occurs, the error content is displayed and the main process is stopped. However, when the hall clerk executes the error canceling operation (removes the error cause) and operates the reset switch 14, is the error cleared? When it is determined whether or not the error has been cleared, the process is restarted.

Next, the update processing of the value corresponding to the number of advantageous section games and the total number of games will be described. In the flowcharts of FIGS. 32 to 37 below, the value corresponding to the number of advantageous section games is abbreviated as the “value corresponding to the advantageous section”.
FIG. 32 is an example of updating the value corresponding to the number of advantageous section games and the total number of games using the register. 33 is a flowchart showing a specific example 1 of a portion surrounded by a dotted line in FIG. 32, FIG. 34 is a flowchart showing a specific example 2 of the portion surrounded by the dotted line, and FIG. 35 is a flowchart showing the specific example 2 of the portion surrounded by the dotted line. It is a flowchart which shows the specific example 3 of a part. Further, FIG. 36 is an example of updating the value corresponding to the number of advantageous section games and the total number of games without using the register.

FIG. 32 is executed at each game, for example, at the end of the game. Further, in the method using registers, in the chip of the present embodiment, A, B, C, D, E, H, and L registers (7 registers) can be used at the time of calculation. In particular, since the value corresponding to the number of advantageous section games ("F004" to "F001") is 4 bytes and the total number of games ("F007" to "F005") is 3 bytes, the total is 7 bytes and can be used. The number of registers and the number of bytes match.

In FIG. 32, in step S101, the upper 1 byte of the total number of games played (data of “F007” in FIG. 27) is set in the A register. In the next step S102, the lower 2 bytes of the total number of games played (data of "F006" and "F005" in FIG. 27) are set in the DE register.
Further, in step S103, the upper 2 bytes (data of "F004" and "F003" in FIG. 27) corresponding to the number of advantageous section games are set in the BC register. In the next step S104, the lower 2 bytes (data of "F002" and "F001" in FIG. 27) corresponding to the number of advantageous section games are set in the HL register.

In step S105, "1" is added to the lower 2-byte register of the total number of games played, that is, the DE register value in this example. In the next step S106, it is determined whether or not the lower 2 bytes of the total number of games have overflowed by adding "1" in step S105. For example, when the lower 2 bytes of data are "FFFF (H)" before the start of this flowchart, digit overflow occurs due to the addition of "1" in step S105 (flag register (F register) built in the main CPU 55). ) Carry flag is "1"). When it is determined that the digit overflow has occurred, the process proceeds to step S107, and when it is determined that the digit overflow does not occur (carry flag ≠ “1”), the process proceeds to step S109. Since it is determined in step S106 whether or not a digit overflow has occurred after adding "1" in step S105, the DE register value at the time of the digit overflow is "0" at the time of step S106. ".
In the present embodiment, the "0" bit of the F register (flag register) is set as the carry flag. The carry flag is a flag that becomes "1" when a carry occurs or a carry (also referred to as overflow) occurs due to an operation using a register.

In step S107, "1" is added to the upper 1-byte register of the total number of games played, that is, the A register value in this example. In the next step S108, it is determined whether or not the total number of games has reached the upper limit. Here, the "upper limit" means the upper limit of the count. Since the total number of games of this embodiment is counted by 3 bytes, when the total number of games is 3 bytes, specifically when the value becomes "FFFFFF (H)", no further addition is possible. , Judge that the upper limit has been reached. After adding "1" to the A register value in step S107, it is determined that the upper limit has been reached when the A register value actually overflows (when the carry flag = "1"). be. It can also be rephrased as when the A register value becomes "0" (when the zero flag = "1"). When it is determined that the upper limit has been reached, the process according to this flowchart is terminated, and when it is determined that the upper limit has not been reached, the process proceeds to step S109.

Therefore, when the total number of games of the present embodiment is 3 bytes full, and when the total number of games is about 16.78 million in decimal, the total number of games is not added any more. However, even when the 3 bytes are full, the flow of FIG. 32 is executed every game, but it is determined as "Yes" in each game, step S108, and this flowchart ends.

Proceeding from step S106 or step S108 to step S109, it is determined whether or not the game is in the advantageous section this time. By providing an advantageous section flag that is turned on during the advantageous section and determining whether the advantageous section flag is on / off, it is possible to determine whether or not the game is an advantageous section this time. Further, in the present embodiment, as described above, it is possible to determine whether or not the segment data of the digit 2 is in the advantageous section by determining whether or not the eighth bit is "1". Is.
If it is determined in step S109 that the advantageous section is in progress, the process proceeds to step S110, and if it is determined that the advantageous section is not in progress, the value corresponding to the number of games in the advantageous section is not updated and the process proceeds to step S114.

In step S110, "100 (D)" is added to the lower 2-byte register value of the value corresponding to the number of advantageous section games, that is, the HL register value in this example. Then, the process proceeds to step S111, and it is determined whether or not an overflow has occurred. In the present embodiment, "100 (D)" is added in increments of "100 (D)" during the advantageous section, so that the overflow occurs in 2 bytes in "FFDC (H) (65500 (D))" and "100 (D)". ) ”Is added to give“ 0040 (H) (65600 (D)) ”. When it is determined that the digit overflow has occurred, the process proceeds to step S112, and when it is determined that the digit overflow has not occurred, the process proceeds to step S113.

In step S112, "1" is added to the upper 2-byte register of the value corresponding to the number of advantageous section games, that is, the BC register in this example. Then, the process proceeds to step S113, and the updated BC register value and HL register value are written in "F004" to "F001" in FIG. 27. As a result, the value corresponding to the number of advantageous section games (RWM53) is updated. Further, in the next step S114, the updated A register value and DE register value are written in "F007" to "F005" in FIG. 27. As a result, the total number of games (RWM53) is updated. Then, the process according to this flowchart is completed.

In the flowchart of FIG. 32, the value corresponding to the number of advantageous section games does not reach 4 bytes full before the total number of games reaches 3 bytes full. As described above, the total number of games can be counted as about 16.78 million, but even if the total number of games is assumed to be an advantageous section and the value of about 16.78 million is multiplied by 100, This is because it does not reach 4 bytes full. Therefore, in step S112, even if "1" is added to the upper 2-byte register value of the value corresponding to the number of advantageous section games, correct arithmetic processing can be realized without determining whether or not an overflow has occurred. At the same time, it becomes possible to realize simplification of arithmetic processing.

Further, in the flowchart of FIG. 32, each data of the RWM 53 is set (copied) in the register and the calculation is executed. When it is determined in step S108 that the total number of games has reached the upper limit, the total number of games is set. The process according to this flowchart ends without returning the set register value to RWM53. Therefore, the total number of games stored in the RWM53, that is, the 3-byte data stored in "F007" to "F005" of the RWM53 remains "FFFFFF (H)", and the RWM53 before and after the start of this flowchart. There is no change in the total number of games played.

Next, in FIG. 32, a specific example of the processing of steps S109 to S114 will be described.
FIG. 33 is a flowchart showing a specific example 1 of the steps during this period. In FIG. 33, steps S109 to S112 are the same as in FIG. 32. In FIG. 33, when it is determined as "No" in step S109, the process proceeds to step S123.

When the process proceeds to step S121 after step S112, the value of the upper two bytes of the value corresponding to the number of advantageous section games is updated. Specifically, the value of the BC register is written in "F004" and "F003" in FIG. 27. In the next step S122, the value of the lower two bytes of the value corresponding to the number of advantageous section games is updated. Specifically, the value of the HL register is written in "F002" and "F001" in FIG. 27.
Next, when the process proceeds to step S123, the total number of games is updated for 3 bytes at a time. Specifically, the A register value and the DE register value are written in "F007", "F006", and "F005" in FIG. 27, respectively.

FIG. 34 is a flowchart showing a specific example 2 of steps S109 to S114 of FIG. In FIG. 34, steps S109 to S112 are the same as in FIG. 32. In FIG. 33, when it is determined as "No" in step S109, the process proceeds to step S123.
When the process proceeds to step S131 after step S112, the value corresponding to the number of advantageous section games is updated in a batch for 4 bytes. Specifically, the BC register value and the HL register value are written in "F004", "F003", "F002", and "F001" in FIG. 27, respectively. Then, when the process proceeds to step S123, the total number of games is updated for 3 bytes at a time, as in the case of Specific Example 1.

FIG. 35 is a flowchart showing a specific example 3 of steps S109 to S114 of FIG. In FIG. 35, when “No” is determined in step S109, the process proceeds to step S141.
Each step in FIG. 35 is the same as in FIG. 34. In FIG. 35, the difference from FIG. 34 is that even when it is determined in step S109 that the player is not in the advantageous section, the process proceeds to step S131 and the value corresponding to the number of games in the advantageous section is updated. That is, in this case, the value corresponding to the number of advantageous section games is not added by "100 (D)", but is based on the BC register value and the HL register value set in steps S103 and S104 in FIG. , In FIG. 27, write in "F004", "F003", "F002", and "F001". In this case, the same value as in the previous game is written again.

The above examples of FIGS. 32 to 35 are examples of updating the total number of games and the value corresponding to the number of advantageous section games via the register (using).
On the other hand, FIG. 36 is an example of updating the total number of games and the value corresponding to the number of advantageous section games without going through the register in principle.
In FIG. 36, in step S201, “1” is added to the lower 2 bytes of the total number of games played. Specifically, in FIG. 27, "1" is added to the data of "F006" and "F005".

In the next step S202, it is determined whether or not an overflow has occurred in the addition in step S201. That is, by adding "1" to the data of "F006" and "F005", it is determined whether or not the carry flag has become "1". It should be noted that the determination may be made based on whether or not the data of "F006" and "F005" is "0000 (H)". When it is determined that the digit overflow has occurred, the process proceeds to step S203, and when it is determined that the digit overflow has not occurred, the process proceeds to step S207.

In step S203, "1" is added to the upper 1 byte of the total number of games played. Specifically, in FIG. 27, "1" is added to the data of "F007". In the next step S204, it is determined whether or not the total number of games has reached the upper limit. The judgment here is that by adding "1" in step S203, it is determined whether or not "F007" overflows and the carry flag becomes "1", and the carry flag becomes "1". When it is, it is judged that the upper limit has been reached. It should be noted that it may be determined whether or not the data of "F007" is "0 (H)", and when it is "0 (H)", it may be determined that the upper limit has been reached. When it is determined that the upper limit has been reached, the process proceeds to step S205, and when it is determined that the upper limit has not been reached, the process proceeds to step S207.

In step S205, "1" is subtracted from the upper 1 byte of the total number of games played. When the process proceeds to step S205, an overflow occurs in the upper 1 byte in the addition of step S203, which is "0 (H)". Therefore, by subtracting "1" from this value, step S203 is performed. The data before adding "1", that is, "FF (H)" is restored.
Next, the process proceeds to step S206, and "1" is also subtracted for the lower 2 bytes of the total number of games played. As a result, the values of "F006" and "F005" become "FFFF (H)". Then, the process according to this flowchart is completed.

On the other hand, when the process proceeds from step S202 or step S204 to step S207, it is determined whether or not the game is in the advantageous section this time. This determination is the same as in step S109 of FIG. Then, when it is determined that the player is not in the advantageous section, it is not necessary to update the value corresponding to the number of games in the advantageous section, so that the process according to this flowchart is terminated. On the other hand, when it is determined that the section is in the advantageous section, the process proceeds to step S208. In step S208, "100 (D)" is added to the lower two bytes of the value corresponding to the number of advantageous section games, that is, "F002" and "F001" in FIG. 27. Here, since the assembler cannot directly add the value of "100 (D)" to the RWM53, first, the data of "F002" and "F001" are stored in the HL register. Then, the data of "F002" and "F001" is updated by storing the result of adding the value of "100 (D)" to the HL register in "F002" and "F001".

In the next step S209, in the calculation of step S208, it is determined whether or not an overflow has occurred. Here, it is determined whether or not the carry flag is "1", and when the carry flag is "1", it is determined that an overflow has occurred.

When it is determined in step S209 that overflow has occurred, the process proceeds to step S210, and when it is determined that overflow has not occurred, the process according to this flowchart ends. In step S210, "1" is added to the upper two bytes of the value corresponding to the number of advantageous section games, that is, "F004" and "F003" in FIG. 27. Then, the process according to this flowchart is completed.

Next, the calculation process of the advantageous section ratio will be described.
In the present embodiment, the total number of games and the value corresponding to the number of advantageous section games are stored. Therefore, in order to calculate the advantageous section ratio, simply "value corresponding to the number of advantageous section games ÷ total number of games" is used. Can be calculated. However, in the slot machine 10, a chip that satisfies the rule can only perform an operation with 2 bytes, and cannot perform division of a numerical value of 2 bytes or more. Therefore, the ratio is calculated by the subtraction shown below.

Specifically, when the value corresponding to the number of advantageous section games = x and the total number of games = y, “x ÷ y” can be calculated by repeating the following subtraction.
xy = a (> 0)
a-y = b (> 0)
by = c (> 0)
cy = d (<0)
In this way, as a result of repeating the subtraction of the total number of games y, the number of times that "> 0 (greater than" 0 ")" is "3", so the quotient of "x ÷ y" is "3". It can be calculated that there is. Then, in the present embodiment, since the numbers after the decimal point are rounded down, the advantageous section ratio is calculated as "3" in the above example.

FIG. 37 is a flowchart showing the calculation processing of the advantageous section ratio.
First, in step S301, the data of RWM53 is acquired in the register. In the same manner as above, seven A, B, C, D, E, H, and L registers are used.
In this step S301, each data of “F001” to “F007” shown in FIG. 27 is stored in the register. Specifically, it is as follows.
A register: Stores the data of "F007" D register: Stores the data of "F006" E register: Stores the data of "F005" B register: Stores the data of "F004" C register: Stores the data of "F003" H register: Stores the data of "F002" L register: Stores the data of "F001"

Next, the process proceeds to step S302, and the advantageous section ratio (RWM53) is initialized. This process clears (sets to "0") the data stored in "F008" in FIG. 27.
Then, the process proceeds to step S303, and the lower byte is subtracted. In this process, the data stored in the DE register (lower 2 bytes of the total number of games) is subtracted from the data stored in the HL register (lower 2 bytes of the value corresponding to the number of advantageous section games), and the calculation result is obtained. Stored in the HL register.

Next, the process proceeds to step S304, and it is determined whether or not a carry has occurred. When the carry flag is not set (when the carry flag ≠ "1") as a result of the operation in step S303 (the result of subtracting the DE register value from the HL register value), it is determined as "No".
When it is determined that the carry flag is set (there is a carry flag), the process proceeds to step S305, and when it is determined that there is no carry flag, the process proceeds to step S307.

In step S305, it is determined whether or not the upper 2 bytes of the value corresponding to the number of advantageous section games, that is, the BC register value is “0”. When it is "0", the subsequent subtraction cannot be performed, so the process according to this flowchart is terminated. On the other hand, when it is determined that the value is not "0", the process proceeds to step S306.
In step S306, "1" is subtracted from the upper byte of the value corresponding to the number of advantageous section games. Specifically, "1" is subtracted from the BC register value, and the calculation result is stored in the BC register.

In the next step S307, the high-order byte is subtracted. Specifically, the A register value (the upper 1 byte of the total number of games) is subtracted from the BC register value (the upper 2 bytes of the value corresponding to the number of advantageous section games), and the calculation result is stored in the BC register. Then, the process proceeds to step S308, and it is determined whether the calculation result in step S307 is less than "0", that is, whether the carry flag is set by the calculation in step S307. When the carry flag is set, it is determined as "Yes" in step S308, and no further subtraction is possible, so the process according to this flowchart is terminated. On the other hand, when it is determined as "No" in step S308, the process proceeds to step S309.
In step S309, the HL register value is stored in the stack area (a part of the storage area of the RWM 53).

In the next step S310, the data (advantageous section ratio) stored in "F008" is stored in the HL register, and "1" is added to the data stored in the address (F008) indicated by the HL register. Then, the process proceeds to step S311, and the data stored in the stack area in step S309 is stored in the HL register. After step S311, the process returns to step S303 and the above process (subtraction) is repeated.
By the above processing, the total number of games is subtracted from the value corresponding to the number of advantageous section games, and the advantageous section ratio is added by "1" for each subtraction. Therefore, after the processing of FIG. 37, the advantageous section game count corresponding value stored in "F001" to "F007" and the advantageous section ratio calculated from the total number of games are stored in "F008".
As is clear from the above, the advantageous section ratio is added by "1" each time the processes of steps S303 to S311 in FIG. 37 are executed once. That is, the number of executions (number of repetitions) of steps S303 to S311 is the advantageous section ratio.

In the above, the quotient of the value corresponding to the number of advantageous section games (value obtained by multiplying the number of advantageous section games by 100) and the total number of games is calculated and used as the advantageous section ratio (%). By (repeating subtraction), the continuous bonus ratio (6000 games (15 sets)), the bonus ratio (6000 games (15 sets)), the continuous bonus ratio (cumulative), and the bonus ratio (cumulative) are calculated. be able to.

Specifically, the value corresponding to the number of payouts when the continuous accessory is activated for 6000 games (15 sets) (“F070” to “F06E” in FIG. 29) and the total number of payouts for 6000 games (15 sets) (in FIG. 28). , "F031" to "F02F"), by repeating the same subtraction as above, the quotient of "value corresponding to the number of payouts when the continuous accessory of 6000 games is activated / the total number of payouts of 6000 games" is calculated. The value is stored in "F075" in FIG. 29 as the continuous accessory operation ratio (6000 games).

Further, from the cumulative total number of payouts when the continuous accessory is activated (“F074” to “F071” in FIG. 29) and the cumulative total number of payouts (“F034” to “F032” in FIG. 28), “ The quotient of "cumulative value corresponding to the total number of payouts during continuous bonus operation ÷ cumulative total number of payouts" is calculated, and the value is stored in "F076" in FIG. 29 as the continuous bonus operation ratio (cumulative).

Similarly, from the value corresponding to the number of payouts when the accessory of 6000 games is activated (“F0B0” to “F0AE” in FIG. 30) and the total number of payouts of 6000 games (“F031” to “F02F” in FIG. 28). , Calculate the quotient of "value corresponding to the number of payouts when the character is activated in 6000 games / total number of payouts in 6000 games", and store the value in "F0B5" in FIG. 30 as the character operation ratio (6000 games). ..

In addition, from the cumulative total number of payouts when the accessory is activated (“F0B4” to “F0B1” in FIG. 30) and the total number of total payouts (“F034” to “F032” in FIG. 28), “cumulative total”. The quotient of "value corresponding to the number of payouts when the accessory is activated / total number of total payouts" is calculated, and the value is stored in "F0B6" in FIG. 30 as the accessory operation ratio (cumulative).

FIG. 38 shows the “advantageous section ratio”, the “continuous accessory ratio (6000 games (15 sets))”, the “character ratio (6000 games (15 sets))”, and the “continuous accessory ratio” calculated as described above. It is a figure which shows the display example of "ratio (cumulative)", "combination ratio (cumulative)". These five pieces of information are displayed according to the information type and the numerical value, and are displayed on the management information display LED 74.
The five pieces of information shown in FIG. 38 are examples, and are not limited to these pieces of information. Information other than these may be displayed, or some of the information shown in FIG. 38 may be displayed. Only information may be displayed. Further, the display is not limited to the order shown in FIG. 38, and the display order is arbitrary.

The management information is displayed as described above for the following reasons.
For gaming machines, those that meet the type test stipulated by the Fuei Law are allowed to install halls. Here, in the type test, the bonus ratio and the continuous bonus ratio when 6000 games are executed do not exceed the predetermined values (70% for the bonus ratio and 60% for the continuous bonus ratio). There are established regulations.
In addition, at the time of the type test, a document stating the average value of the character ratio and continuous character ratio of the applied gaming machine is attached (in the future, the average value will also be described for the advantageous section ratio. May be required).

In this case, the hall clerk or a third party can easily check whether or not the gaming machine installed in the hall has the same specifications as the conforming one (whether or not it is fraudulent). It is desired to.
For example, a gaming machine whose numerical value deviates from the conforming gaming machine may be different from the conforming gaming machine. In this case, the manufacturer should be requested to confirm the gaming machine. Therefore, fraud and the like can be confirmed at an early stage.
Therefore, if a function for calculating and displaying management information is provided as in the present embodiment, it becomes possible to easily and surely confirm whether or not the conforming one is matched.

In the present embodiment, when the front door of the slot machine 10 is opened (the door switch 15 is turned on by this), the setting key is inserted, and the setting key is rotated 90 degrees clockwise, the setting key switch 12 is turned on. .. In this state, so-called setting confirmation is in progress. Therefore, the set value display LED 73 displays the current set value. Since the setting is being confirmed differently from the setting being being changed, the setting value is not changed even if the setting switch 13 is operated.

Then, in the present embodiment, when the setting switch 13 is pressed once during this setting confirmation, the "advantageous section ratio" is displayed in the digits 6 to 9 in FIG. First, the digits 6 and 7 display the information type. In the example of FIG. 38, the advantageous section ratio is displayed as "U7". Further, in this example, the advantageous section ratio is assumed to be "50 (%)", and "50" is displayed on the digits 7 and 8. Therefore, "U750" is displayed on the management information display LEDs 74 (digits 6 to 9).
When displaying the numerical value of the management information, it is expressed in decimal notation.

Next, when the setting switch 13 is pressed again, "continuous accessory ratio (6000 games (15 sets))" is displayed, and "y6" is displayed as the type of this information. In this example, the ratio is "45". (%) ”Is displayed.
Further, when the setting switch 13 is pressed again, the display of "Character ratio (6000 games (15 sets))" is displayed, and "y7" is displayed as the type of this information. In this example, the ratio is "60 (%)". ) ”Is displayed.

Similarly, when the setting switch 13 is pressed again, the "continuous accessory ratio (cumulative)" is displayed, and "A6" is displayed as the type of this information. In this example, the ratio is "48 (%)". it's shown.
Similarly, when the setting switch 13 is pressed again, the "role ratio (cumulative)" is displayed, and "A7" is displayed as the type of this information. In this example, the ratio is "52 (%)". it's shown.
Further, when the setting switch 13 is pressed again, the display returns to the initial display and the advantageous section "U750" is displayed.
Further, the display of the management information may be turned off when the setting switch 13 is not operated for a certain period of time (for example, 10 seconds). After the light is turned off, when the setting switch 13 is pressed, the first display, the advantageous section ratio "U750", is displayed.

Further, while the door switch 15 detects that the front door is open, the management information is continuously displayed (each digit 6 to 9 is continuously lit), and the door switch 15 detects that the front door is closed. At that time, the digits 6 to 9 may be turned off.
In this case, when the opening of the front door is detected by the door switch 15, the advantageous section "U750" may be displayed before the setting key switch 12 and the setting switch 13 are turned on, or the door switch 15 may be displayed. When the opening of the front door is detected, the digits 6 to 9 are not turned on, and when the setting key switch 12 and the setting switch 13 are turned on, the advantageous section "U750" may be displayed.

Further, regardless of whether or not the opening of the front door by the door switch 15 is detected, after the power switch 11 is turned on, a predetermined cycle (for example, about every 3 seconds (the number of interrupt processing is every 1500 interrupts). )), The display contents shown in FIG. 38 may be sequentially displayed on the management information display LED 74.
Here, the management information shown in FIG. 38 includes information whose ratio depends on the set value such as the continuous accessory ratio.
On the other hand, it is highly likely that the front door will be opened while the hall is open (when the player can play).
a) Error that occurs when it is determined that the medal in the hopper 35 is empty,
b) An error that occurs when it is determined that medals have accumulated in the medal selector,
c) An error that occurs when it is determined that medals have accumulated in the payout port of the hopper 35,
d) An error that occurs when the medals are full in the hopper 35 (the sub storage that is provided next to the hopper 35 and stores the medals that overflow from the hopper 35 is full) (both can be restored as described above). Errors that belong to errors) and the like.

If a person involved in the hall opens the front door when such an error occurs, the player may be able to see the management information and guess the set value. In order to eliminate such a situation, when at least one of the above errors a) to d) or at least one of the errors a) to d) occurs, the management information display LED 74 does not display the lighting. It is desirable to configure it so that it goes out. It should be noted that the present invention is not limited to the errors a) to d) described above, and it is possible to configure the management information display LED 74 not to display the lighting even when other errors occur.
In addition, when the above-mentioned non-recoverable error occurs, the credibility of the displayed management information is doubtful, and after the non-recoverable error is cleared, the data that is the basis of the displayed management information is cleared. Therefore, it is desirable not to display it.

In addition, in order to see the management information displayed on the main control board 50, the front door must be opened, and if the front door is opened, a door opening error will always occur, but it is managed by operating the above various switches. You may display the information.

Further, the above information types "U7", "y6", "y7", "A6", and "A7" are examples, and arbitrary display is performed by a two-digit alphabet, a symbol, a numerical value, or a combination thereof. be able to.
Further, in the above example, a numerical example different between the continuous bonus ratio and the bonus ratio is shown, but when only the continuous bonus is provided as in the present embodiment, the continuous bonus ratio and the bonus ratio are the same value. It becomes.

Further, in the case of performing the above display, for example, when the door switch 15 is turned on, the setting key switch 12 is turned on, and the setting switch 13 is turned on, the mode shifts to the management information display mode and "U7 (advantageous section)". Read the segment data to display "ratio)" and display it on digits 6 and 7. Specifically, if "U7" is displayed, the segment data will be "00111110 (B)" and "00100111 (B)".

Further, when displaying the numerical value, for example, if it is an advantageous section ratio, the data of “F008” in FIG. 27 described above is read and converted into segment data. When the advantageous section ratio is "50 (D)", the data stored in "F008" is "00110010". When the value is converted into segment data, it becomes "01101101 (B)" and "00111111 (B)".

Further, when displaying the advantageous section ratio, the total number of games ("F007" to "F005") is read, and it is determined whether or not the total number of games has reached "175000 (D)". When it is determined that the total number of games has not reached "175000" games, the numerical value of the advantageous section ratio is displayed in blinking. On the other hand, when it is determined that the total number of games has reached "175000", the numerical value of the advantageous section ratio is lit and displayed. In this way, the display pattern is different depending on whether or not the total number of games has reached "175,000 games".

Specific examples of blinking display include displaying in a pattern of repeating turning off and turning on at intervals of "0.5 seconds", turning off time of "0.5 seconds", and repeating lighting time of "1 second". Displaying in a pattern can be mentioned. Compared with the case where the extinguishing time and the lighting time are set to the same time, if the lighting time is longer than the extinguishing time, the display time of the management information can be lengthened and the lighting of the hall etc. is dim. Visibility can be improved even under circumstances.
Since the display pattern may be different so that it can be determined whether or not the game has reached the "175000" game, the display of the information type "U7" is not limited to blinking or lighting, for example, "U7"("U7"("" It may be displayed differently from the display (more than 175000” games), for example, “U1” (less than “175000” games). Alternatively, when the game is less than "175000", "U7" may be blinked and displayed, and the numerical value may be lit.

In the same manner as above, when displaying the continuous character ratio (6000 games) and the character ratio (6000 games), if the total number of games has not reached "6000" games, the continuous character ratio and the character ratio are displayed, respectively. The numerical value of the accessory ratio is displayed blinking. On the other hand, when the total number of games has reached "6000", the numerical values of the continuous bonus ratio and the bonus ratio are lit and displayed, respectively.
Therefore, when displaying the continuous character ratio (6000 games) and the character ratio (6000 games), the value of the total number of games (“F007” to “F005”) in FIG. 27 is set in the same manner as above. It is read, it is determined whether or not the game has reached "6000", and the display pattern is changed according to the result.

Similarly, when displaying the continuous bonus ratio (cumulative) and the bonus ratio (cumulative), if the total number of games has not reached "175000", the continuous bonus ratio (cumulative) and the bonus ratio, respectively. The numerical value of the accessory ratio (cumulative) is displayed in blinking. On the other hand, when the total number of games has reached "175000", the numerical values of the continuous bonus ratio (cumulative) and the bonus ratio (cumulative) are lit and displayed, respectively.
Therefore, when displaying the continuous bonus ratio (cumulative) and the bonus ratio (cumulative), the value of the total number of games ("F007" to "F005") in FIG. 27 is read, and the game is set to "175000". It is determined whether or not the value has been reached, and the display pattern is changed according to the result.

In particular, by displaying the advantageous section ratio, the continuous bonus ratio, and the bonus ratio in a discriminable manner as to whether or not the number of games is 6000 or more and whether or not the number of games is 175,000 or more (different display modes, etc.). , Has the following merits.
For example, when determining whether or not a gaming machine is an illegal gaming machine based on the currently displayed advantageous section ratio, continuous bonus ratio, and bonus ratio management information, how many times the management information is played. By referring to whether or not the value is for, it becomes possible to more accurately determine whether or not the gaming machine is an illegal game machine.

For example, it is assumed that the design value (average value) of the advantageous section ratio was 55 (%) at the time of applying for the model of the gaming machine.
At this time, for example, when the advantageous section ratio in 1000 games is 80 (%) and when the advantageous section ratio is 80 (%) in 175,000 games or more, the judgment as to whether or not it is illegal is different. .. It is quite possible that the value of the advantageous section ratio in 1000 games has not yet converged. On the other hand, since the advantageous section ratio in 175,000 games is a value with respect to a sufficient number of games, it is considered that the values have converged. Therefore, it can be determined that the latter is more likely to be fraudulent.

In this way, even if the values are the same, the greater the number of games played, the more the numerical value converges to the design value. You can make more accurate judgments.
As described above, when the total number of games has not reached the predetermined number of games (6000 games or 175000 games), the blinking display is displayed, and when the total number of games is reached, the lighting display is displayed. On the contrary, when the total number of games has not reached the predetermined number of games, the display may be lit, and when the total number of games has been reached, the display may be blinking.

Further, in the above example, the digits 6 to 9 are mounted on the main control board 50 and the management information display LED 74 is provided. However, for example, the management information may be displayed by using the storage number display LED 76 or the acquisition number display LED 78. It is possible. With this setting, it is not necessary to separately provide digits 6 to 9, which results in cost reduction.

FIG. 39 is a diagram showing an example of displaying management information using the storage number display LED 76.
The example of FIG. 39 shows an example of having nine medals as credits. Therefore, at first, the display of the stored number display LED 76 is "09".
Then, even if the front door is opened and the door switch 15 is turned on, the display of the stored number display LED 76 is not changed (because the door open error is displayed by the acquired number display LED 78, which will be described later).

Then, when the setting switch 13 is pressed once, the storage number display LED 76 displays "U7" indicating that it is an advantageous section ratio. Then, when a certain time (for example, 2 seconds) has elapsed, "50", which is a numerical value of the advantageous section ratio, is displayed. If this state is left unattended, "U7" and "50" are alternately displayed every 2 seconds.

Then, when the setting switch 13 is pressed next time, the stored number display LED 76 displays "y6" indicating that the "continuous accessory ratio (6000 games)". Then, when the above-mentioned fixed time elapses, the numerical value "45" of the "continuous accessory ratio (6000 games)" is displayed. Then, in the same manner as described above, if this state is left unattended, "y6" and "45" are alternately displayed every 2 seconds.
In the example of FIG. 39, the arrow is shown so as to shift from the display of "50" to the display of "y6", but even if the setting switch 13 is pressed while the display of "U7" is displayed, the display of "y6" is displayed. Of course, (the same is true for other figures).

Further, when the setting switch 13 is pressed while "y6" or "45" is being displayed, the storage number display LED 76 displays "y7" indicating that the "character ratio (6000 games)" is displayed. When the above-mentioned fixed time elapses, the numerical value "60" of the "role ratio (6000 games)" is displayed. Then, in the same manner as described above, if this state is left unattended, "y7" and "60" are alternately displayed every 2 seconds.

Furthermore, when the setting switch 13 is pressed while "y7" or "60" is being displayed, the storage number display LED 76 displays "A6" indicating that it is the "continuous accessory ratio (cumulative)". , When the above-mentioned fixed time elapses, the numerical value "48" of the "continuous accessory ratio (cumulative)" is displayed. Then, in the same manner as described above, if this state is left unattended, "A6" and "48" are alternately displayed every 2 seconds.
Similarly, when the setting switch 13 is pressed while "A6" or "48" is being displayed, the storage number display LED 76 displays "A7" indicating that it is the "role ratio (cumulative)". , When the above-mentioned fixed time elapses, the numerical value "52" of the "role ratio (cumulative)" is displayed. Then, in the same manner as described above, if this state is left unattended, "A7" and "52" are alternately displayed every 2 seconds.

Further, when the setting switch 13 is further pressed in this state, the display returns to the initial display of the advantageous section ratios “U7” and “50”.
When the front door is closed and the door switch 13 is turned off during the above display, the display switches to the storage number display "09".

FIG. 40 is a diagram showing an example of displaying management information using the acquired number display LED 78.
In the example of FIG. 40, an example in which "09" is displayed as the number of acquisitions is shown.
Then, when the front door is opened and the door switch 15 is turned on, a door open error is detected. As a result, "dE" indicating a door open error is displayed on the acquired number display LED 78. In this state, when the setting switch 13 is pressed once, the acquired number display LED 78 displays "U7" indicating that it is an advantageous section ratio. Then, when a certain time (for example, 2 seconds) has elapsed, "50", which is a numerical value of the advantageous section ratio, is displayed. If this state is left unattended, "U7" and "50" are alternately displayed every 2 seconds.

After that, as in the example of FIG. 39, each time the setting switch 13 is operated, predetermined management information (information type and numerical value) is displayed. Next, when the front door is closed and the door switch 15 is turned off, the error content "dE" is displayed again (the door open error cannot be resolved simply by closing the front door). Then, in order to eliminate this error display, an error canceling operation is performed. For example, the error is cleared by inserting the door key into the keyhole provided in the front door and turning the door key counterclockwise, for example. When the error canceling operation is performed in this way, the acquired number "09" before the "dE" is displayed is displayed again on the acquired number display LED 78.

In the examples of FIGS. 39 and 40, when the continuous bonus ratio (6000 games) and the bonus ratio (6000 games) are less than the total number of games "6000", at least one of the information type and the numerical value is blinked. indicate. Similarly, when the continuous bonus ratio (cumulative) and the bonus ratio (cumulative) are less than the total number of games "175000", at least one of the information type and the numerical value is blinked and displayed.

<Second Embodiment>
Subsequently, the second embodiment of the present invention will be described.
In the second embodiment, the management information display LED 74 (digits 6 to 9) mounted on the main control board 50 (main control board 50B in the case of being divided into the main control boards 50A and 50B) is always used. , It is in the lit state.
There are various ways to display the five pieces of information shown in FIG. 38 when the lights are turned on all the time. For example, the management information to be displayed may be updated every 5 seconds. Specifically, "U750" (displayed for 5 seconds) → "y645" (displayed for 5 seconds) → ... "A752" (displayed for 5 seconds) → "U750" (displayed for 5 seconds) → ... Can be mentioned. A digit extinguishing time of about 0.5 to 1 second may be provided between each information display.

FIG. 41 is an external perspective view showing the base portion 1 of the slot machine 10. In FIG. 41, the front door is not shown. The front door opens / closes the front surface of the base portion 1 with the “front door opening / closing shaft” (left side in the drawing) as a support shaft in FIG. 41. Further, although FIG. 41 is used in the description of the second embodiment, the structure of the first embodiment is also the same as that of FIG. 41.
As shown in FIG. 41, a power supply unit including a power switch 11, a medal payout device including a hopper 35, a symbol display device including three reels 31, and the like are housed inside the base portion 1.
Further, the sub-control board 80 is attached to the left side surface of the base unit 1 on the inner surface side. On the other hand, the substrate case 16 and the main control substrate 50 housed therein are attached to the back surface inside the inner surface of the substrate portion 1. Furthermore, the board case 16 and the main control board 50 are attached above the symbol display device so that the state of the crimped portion 16a of the board case 16 can be easily visually confirmed when the front door is opened. Therefore, it is attached to a relatively easy-to-see position in the substrate portion 1.
Therefore, the management information display LED 74 mounted on the main control board 50 can also be visually confirmed relatively easily.

In the specifications of the slot machine 10, in addition to the method in which medals are automatically replenished to the hopper 35a when the medals in the hopper 35 are exhausted, the clerk in the hall opens the front door every time the medals in the hopper 35 are exhausted. Then, a method of supplying medals to the hopper 35 is known.
However, when the front door is opened, the management information display LED 74 mounted on the main control board 50 always displays the management information, so that the player can see the management information. .. As a result, it is possible to know the ratio of advantageous sections of the platform currently being played, the ratio of continuous characters, and the like. Therefore, there is a possibility that the set value can be estimated based on these values.
Therefore, in the second embodiment, the management information display LED 74 mounted on the main control board 50 constantly displays the management information, but is not easily visible to the player.

FIG. 42 is a diagram showing the substrate case 16 and the main control substrate 50 (50A and 50B) in the second embodiment, and is a diagram corresponding to FIG. 3 in the first embodiment. In FIG. 42, Example 1 of (a) shows an example in which the main control board 50 is composed of one, and Example 2 of (b) is composed of two main control boards 50A and 50B. An example is shown (this point is the same as FIG. 3 of the first embodiment).
FIG. 42A is different from the first embodiment in that the management information display LED 74 is arranged as close to the left side as possible when viewed from the front of the main control board 50. In FIG. 41, the opening / closing shaft of the front door is provided on the left side when viewed from the front in the drawing. Therefore, if the management information display LED 74 is arranged as far to the left as possible when viewed from the front, even if the front door is opened. , It becomes difficult for the player to see.

Further, in the example of FIG. 3B, the arrangement of the main control boards 50A and 50B was reversed from that of FIG. 3B. The management information display LED 74 is mounted on the main control board 50B, but is located on the left side in the board case 16.

Furthermore, in the second embodiment, the distance (distance) between the management information display LED 74 and the caulking portion 16a is increased. Assuming that the position of the management information display LED 74 is to the left in FIG. 42, when the caulking portion 16a of the board case 16 is moved away from the management information display LED 74, as shown in FIG. 42 (the same applies to FIG. 3), the caulking portion 16a Is the right end portion of the substrate case 16.
In this way, even when the caulking portion 16a is destroyed to access the main control boards 50 (50A and 50B), the management information display LED 74 is damaged or damaged when the caulking portion 16a is destroyed. It can be prevented more effectively.

Further, the caulking portion 16a is for breaking when the board case 16 is opened, but in addition to the caulking portion 16a, a main body caulking portion (not shown) for fixing the gaming machine and the board case 16 is provided. You may have it. At this time, when removing the board case 16 from the gaming machine, it is necessary to destroy the crimped portion of the main body as well. In this case as well, as in the case of the crimped portion 16a, the position where the crimped portion of the main body is provided is the first position in order to prevent the management information display LED 74 from being accidentally damaged or damaged when the crimped portion of the main body is destroyed. When it is a position (for example, the upper end of the board case 16), the position where the management information display LED 74 is provided is a second position away from the first position (for example, a lower part and a right side with reference to the central part of the main control board 50). It is desirable to provide it in the square or left side).

As described above, by arranging the management information display LED 74 in a position direction different from the position direction in which the caulking portion 16a and / or the main body caulking portion is provided, damage to the management information display LED 74 can be effectively prevented. can.
Although the position of the crimped portion 16a is the right end portion, the position is not limited to this, and for example, it can be designed as the upper end portion. At this time, since the management information display LED 74 is a lower portion, a right portion, or a left portion with reference to the central portion of the main control board 50, the management information display LED 74 is erroneously damaged when the caulking portion 16a is destroyed. It can be prevented from being damaged or damaged.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications such as the following are possible.
(1) The upper limit of the number of games in the advantageous section is set to 1500, but the number is not limited to this, for example, the number of payouts is 3000, the difference is 2000, and the instruction function operating game (when the small role B group is won). It is also possible to set using a variable other than the total number of games, such as 100 games. Alternatively, it is also possible to set a plurality of conditions such as 1500 games or 3000 cards, and when any one of them is satisfied, it is determined that the upper limit has been reached.

(2) The advantageous section display LED 77 uses the segment DP of the stored number display LED 76, but the present invention is not limited to this, and a dedicated display (LED or the like) for displaying whether or not the advantageous section is displayed may be provided. However, if the existing LED can be used as in the above embodiment, the cost can be reduced.
Here, the advantageous section is managed by the main control board 50 (main management), and the sub control board 80 does not manage the advantageous section. Therefore, the lamp displaying the advantageous section needs to be electrically connected to the main control board 50. For example, the effect lamp 21 electrically connected to the sub control board 80 displays the advantageous section. It cannot be a lamp.
However, even if the lamp looks as if it is a kind of effect lamp, if it is a lamp controlled by the main control board 50, it can be used as a lamp for displaying an advantageous section.

Further, the advantageous section display LED 77 is composed of the segment DP of the digit 2 of the stored number display LEDs 76, but may be composed of the segment DP of the digit 4 of the acquired number display LEDs 78, for example.

Furthermore, when the player ends the game, the menu button 25 may be operated in order to display the game history (two-dimensional code). Therefore, if the advantageous section display LED is arranged in the vicinity of the menu button 25, the player can be made aware that the advantageous section is in progress at the end of the game. For example, even if the storage number display LED76 (the segment DP of the digit 2 is designated as the advantageous section display LED77) and the acquired number display LED78 (the segment DP of the digit 4 is designated as the advantageous section display LED77) are arranged near the menu button 25. good. Of course, as shown in FIG. 2, it is also effective to provide the advantageous section display LED 77 in the vicinity of the settlement switch 46. Further, when it is decided to shift to the advantageous section, the menu button 25 is turned on before the menu button 25 can be operated, so that the player does not notice the shift to the advantageous section. It is possible to prevent the operation (displaying the game history (two-dimensional code)).

(3) When the power switch 11 is turned off while the advantageous section display LED 77 is lit, and the power switch 11 is turned on again, the advantageous section control means 69 turns the power on / off. In order to maintain the advantageous section before and after, the advantageous section display LED 77 is turned on again. Therefore, for example, when the store is closed with the advantageous section display LED 77 lit in the hall, or when the advantageous section display LED 77 is to be turned off at the start of business the next day, the setting is changed (including resetting the same set value). Can be mentioned. By changing the setting, the predetermined area of the RWM53 is initialized, and the display data (data of the advantageous section) of the storage number display LED76 is also initialized. Therefore, in the segment data of the digit 2, the 8th bit is also "0". ".

(4) During the advantageous section, the instruction function is activated in the game in which the condition device capable of operating the instruction function is won. However, not limited to this, it is not always necessary to activate the instruction function even in the game in which the condition device capable of operating the instruction function is won in the advantageous section. The advantageous section is a game section in which the instruction function can be operated. Therefore, after shifting to the advantageous section, whether or not to execute the instruction function operating game and the number of games of the instruction function operating game are determined by lottery or the like, and the instruction function operating game is executed only for the determined number of games. May be good. Then, even if the number of games is completed, if the continuation condition of the advantageous section is satisfied, it is possible to continue staying in the advantageous section and determine the number of games to execute the instruction function operating game again by lottery or the like. Is. Furthermore, during the advantageous section, the lottery to fall from the advantageous section to the normal section is based on winning each game or a specific condition device (for example, a common setting such as a single winning of a small winning combination D or a small winning combination E1). To decide.

(5) In the present embodiment, the value corresponding to the number of advantageous section games is stored as a value obtained by multiplying the number of games by 100. Similarly, the value corresponding to the number of payouts when the continuous accessory is operated and the value corresponding to the number of payouts when the accessory is operating are stored as values obtained by multiplying the number of payouts by 100, respectively. However, not limited to this, depending on the calculation method (CPU used) of the advantageous section ratio, the continuous accessory ratio, and the accessory ratio, it is possible to store the number of games itself and the number of payouts themselves without multiplying by 100. Therefore, it is not always limited to storing a value multiplied by 100.
Similarly, the value of the total number of games is not limited to the number of games itself, but is not limited to this, and depending on the convenience of calculation, a value obtained by adding a predetermined number to the total number of games or a value obtained by multiplying a predetermined value (total number of games). The value corresponding to the number of times) may be stored.
In this case, when the advantageous section ratio, the continuous bonus ratio, and the bonus ratio are calculated, the calculation of multiplying the data in the storage area in which the number of games itself and the number of payouts itself is stored by 100 and repeatedly executing the subtraction process described above. It can be calculated by executing the process (for example, FIG. 37).

(6) The advantageous section ratio, the continuous accessory operation ratio, and the accessory operation ratio are calculated for each game or a predetermined number of games regardless of whether or not the management information is displayed, and are stored in a predetermined area of the RWM 53, respectively. You may leave it. On the other hand, the advantageous section ratio, the continuous accessory operation ratio, and the accessory operation ratio are calculated when the management information is displayed (when there is a display request), the calculation result is stored in a predetermined area of the RWM53, and the calculation is performed. The result may be displayed.

(7) In the above embodiment, the management information is displayed in order each time the setting switch 13 is pressed. However, the setting switch 13 is not limited to the setting switch 13, and other switches such as the bet switch 40 may be used, or a switch dedicated to displaying management information may be separately provided.
Further, in the present embodiment, the setting switch 13 and the reset switch 14 are provided separately, but it is conceivable that the setting switch and the reset switch are composed of one switch as the setting change / reset switch. In this case, if the operation of the setting change / reset switch does not overlap with the reset (initialization) operation, the management information can be displayed by the operation of the setting change / reset switch. The same applies to the case where the setting switch 13 and the reset switch 14 are provided separately as in the present embodiment, and the management information is displayed by operating the reset switch 14.

Specifically, when an error is detected, the mode does not shift to the management information display mode, and the mode shifts to the management information display mode on condition that no error has occurred.
For example, if a medal retention error occurs in the medal selector among the recoverable errors, the mode does not shift to the management information display mode unless the error is removed.

Further, in the above embodiment, the management information is displayed each time the setting switch 13 is pressed. That is, even if the operator releases the operation switch 13 after turning on the setting switch 13, the management information remains displayed. On the other hand, the management information may be displayed only while the setting switch 13 is pressed, and the display of the management information may be terminated when the operator releases the setting switch 13. For example, in the example shown in FIG. 3, when the setting switch 13 is pressed first, the first management information "U750" is displayed, but when the setting switch 13 is released, the display ends (digits 6 to 6). Turn off 9). Next, when the setting switch 13 is pressed, the second management information "y645" is displayed, but when the setting switch 13 is released, the display can be controlled to end. When the switch for displaying the management information is a switch other than the setting switch 13, the same control as described above is possible.

In this way, there are various variations in which switch is used to display the management information and how the relationship between the operation of the switch displaying the management information and the display pattern (displaying time) is set. However, the present invention is not limited to the one shown in the present embodiment.
Furthermore, for example, when the management information display LED 74 is mounted on the main control board 50, the management information display pattern may be
a) Display pattern that constantly displays management information b) Pattern that displays management information when the front door is opened (when the door switch 15 is turned on) c) The front door is opened and a predetermined switch Pattern that displays management information when you operate d) Open the front door, insert the setting key to turn on the setting key switch 12, and display management information when you operate a predetermined switch. Be done.
However, when the operation to shift to the setting change mode is performed and the setting shift mode is entered, the shift to the management information display mode is not performed and the management information is not displayed. That is, in the setting change mode, the digits 5 are turned on, but the digits 6 to 9 are turned off.

(8) In the present embodiment, the total number of games is counted until the total number of games is counted to 3 bytes full (“FFFFFF (H)”). However, the present invention is not limited to this, and for example, when the cumulative total reaches a predetermined value, the counting may be terminated even if the upper limit of the storage capacity has not been reached.
Further, when the total number of games reaches a predetermined value, the data value of the total number of games may be cleared and the total number of games may be counted again.
The same applies to the total number of payouts.

(9) The slot machine 10 of the present embodiment is designed so that the advantageous section ratio is "70" (%) or less. Therefore, it is not assumed that the ratio of advantageous sections will exceed "70" (%) in the market. However, it cannot be denied that the ratio of advantageous sections may exceed "70" (%), for example, when a goto act is performed. Therefore, for example, the data value of "F008" that stores the advantageous section ratio is monitored, and when the value exceeds "70 (D)", some warning is output or the advantageous section ratio is displayed. It is possible to make it different from the normal time (display that it is abnormal). For example, among the display of the information type "U7" of the advantageous section ratio, a method of alternately blinking the upper digit "U" and the lower digit "7" at high speed can be mentioned.

Similarly, regarding the continuous accessory ratio and the accessory ratio, when the design value upper limit is set to, for example, "60 (%)", and the continuous accessory ratio or the accessory ratio exceeds the design value upper limit, something is done. Examples include a method of outputting a warning and displaying the information type display in the same manner as above.
Alternatively, the external signal transmitting means 70 may be used to transmit information such as the advantageous section ratio to the hall computer 200, and for example, when the advantageous section ratio exceeds "70" (%), the information related to the warning may be transmitted. Can be mentioned.

(10) As described above, if the advantageous section ratio is set to be "70" (%) or less with respect to all the game sections, the others can be set relatively freely.
In addition, winning from the normal section to the advantageous section may be set to less than "1/32".
Furthermore, as described above, during the advantageous section, the instruction function may be activated whenever the condition device capable of operating the instruction function is won, but the instruction function is not activated only by shifting to the advantageous section, and the instruction is instructed. When the lottery for whether or not to activate the function is won, the instruction function may be activated. Alternatively, when shifting to an advantageous section, whether to make it an advantageous section in which the instruction function is always activated, or whether to make it an advantageous section in which the instruction function is activated only when the lottery for whether to activate the instruction function is won. , May be decided by lottery or the like.

Further, the transition from the advantageous section to the normal section (end of the advantageous section) may be made when the predetermined number of games is exhausted at the time of transition to the advantageous section, or the number of games may not be determined. , Every game, or when a predetermined condition is satisfied, a lottery for shifting (falling) from an advantageous section to a normal section may be performed, and when this lottery is won, the section may be shifted from the advantageous section to the normal section. However, when the count value reaches the upper limit by the upper limit counter 69b, it is unconditionally controlled so as to end the advantageous section and shift to the normal section.

(11) In FIG. 3, the management information display LED 74 provided on the main control board 50 is composed of four digits, but may be composed of, for example, two digits. Then, for example, as shown in the examples of FIGS. 39 and 40, when the setting switch 13 is pressed, the information type "U7" is displayed, the numerical value "50" is displayed after the lapse of a predetermined time, and then the predetermined time. "U7" and "50" may be alternately and repeatedly displayed each time.

(12) The advantageous section ratio, the continuous accessory ratio, and the accessory ratio are not always displayed with accurate values because the calculation is performed by rounding down the decimal point. In that sense, the advantageous section ratio, the continuous bonus ratio, and the bonus ratio correspond to the advantageous section ratio (equivalent), the continuous bonus ratio (equivalent), and the bonus ratio, respectively. ) Also referred to as the value to be.
In addition, the advantageous section ratio, continuous bonus ratio, and bonus ratio are not limited to the numbers rounded down to the nearest whole number, the numbers rounded down to the nearest whole number, the numbers rounded up to the nearest whole number, and the last digit is "5" or " It may be a numerical value converted in increments of "10".

(13) In the present embodiment, the combination of symbols that stop at the effective line is the same when the small winning combination E1 is won and when the small winning combination E2 is won. For example, when the small winning combination E1 or E2 is won, the middle-tier cherry can be stopped (winning the small winning combination 36) at the left or middle first stop, and the middle-tier cherry does not appear at the right first stop. (Small role 38 prize). Therefore, it was not possible to determine whether the small winning combination E1 or E2 was won regardless of the appearance of the middle cherry.
However, the present invention is not limited to this, and for example, when the middle cherry is not made to appear, the stop result may be different instead.
For example, when the small winning combination E1 or E2 is won, the middle cherry is made to appear when the left or middle first stop is made, and when the middle cherry appears, the player determines whether the small winning combination E1 or E2 is won. Make it impossible.

On the other hand, when the small winning combination E1 or E2 is won, when the right first stop is made, the middle-tier cherry is controlled so as not to appear as described above, and instead of not causing the middle-tier cherry to appear, the small winning combination E1 or E2 It is possible to make a stop roll that allows the player to judge which one is won.

Specifically, for example, the following control can be mentioned.
First, the small winning combinations included in the winning of the small winning combination E1 are the small winning combinations 36 and 38, as in the above embodiment.
On the other hand, the small wins included in the winning of the small win E2 are the small wins 36 and 41 (the small win 41 is newly added).
Then, the small winning combination 36 (middle-tier cherry) can be stopped at the time of the left or middle first stop at the time of winning the small winning combination E1 or E2, and the small winning combination 38 is stopped at the time of the right first stop at the time of winning the small winning combination E1. On the other hand, the small winning combination 41 is stopped at the first right stop when the small winning combination E2 is won.

The combination of the symbols of the small winning combination 41 is, for example, "bell A / bell B"-"replay"-"black 7 / blue 7 / red 7 / blank". As a result, the design of the middle reel 31 is different between when the small winning combination 38 is stopped and when the small winning combination 41 is stopped. When the small winning combination 38 is stopped, the "replay" does not stop on the middle reel 31, but when the small winning combination 41 is stopped, the "replay" always stops on the middle reel 31. Thereby, the winning of the small winning combination 38 (small winning combination E1) or the small winning combination 41 (small winning combination E2) can be determined.

Further, regardless of the pressing order of the stop switch 42, the small winning combination 38 is stopped when the middle cherry is not stopped when the small winning combination E1 is won, and the small winning combination 41 is stopped when the middle cherry is not stopped when the small winning combination E2 is won. You may. In this way, it is possible to determine whether the player has won the small winning combination E1 or the small winning combination E2 when the middle-stage cherry is not stopped, even when the left or middle first stop is made.

In addition, for example, the following method can be mentioned.
The small winning combination included in the winning of the small winning combination E1 is the small winning combination 36 and 38 as in the above embodiment. Further, the small winning combination included in the winning of the small winning combination E2 is also the small winning combination 36, the small winning combination 37 and 38, as in the above embodiment. The small winning combination 36 (middle cherry) can be stopped at the time of the left or middle first stop when the small winning combination E1 or E2 is won, and the small winning combination 38 is changed by the operation timing of the stop switch 42 at the time of the right first stop when the small winning combination E1 is won. The small winning combination 38 is stopped according to the operation timing of the stop switch 42 at the time of the first right stop when the small winning combination E2 is won.
Then, when the small winning combination 38 is missed when the small winning combination E1 or E2 is won, the combination of different symbols is stopped. As a result, it may be possible to determine whether the small winning combination E1 or E2 has been won.

(14) When 1BBA + small winning combination E1 is won and the advantageous section display LED 77 is turned on by the time when the predetermined timing of the next game arrives, the effect (continuous effect, etc.) of whether or not to shift to the advantageous section is not output. Is preferable. This is because the advantageous section display LED 77 is lit, so that the player knows that he / she has shifted to the advantageous section. However, it is possible to output the continuous production of whether or not 1BBA (special role) has been won. Further, when 1BBA + small winning combination E1 is won and it is decided to shift to the advantageous section, the advantageous section display LED 77 is not always turned on even after a predetermined timing has passed (always shown in the figure). At the timing 2) shown in 23, the advantageous section display LED 77 is turned on by the time the predetermined timing of the next game of the game in which the small winning combination E1 has won is reached, so that the small winning combination E1 is independently elected and the advantageous section is entered. Since it can be seen that it has been decided to shift, in such a case, it is not necessary to output an effect that encourages whether or not the player has won 1BB.

(15) In the present embodiment, when the push order is incorrect when the small winning combination B group is won, one winning combination can be won. However, not limited to this, the number of small wins that can be won when the push order is incorrect at the time of winning the small win B group may be any number of coins. Further, the omission rate at the time of incorrect answer of the push order at the time of winning the small winning combination B group is 75% in this embodiment, but is not limited to this, and various settings such as 50% can be set.
Further, even when the push order is incorrect when the small winning combination C is won, it is possible to set the winning combination to be missed with a certain probability as in the case where the small winning combination B is won.

(16) In the above embodiment, during 1BBA operation, the number of games (expected value) of setting 6 is increased with respect to setting 1, and it is advantageous when, for example, the number of games during 1BBA operation reaches a predetermined number. Added the section.
However, contrary to the above, during 1BBA operation, the winning probability of the small winning combination A of the setting 6 is increased and the winning probability of the small winning combination E2 is lowered with respect to the setting 1, so that the game with the setting 6 is smaller. It may be the number of times (expected value). In this case, for example, when the operation of 1BBA is completed with a small number of games (setting 6 is easier to achieve than setting 1), it is possible to add an advantageous section.

(17) In the present embodiment, when it is decided to shift to an advantageous section at the time of a single winning of a conditional device that does not include a special combination that can carry over the winning, for example, a small winning combination E1, it is advantageous by a predetermined timing. It was decided to turn on the section display LED 77. Here, the "predetermined timing" is not limited to the timing shown in the above embodiment, and can be set in various ways. For example, in the game when the small winning combination E1 is won, when the winning determination is completed, when the medal is paid out in the game, when the medal payout is finished, and the like can be mentioned.

Further, although it does not occur in the present embodiment, for example, when the replay decides to shift to the advantageous section in the winning game, the automatic bet ends based on the winning of the replay, or the game starts in the next game (replay). When the switch 41 is operated, the advantageous section display LED 77 may be turned on.

(18) At the time of winning "1BBA + small winning combination E1", if the stop switch 42 is operated at the left or middle first stop, the small winning combination 36 can be won, so that the middle cherry can appear. However, when the winning flag is only the small winning combination E1, the middle-tier cherry can appear, and when the winning flag of 1BBA is also set, the middle-tier cherry does not appear in any push order (all small winning combination 38 is won). The stop control may be performed as follows.
When controlled in this way, there is a demerit that the player cannot be fanned by displaying the middle cherry even when it is decided to shift to the advantageous section when "1BBA + small winning combination E1" is won.

On the other hand, even when the small winning combination E1 is independently won after being inside the 1BBA, the standing winning flag is "1BBA + small winning combination E1", so that the same stop control as described above can be adopted.
As mentioned above, it is not possible to decide the transition to the advantageous section inside, so even if the player wins the small role E1 and the middle cherry appears after knowing that the player is inside, the player will not be able to decide. , I get the impression that I wasted money. On the other hand, if the stop control as described above is performed, the middle-stage cherry does not appear at all inside, so that the player does not have to give the impression that he / she has made a wasteful pull.

In particular, as a combination of the symbols of the small role 38, there are "bell A / bell B"-"cherry"-"black 7 / blue 7 / red 7 / blank" (FIG. 11). It is similar to the symbol 02 "bell A / bell B"-"cherry"-"bell A / bell B". Therefore, by making the combination of the above symbols of the small winning combination 38 appear, it is possible to make it appear to be missed when the small winning combination B group is won (do not show it as a rare role).
The above is the same when "1BBA + small role E2" is won, when the small role E1 is won alone after being inside 1BBB, or when the small role E2 is won alone after being inside 1BBB. Is.

(19) As shown in FIG. 17, the winning probability of the replay is the same (the number is "8978") between the non-RT and the RT1. However, the present invention is not limited to this, and the winning probability of the RT1 replay may be set higher than the winning probability of the non-RT replay.

(20) In the present embodiment, after the 1BBB operation is completed, the transition to RT1 is performed, a lottery for replay E is performed at RT1, and an advantageous section is added by winning the replay E. However, the present invention is not limited to this, and when the player shifts to RT1 during the advantageous section, the advantageous section can be set in the additional special zone (a state in which the frequency of addition is high and the number of additional games is large). Then, the pattern symbol is displayed, the addition special zone is continued until the transition to RT2, and every time a predetermined condition is satisfied in this RT1 (not limited to the winning of Replay E), the addition of the advantageous section is executed. May be good.

(21) In the present embodiment, the RT after the end of the 1BBA operation is set to non-RT, and the RT after the end of the 1BBB operation is set to RT1. However, instead of migrating to different RTs in this way, they may be migrated to the same RT. For example, it may be shifted to non-RT after 1BBB operation is completed. In this case, after the 1BBB operation in the advantageous section is completed, the advantageous section may be added and set as a special zone.

(22) In the present embodiment, the advantageous section ratio (cumulative), continuous bonus ratio (6000 games and cumulative total), and bonus ratio (6000 games and cumulative total) are displayed as management information, but other than these. It is also possible to calculate and display management information, such as the payout rate.
Examples of the method of calculating the payout rate include the following methods.
a) "Total number of payouts x 100" / "Total number of games excluding replays after winning a replay"
b) "(Total number of payouts + number of replay prizes x 3) x 100" ÷ "total number of games played"
Then, when a) is adopted, each buffer for storing "total number of payouts x 100" and "total number of games excluding replays after winning the replay" is provided. Further, when b) is adopted, a buffer for storing "(total number of payouts + number of replay winnings x 3) x 100" is provided. It should be noted that buffers of "total number of payouts x 100" and "number of replay winnings x 300" may be provided separately, and the values of both may be added.

In addition, "3" of "replay winning number of times x 3" means the number of bets of the game when a replay wins. For example, when the number of bets fluctuates depending on the game state, etc., the bet number is not limited to "3", but is the value bet on the game when the replay wins (for example, "2" or "1"). There may be a game to play.
In addition, it has a storage area that stores the total number of games, the total number of payouts, and the number of replay wins (may be "the number of replay wins x the value bet on the game when the replay wins"), and the payout rate can be determined. When calculating, the value may be multiplied by 100 before calculation.

Further, as the calculation methods of a) and b), a method of repeating subtraction is adopted in the same manner as the above-mentioned calculation method.
Then, by displaying the payout rate as one of the management information and comparing it with the design payout rate, it is possible to determine whether or not the machine is an illegal gaming machine. Further, also in this case, if the lighting mode is different depending on whether or not the total number of games is 6000 games or more and 175,000 games or more, whether or not the gaming machine is more accurately illegal. It becomes possible to judge whether or not.
The display of the information type indicating the payout rate may be any display as long as it can be distinguished from other management information. For example, digit 6 is displayed as "P." and digits 7 to 9 are displayed. The payout rate (three-digit number) can be displayed using.

(23) In the present embodiment, it has been explained that the upper limit counter 69b may be a decrement counter and an increment counter. Here, adopting an increment counter for the upper limit counter 69b has the following merits.
When the count value of the upper limit counter 69b reaches the upper limit value, for example, when the count value becomes "1500" in the case of an increment counter, various parameters related to the advantageous section (stored in RWM53) are stored in order to forcibly terminate the advantageous section. Initialize the value). Examples of the parameters to be initialized include an advantageous section counter 69a, an upper limit counter 69b, and the number of games of the instruction function operating game (when the instruction function is activated when the small winning combination B group is won). Then, "0" is optimal as the value at the time of initialization. Further, it is preferable that the addresses of the RWM 53 for storing the parameters to be initialized are continuous. Specifically, for example, "F100", "F101", "F102", ...

This is simple because it can be initialized by repeating the process of inserting "0" into the address of the RWM53 within the predetermined range while shifting the address by one, similar to the initialization process of the RWM53 accompanying the setting change. This is because it can be executed by the converted process. It should be noted that the parameters that are cleared with the advantageous section as the upper limit value are initialized even when the setting is changed.
The address of the RWM53 that stores the parameters to be initialized is assigned with regularity (for example, "F100", "F102", "F104", ...), And "0" is assigned to the address. Even when the process of inserting is initialized by repeatedly shifting the address by a predetermined value (“2” in the above case), the process can be simplified.

Here, when the upper limit counter 69b is a decrement counter and the count value is "0", it means that it is "0" due to the initialization, or the advantageous section is the upper limit value (1500 games). ) And "0" cannot be determined from the count value. Therefore, when determining whether or not it is the upper limit of the advantageous section based on the count value of the upper limit counter 69b, the count value of the upper limit counter 69b and the data indicating whether or not it is an advantageous section (in a predetermined area of RWM53). Must be done based on (remembered).
On the other hand, when the upper limit counter 69b is an increment counter, the count value of the upper limit counter 69b is read, and if it is "1500", it can be determined that it is the upper limit of the advantageous section. That is, it is possible to determine whether or not it is the upper limit only by the count value of the upper limit counter 69b.

(24) The update of the data of RWM53 shown in FIGS. 27 to 30 and the processing of FIGS. 32, 36, and 37 are executed at the end of each game, more specifically, after the winning determination processing. ..
On the other hand, in the second embodiment, the management information such as the advantageous section ratio is always displayed, so that the same management information (for example, the advantageous section ratio) may be displayed a plurality of times in one game, for example. ..
Then, it is conceivable to calculate the advantageous section ratio and the like each time when displaying.
From the above, the same management information (for example, advantageous section ratio) may be calculated multiple times in one game.
(25) The above-described embodiment and various modifications are not limited to being carried out alone, but can be carried out in combination as appropriate.

Subsequently, the third and subsequent embodiments of the present invention will be described.
In the third and subsequent embodiments, the meanings of the terms are as follows.
The “instructed game section” refers to a game section in which the instruction function operating game is always executed or the execution frequency is increased in a game having an advantageous operation mode of the stop switch in the advantageous section.
The "instructed game section" is similar to the conventional AT (abbreviation of "assist time". When the AT is executed in the RT having a high probability of winning the replay, it is "ART"). In the following description, the "instructed game section" will be referred to as "AT" as necessary.

"Always execute the instruction function operating game" means a game having an advantageous operation mode of the stop switch, specifically, when the replay group B of the embodiment is won, when the replay C group is won, and when the small winning combination B group is won. , And when the small winning combination C group is won, it means that the instruction function is always activated.
Since the AT of the present embodiment is executed at RT3 (high probability of replay) in principle, it is "ART" in principle, but it may fall to RT2 due to an operation error of the stop switch of the player. Even if it falls from RT3 to RT2, AT is continued. Furthermore, AT may be executed even at RTs other than RT3 and RT2. Therefore, an AT at an RT that does not have a high replay probability such as RT3 is not strictly "ART". Further, when the RT3 has fallen to RT2 during AT, the correct answer pressing order is displayed by the operation of the instruction function in order to return to RT3 by activating the instruction function when the replay B group is won.

On the other hand, "increased execution frequency" means that, for example, when the small winning combination B group is won or the small winning combination C group is won, the instruction function is not activated at "100%", for example, the instruction function is activated at 95%. It is a concept that includes such cases.
As will be described later, during the instructional game period, when the small winning combination B group is won, a lottery is performed to determine whether or not to activate the instruction function, and when this lottery is won, it is conceivable to activate the instruction function. In such a case, since it does not mean that the instruction function is always activated, it is stipulated that the execution frequency is increased.

As described above, the instruction game section is a game section in which the instruction function operation game is executed, and therefore, as a premise, it is necessary to be an advantageous section. Therefore, the designated game section is always an advantageous section, and the designated game section is a normal section or a waiting section (hereinafter, the normal section and the waiting section may be collectively referred to as a “non-advantageous section”). There is no.
In addition, the start and end of the designated game section can be arbitrarily set. For example, the designated game section may be started at the same time as the start of the advantageous section. Alternatively, even if the advantageous section is started, the designated game section is not started immediately, but the designated game section is started when the start condition of the designated game section is satisfied in the advantageous section.

Furthermore, the end condition of the designated game section may be determined at the start of the designated game section, or may not be determined at the start of the designated game section.
When the end condition of the designated game section is determined by the start of the designated game section, the designated game section may be extended after the designated game section is started.
Here, various parameters (variables) for determining the designated game section can be mentioned. For example, first, the end condition of the designated game section may be set by the number of games. Specifically, at the start of the designated game section, the number of games in the designated game section may be set to, for example, "50" games or "100" games.

Secondly, the end condition of the designated game section is set by the number of payouts. If it is set in this way, the end condition will be the same as that of the special game. Specifically, the end condition of the designated game section may be set to, for example, "the number of payouts exceeds 300".

Furthermore, the third is to set the end condition of the designated game section by the difference number of sheets. Specifically, the end condition of the designated game section may be set to "the difference number exceeds 200".
Fourth, the end condition of the instruction game section is set by the number of times the instruction function is operated at the time of winning the small combination B group and the small combination C group (may be only the small combination B group). Specifically, in a game in which the end condition of the instruction function section is set to "the number of times the instruction function is operated 50 times when the small combination B group and the small combination C group are won", and the number of times the instruction function is operated is 50 times. The end of the designated game section can be mentioned.

In the designated game section defined as described above, when the designated game section is extended, the parameters defining the designated game section are changed (also referred to as "extension", "addition", and "addition").
For example, in the designated game section of 100 games, when the designated game section is extended to the 50th game and the number of games is increased by 30 games, the remaining number of games in the designated game section is changed from 50 games to 80 games. Be changed.
Similarly to the above, when the designated game section is set by the number of payouts, the difference number, or the number of times the designated function is operated, when the designated game section is extended, the value to be added to these parameters is determined, and the remaining parameters are determined. Add (add) the added value.

Further, the indicated game section (AT) may be started and ended based on the transition of the game state.
Here, as the "game state", in addition to the RT (lottery state) described above, a control state controlled by the main control board 50 can be mentioned. That is, the gaming state is a concept including both a lottery state and a control state.
Further, the "control state" is a gaming state that can be determined independently of RT (as will be described later, there may be a control state linked to RT).
Examples of the control state include concepts such as precursor, CZ (abbreviation of "chance zone"), AT, and normal. More specifically, as the control state performed in the advantageous section, a state in which the transition probability to the instruction game section (AT) is high (high probability state), a state in which the transition probability to the instruction game section (AT) is low (low probability state), or a state in which the instruction game section (AT) is performed. Examples of the control state include various control states in consideration of game playability, such as a state in which the additional winning probability of the indicated game section (AT) is high (additional special zone, etc.) and a state in which the additional winning probability is low.
The control state of the normal section is normal, and the control state of the advantageous section is precursor, CZ, or AT.

For example, at the same time as the transition to the advantageous section, the control state is changed from "normal" to "precursor". This precursor has a case of transition (promotion) to CZ and a case of transition (fall) to normal. When the transition condition to CZ is satisfied in the omen, the transition to CZ is performed, and when the transition condition to normal is satisfied, the transition to normal is performed.
In addition, when it shifts to CZ, it has a case of shifting to AT (promotion) and a case of shifting to precursory or normal (falling). In CZ, when the transition condition to AT is satisfied, the transition to AT is performed, and when the transition condition to precursor or normal is satisfied, the transition to precursor or normal is performed, respectively.

In addition, in this embodiment, in the case of transition to AT, when the same RT transition (FIG. 22) as in the first embodiment is performed, control is performed so that the RT3 stays. For example, when it is decided to shift to AT in RT2, when the replay B group is won, the correct answer pressing order for shifting to RT3 by the operation of the instruction function is displayed. Further, after the transition to RT3, in order to prevent the player from falling from RT3, the correct answer pressing order for maintaining RT3 by the operation of the instruction function is displayed at the time of winning the replay C group.

Further, for example, a finite RT may be provided, and the AT may be used while staying at the finite RT. In this case, the AT ends when the finite RT shifts to another RT.
The "finite RT" means staying in the RT until the predetermined number of games is exhausted, and when the predetermined number of games is exhausted, the end condition of the RT is satisfied and the player shifts to another RT.
For example, when shifting to a finite RT after the end of a special game, it is possible to execute AT at this finite RT. Then, when the predetermined number of games is exhausted by the finite RT, the game shifts to the RT corresponding to the normal section, and the AT, that is, the indicated game section and the advantageous section are ended.
Further, as in the first embodiment, in the case where the special combination is won and the transition to RT4 (internal middle RT) is performed, for example, when the special combination in the finite RT is won, the RT transition may be performed. In this case, the finite RT ends with the winning of the special combination, and after the end of the special game, it can be started from a predetermined RT (for example, the non-RT in FIG. 59) different from the finite RT.
On the other hand, in the case of the specification that does not shift to RT by winning the special role, even if the special role is won during the finite RT, the finite RT is not ended, and after the special game is finished, it has been executed until then. It can be restarted from the middle of the finite RT.

Further, since the precursor and the CZ are executed in the advantageous section, the instruction function can be activated in the game section. Therefore, whether or not to activate the instruction function is arbitrary, but since it is during AT that the instruction function is always or frequently operated, the instruction function is not activated as much as during AT during the precursor or CZ. During the omen or CZ, the instruction function may be activated at a small rate, or the instruction function may be activated only once. In addition, in the specification that shifts from normal to precursor with the transition from normal section to advantageous section and may fall to normal (normal section) before shifting from the precursor to CZ or AT, precursor or CZ (advantageous). It is necessary to execute the instruction function operating game at least once during the section).

In particular, when the player shifts to the advantageous section, the instruction function may be activated at the time of winning the first small winning combination B group in order to achieve "execute the instruction function operating game at least once in the advantageous section" at an early stage. ..
Further, since the AT is premised on being an advantageous section, the AT also ends when the advantageous section ends. Therefore, for example, when the number of remaining games of AT is reached and 1500 games, which is the upper limit of the advantageous section, is reached, the advantageous section and AT are terminated.

"Freeze" is to delay the progress of the game by suspending it for a predetermined period of time. For example, acceptance of medals, acceptance of operation of bet switch 40, acceptance of operation of start switch 41 and stop switch 42. This is to put the function related to (accepting the stop operation of the reel 31) into the pause state. In addition to executing such a freeze, it is possible to output various effects during this freeze period.
The freeze is executed, for example, at the end of AT. On the other hand, after the transition to the advantageous section, if only CZ is executed (when AT is not executed), the freeze is not executed. Therefore, after shifting to the advantageous section, there are cases where the freeze is executed and cases where the freeze is not executed at the end of the advantageous section.

<Third Embodiment>
The third embodiment is characterized in that the number of AT games can be added.
As described above, various AT parameters can be mentioned, but in the third embodiment, the AT end condition is determined by the number of games played.
In the third embodiment, FIGS. 43 (Example 1) to 52 (Example 10) will be described as processing on the main control board 50 side.
Further, Examples 1 (FIG. 53) and Example 2 (FIG. 54) will be described as processing on the sub-control board 80 side.
Further, in the following example, AT is started at the same time as the start of the advantageous section. Then, the advantageous section ends at the same time as the end of AT. That is, "AT = advantageous section".
However, as in the first embodiment described above and the fourth embodiment described later, it is of course possible to have an advantageous section but a non-AT period (for example, precursor, CZ, pullback period, special game, etc.). (This point will be described later).

Furthermore, the upper limit counter described in the following example corresponds to the upper limit counter 69b of the first embodiment. Further, in Examples 1 to 10 below, an AT counter, an additional counter, an advantageous section counter, and the like are provided (in all the examples, it does not mean that these three counters are always provided).
In the flowcharts of FIGS. 43 (Example 1) to 52 (Example 10), the same step numbers are assigned to the same processes. Then, the description of the same step number as the step number already described will be omitted as appropriate.
Further, the count value by the counter is abbreviated as "counter value".
Furthermore, "clearing" the counter value means initializing the counter value (setting the counter value to "0" in the increment counter).

In the third embodiment, when the condition device (condition device shown in FIG. 17) corresponding to the addition of the advantageous section in the first embodiment is won during the AT, the number of games of the AT is added. The number of games to be added may be determined in advance according to the conditional device, or the number of games to be added may be determined by lottery when the conditional device to be added is won.
For example, in FIG. 17, when a small winning combination E1 with a number of "250" is won, the number of additional games is determined to be "50" (50%), "100" (40%), or "200" (10%). To do. In addition, when the small winning combination E1 with the number of placements "750" is won, the number of additional games is determined to be "30" (50%), "50" (30%) or "100" (20%). Be done.
Further, regardless of the above example, the number of additional games of the AT may be predetermined based on the control state and the condition device, or the number of additional games of the AT may be drawn based on the control state and the condition device. good. In this case, for example, even when the same condition device is won, the number of additional games determined or lottered can be different depending on the control state during execution.

In the third embodiment, as described above, "AT = advantageous section", and as in the first embodiment, the upper limit of the advantageous section is 1500 games. Therefore, the maximum number of AT games is 1500.
Here, when starting the AT, the initial value of the number of games played by the AT is determined, and during the AT, the (remaining) number of games played by the AT is added according to the winning condition device.
When adding the number of AT games, the total number of AT games (meaning the sum of the number of digested games of AT and the number of remaining games; the same shall apply hereinafter) is unlimited regardless of whether or not it exceeds "1500". There are cases where the addition is executed and cases where the addition exceeding "1500" is not executed.
As a result of adding the number of AT games, even if the total number of AT games exceeds "1500", the number of AT games to be executed is limited to "1500".

Furthermore, when adding the number of games during AT, the method of executing the addition under the same conditions from the beginning to the end, and the closer to the upper limit of 1500 games, the more difficult it is to add (the expected value of the number of additions becomes smaller). ) Method. To give an example of the latter, when the initial value of the number of AT games is, for example, "100" and the condition device to be added is first won in a situation where the addition is not performed at all, for example, 80 The addition number "100" is selected with a probability of%, but when the total number of AT games is "1000" or more, when the same condition device as above is won, for example, an addition with a probability of 80%. This is the case when the number "50" is selected.
Even in the case of controlling in this way, there are cases where the addition is continued even if the total number of AT games exceeds "1500" and cases where the addition is stopped.
Furthermore, when the addition is continued even if the total number of AT games exceeds "1500", there is a method of storing the value even if the value exceeds "1500", and the amount exceeding "1500". For, there is a method of clearing the value.

FIG. 43 (Example 1) below is an example in which the addition is executed (added to the counter) without any limitation even if the total number of AT games exceeds "1500" (regardless of the total number of games).
Further, FIGS. 44 (2) to 46 (4) are examples in which the addition is not executed (not added to the counter) when the total number of AT games exceeds "1500". In this case, the additional lottery itself is not executed, and the additional lottery itself is executed, but after the additional lottery, it is determined whether or not the total number of AT games exceeds "1500", and if it exceeds "1500", There is a case where the additional lottery result is cleared. The latter is adopted in FIGS. 44 (Example 2) to 46 (Example 4).

If it is decided to add it, a freeze may occur. This is to generate a freeze and output an additional effect (number of games to be added, etc.) during that period.
However, if it is decided to add the number of games and the number of games is cleared because the total number of games of AT exceeds "1500" after the freeze is generated, the number of games is added even if the freeze occurs. It happens that it is not done.
Therefore, for example, after winning the condition device to be added in the game this time and performing an additional lottery, it is decided to add the additional number, and after it is confirmed that the additional number is added to the remaining number of games of the AT. For example, in the next game, there is a control that causes a freeze as well as an additional effect.

Furthermore, in FIGS. 47 (5) to 49 (7), when the total number of AT games reaches "1000" or more (that is, when the upper limit of "1500" is approached), the expected value of the additional number is reduced. This is an example of Here, when the expected value of the number of additions is reduced, the probability of winning the addition is lowered, the number of additions is reduced, and both of these are executed.

Further, in FIGS. 50 (8) to 52 (10), when the total number of AT games reaches "1000" or more (that is, when the upper limit of "1500" is approached), the winning combination (winning condition device) This is an example of lowering the grade of and performing an additional lottery. Here, "lowering the grade of the winning combination" is, for example, the following method.
As shown in the first embodiment, as shown in FIG. 17, a small winning combination E1 having a placement number of "250" and a small winning combination E1 having a placement number "750" are provided as condition devices to be added to the lottery. It is assumed that it has been done.
Here, the small winning combination E1 having the number "250" is a conditional device that is difficult to win because the number of small winning combinations E1 is smaller than that of the small winning combination E1 having the number "750". In such a case, the expected value of the additional number when winning the small winning combination E1 of the number "250" is x1, and the expected value of the additional number when winning the small winning combination E1 of the number "750" is x2 ( Let x2 <x1).
Further, as an example of changing the expected value of the number of additions, a method of providing a plurality of types of lottery tables in advance and changing the lottery table used in the addition lottery is adopted.

Then, when the total number of AT games is less than "1000", when the small winning combination E1 with the number "250" is won, an additional lottery is performed with the expected value x1 and the small winning combination E1 with the number "750" is won. At that time, an additional lottery is performed with the expected value x2.
Next, when the total number of AT games is "1000" or more, both when the small winning combination E1 with the number "250" is won and when the small winning combination E1 with the number "750" is won. An additional lottery will be held with the expected value x2.
As a result, when the small winning combination E1 with the number "250" is won, the grade is lowered to the small winning combination E1 with the number "750", and the lottery is added.

Alternatively, when the total number of AT games is "1000" or more, when the small winning combination E1 with the number "250" is won, an additional lottery is performed with the expected value x2, and the small winning combination E1 with the number "750" is assigned. If you win, you may draw an additional lottery with the expected value x3 (x3 <x2).
The expected values x1 to x3 are assumed to exceed "0", but may be, for example, "0". The additional lottery with the expected value of the additional number "0" includes, for example, setting the additional winning probability to "0", or winning the additional number "0" although the winning itself is achieved by the additional lottery. ..

Further, for example, it is assumed that the expected value of the number of additional numbers when the small winning combination E1 is won is x11, and the expected value of the number of additional numbers when the small winning combination D is won is x12 (x12 <x11).
In this case, if the total number of AT games is less than "1000", when the small winning combination E1 is won, an additional lottery is performed with the expected value x11, and when the small winning combination D is won, the additional lottery is performed with the expected value x12. ..
Next, when the total number of AT games is "1000" or more and the small winning combination E1 is won, the small winning combination D is replaced with the winning, and an additional lottery is performed with the expected value x12.
Even if the winning combination is replaced with a lower-grade winning combination in order to lower the grade of the winning combination, the winning combination itself is not changed.

Further, in the above example, the threshold value of the total number of games played by the AT in which the expected value of the additional number is changed is set to "1000", but the present invention is not limited to this, and "500", "800", and "1200". , "1300", "1400", etc., can be set in various ways according to the specifications of the slot machine.

(Example 1)
FIG. 43 is a flowchart showing Example 1 of the control process on the main control board 50 side.
First, the main control board 50 includes, as counters, an AT counter that counts the number of digested games during AT, and an upper limit counter that counts the upper limit number of games "1500" in the advantageous section.
In the third embodiment, "100" is given as an initial value (number of games) at the start of AT. Therefore, "100" is set in the AT counter at the start of AT. Then, each game is subtracted by "1" (decrement counter).

Further, the upper limit counter is set to the initial value "1500" at the start of AT. Then, each game is subtracted by "1" (decrement counter).
From the above, when the AT counter or the upper limit counter becomes "0", the end condition of AT is satisfied.
If 1BB is won during AT, the AT counter will not be updated (counting will be interrupted) until the end of the 1BB game. On the other hand, the upper limit counter is updated every game even during 1BB game. That is, since the AT counter is not updated during the internal middle game and the 1BB game, after the end of 1BB, the AT counter value at the time of winning 1BB is restarted.
Furthermore, in the first embodiment, the advantageous section flag corresponds to the 8th bit in the segment data of the digit 2, "1" is set during the advantageous section, and "0" when it is not an advantageous section. Is set.

In FIG. 43 (a), in step S401, the main control board 50 (main CPU 55) performs a command transmission process at the start of the game to the sub control board 80. This process is the process shown in (b) in the figure described later. Next, the process proceeds to step S402, and the control when the start switch 41 is operated is executed. In step S402, it continues to detect whether or not the start switch 41 has been operated, and when it is determined that the start switch 41 has been operated, the process proceeds to the next step S403.

In step S403, the internal lottery process is executed. This process is the same as the lottery of the winning combination by the winning combination lottery means 61 in the first embodiment. In the next step S404, an additional lottery is performed. Here, "addition" is an addition of the number of AT games. Therefore, when the game is not in AT (in the normal section and in the advantageous section but not in AT), the additional lottery in step S404 is not executed. The additional lottery in step S404 is the process shown in (c) in the figure.
In this embodiment, when the condition device shown in FIG. 17 of the first embodiment is won, the AT addition lottery is executed.
In addition, the number of additions and the winning probability thereof shall be determined in the lottery table described later.

Next, the process proceeds to step S405, and the main control board 50 transmits a command to the sub control board 80 when the start switch 41 is operated. This process is the process shown in (d) in the figure described later.
In the next step S406, it continues to determine whether or not all reels 31 have stopped, and when it is determined that all reels 31 have stopped, the process proceeds to step S407. In step S407, a variable update process is performed as a process at the end of the game. This process is the process shown in (e) in the figure. Then, the process according to this flowchart is completed.

Proceeding to step S401 of FIG. 43 (a), the game start command transmission process of FIG. 43 (b) is executed.
First, in step S411, the AT counter value is transmitted. In the next step S412, the upper limit counter value is transmitted. Further, in the next step S413, the value of the advantageous section flag is transmitted. As for the value of the advantageous section flag, "1" is transmitted when it is in the advantageous section, and "0" is transmitted when it is not in the advantageous section. Then, the process according to this flowchart is completed. Through the above processing, the main control board 50 transmits three parameters, an AT counter value, an upper limit counter value, and an advantageous section flag value, to the sub control board 80.

Proceeding to step S404 of FIG. 43 (a), the additional lottery of FIG. 43 (c) is executed.
First, in step S421, a lottery table is set. This lottery table is stored in the ROM 54 in advance, and determines the number of additional numbers corresponding to the winning combinations and the winning probability thereof. Specifically, for example, when the small winning combination E1 alone is won with the number "250", the probability of determining the additional number to "50" is 60%, and the probability of determining the additional number to "40" is set. It can be set to 40%. In addition, when the small winning combination E1 alone is won, the probability of determining the additional number to "30" is set to 50%, and the probability of determining the additional number to "20" is set to 50%. Can be mentioned. For other conditional devices, the winning probability and the number of additions are determined.

In the next step S422, an additional lottery is performed using the lottery table set in step S421. Then, the process proceeds to step S423, and the result of the lottery (determined number of additions) in step S422 is added to the AT counter value. For example, when the AT counter value up to that point is "50" (the number of remaining games) and the number of additions is determined to be "20", the AT counter value is updated to "70". Then, the process according to this flowchart is completed.

Proceeding to step S405 of FIG. 43 (a), the command transmission at the time of operating the start switch of FIG. 43 (d) is executed.
Here, in step S431, the AT counter value is transmitted. Then, the process according to this flowchart is completed. Therefore, the AT counter value is transmitted in step S411 at the start of the game, but the AT counter value is transmitted again in step S431. When it is not decided to add the number of AT games in the game, the same value is transmitted in step S411 and step S431.

On the other hand, when it is decided to add the number of AT games, in step S431, the updated AT counter value is transmitted. When the sub-control board 80 receives the AT counter value in step S411 and then receives the AT counter value again in step S431, the sub-control board 80 receives the AT counter value stored in the sub-control board 80 side in step S431. Rewrite to the AT counter value.
Before step S431, it is determined whether or not the AT addition has been executed in the game, and only when the AT addition is executed, the second AT counter value in the game is transmitted in step S431. May be good.

Proceeding to step S407 of FIG. 43 (a), the variable update process of FIG. 43 (e) is executed.
First, in step S441, the AT counter value is subtracted by "1". Next, the process proceeds to step S442, and the upper limit counter value is subtracted by "1". In the next step S443, it is determined whether or not the upper limit counter value is "0". When it is determined to be "0" (that is, when the number of games in the advantageous section reaches the upper limit "1500"), the process proceeds to step S445 and subsequent steps in order to end the AT and the advantageous section. On the other hand, when it is determined that the value is not "0", the process proceeds to step S444.

In step S444, it is determined whether or not the AT counter value is "0" and the number of times the instruction function operating game is executed is "1" or more. Here, when the AT counter value is "0", it means that the number of remaining games of AT is "0".
Further, in order to determine whether or not the number of times the instruction function operation game is executed is "1" or more, for example, an instruction function operation counter or an instruction function operation flag may be provided.
The instruction function operation counter can be, for example, an increment counter that adds "1" each time the instruction function is activated. If this counter value is "1" or more, the number of times the instruction function operation game is executed is It can be determined that it is "1" or more.

In addition, the instruction function activation flag is turned off when the instruction function activation game has never been executed after executing the advantageous section and AT, and is turned on (after that) when the first instruction function activation game is executed. Is a flag. When this instruction function operation flag is on, it can be determined that the number of executions of the instruction function operation game is "1" or more.

As described in the first embodiment, when the section shifts to the advantageous section, the winning combination of the instruction function operating game (the game having the advantageous pressing order of the stop switch 42 and the number of payouts is the largest) is won at least once. Game of time. In the first embodiment, the game at the time of winning the small winning combination B. The same shall apply hereinafter), the advantageous section cannot be ended. In this way, executing the instruction function operating game at least once during the advantageous section has priority over the end condition of the AT.

However, when the 1500 game, which is the upper limit of the advantageous section, is reached without executing the instruction function operating game even once, the advantageous section can be terminated (see the eleventh embodiment (FIG. 69) described later). ). Therefore, in Example 1 of FIG. 43, it is first determined in step S443 whether or not the upper limit counter value is "0", and if it is "0", the advantageous section and AT are not performed without determining step S444. I am trying to finish.

In step S444, when it is determined that "the AT counter value is" 0 "and the number of times the instruction function operating game is executed is" 1 "or more", the advantageous section and the end condition of AT are satisfied. move on. On the other hand, when it is determined as "No" in step S444, the process according to this flowchart is terminated (the next game also continues the AT and the advantageous section).

In step S445, the AT counter value is cleared (set to "0"). Next, the process proceeds to step S446, and the upper limit counter value is cleared (set to "0"). Further, the process proceeds to step S447, and the value of the advantageous section flag is cleared (set to "0"). In this way, when the advantageous section ends, it is necessary to clear (reset) all the parameters related to the advantageous section. Then, the process according to this flowchart is completed.

(Example 2)
FIG. 44 is a flowchart showing Example 2 of the control process on the main control board 50 side. In Example 2 of FIG. 44, an AT counter (initial value “100”, decrement counter), an additional counter (initial value “0”, increment counter), and an upper limit counter (initial value “1500”, decrement counter) are provided as counters. .. Further, as in Example 1, an advantageous section flag is provided.
The addition counter adds the number of additions each time the number of games is added during AT.

In FIG. 44, (a) and (b) are the same as in Example 1 of FIG. 43.
Further, in the additional lottery process of FIG. 44 (c), after the additional lottery is executed in step S422, the process proceeds to step S451 to determine whether or not the additional counter value exceeds the specified number. Here, the specified number is set to "1400". That is, when "100" is set as the initial value of the number of AT games and the number of additional games of AT reaches "1400", the total number of games of AT becomes "1500", which is the upper limit of the advantageous section. To reach. Therefore, it is set not to add more than the number of games "1400".

When it is determined in step S451 of FIG. 44 (c) that the addition counter value exceeds the specified number (“1400”), even if the addition number is determined in the lottery in step S422, the addition number is added. Instead, the process according to this flowchart is terminated.
On the other hand, in step S451, when it is determined that the addition counter value is equal to or less than the specified number, the process proceeds to step S452. In step S452, the lottery result (determined number of additions) in step S422 is added to the addition counter value. The process of the next step S423 is the same as that of Example 1 described above. From the above, for example, when the AT counter value before the addition lottery = "50", the addition counter value = "200", and the determined number of additions is "30", the AT counter value after the addition is "80", and the addition is added. The counter value is "230".

Further, in the command transmission process when the start switch is operated in FIG. 6D, the additional counter value is transmitted to the sub control board 80 in step S461. In Example 1, the AT counter value is transmitted to the sub-control board 80, but in Example 2, the additional counter value is transmitted. When the addition counter value reaches "1400", the sub-control board 80 can determine that the addition has been performed until the upper limit of the advantageous section is reached.
Furthermore, in FIG. 4E, steps S441 to S447 are the same processes as in FIG. 43 (Example 1). Further, after step S447, the process proceeds to step S471 to clear the additional counter value. This is to clear all the parameters related to the advantageous section at the end of the advantageous section.

(Example 3)
FIG. 45 is a flowchart showing Example 3 of the control process on the main control board 50 side.
In Example 3 of FIG. 45, as counters, an AT counter (an increment counter that is set to an initial value “0” and increments by “1” each time one game is exhausted) and an additional counter (initial value “100”). , Increment counter), upper limit counter (same as Example 1). Furthermore, the specified number is set to "1500", which is the maximum number of games in the advantageous section.

In FIG. 45, (a) and (b) are the same processes as in FIG. 43 (Example 1).
Further, in FIG. 3C, steps S421 and S422 are the same processes as in Example 1. After step S422, the process proceeds to step S451, and it is determined whether or not the additional counter value exceeds the specified number (“1500”). The fact that the additional counter value exceeds the specified number "1500" means that in Example 3, the total number of AT games has exceeded "1500". Therefore, when the addition counter value exceeds the specified number "1500", even if the addition number is determined in step S422, the addition number is not added and the process according to this flowchart ends. On the other hand, when it is determined in step S451 that the addition counter value is equal to or less than the specified number, the process proceeds to step S452, and the determined addition number is added to the addition counter value. Note that step S423 (addition of the number of additions to the AT counter value) shown in Example 1 of FIG. 43 is not performed. In this example 3, the AT counter is only for counting the number of games played during AT.

Further, FIG. 4D is the same process as in FIG. 44 (Example 2).
Furthermore, in the figure (e), in step S481, "1" is added to the AT counter value. During AT, the AT counter value is incremented. In the next steps S442 and S443, the same processing as in Example 1 is performed. In the next step S482, it is determined whether or not the AT counter value is equal to or greater than the additional counter value. In Example 3, when the number of AT games exceeds the number of additional games, it is determined that the end condition of the AT and the advantageous section is satisfied.

In Example 3 of FIG. 45, the initial value of the AT counter value is “0”, and the initial value of the additional counter value is “100”. Then, when the number of AT games reaches "100" without adding the number of AT games even once, the AT counter value becomes "100", the additional counter value becomes "100", and the "AT counter value". ≧ Additional counter value ”will be satisfied. If "Yes" is determined in step S482, the process proceeds to step S483. On the other hand, when it is determined as "No", the advantageous section and the end condition of the AT are not satisfied, so the process according to this flowchart is terminated.

In step S483, it is determined whether or not the number of executions of the instruction function operating game is "1" or more. When it is "1" or more, the advantageous section and the end condition of AT are satisfied, so the process proceeds to step S445. On the other hand, when it is determined that the value is not "1" or more, the process according to this flowchart is terminated in order to continue the AT and the advantageous section in the next game.
The processing after step S445 is the same processing as in FIG. 44 (Example 2).

(Example 4)
FIG. 46 is a flowchart showing Example 4 of the control process on the main control board 50 side.
In Example 4 of FIG. 46, the counters are an addition counter (an increment counter set to the initial value "100") and an advantageous section counter (set to the initial value "0", and every game during AT and the advantageous section. It is provided with an increment counter) that is incremented by "1".
In Example 4, the AT counter is not provided. The number of AT games is counted by the advantageous section counter. That is, the advantageous section counter of Example 4 has the same function as the AT counter (increment counter) of Example 3.
Further, in Example 4, the upper limit counter provided in Example 1 and the like is not provided. In Example 4, the advantageous section counter also serves as the upper limit counter. The specified number is "1500" as in Example 3.

In Example 4 of FIG. 46, (a), (c) and (d) are the same processes as in FIG. 45 (Example 3).
Further, in FIG. 3B, when step S401 is started, the advantageous section counter value is transmitted to the sub-control board 50 in step S491. Next, the process proceeds to step S413, and the value of the advantageous section flag is transmitted to the sub control board 50 in the same manner as in Example 1.

Furthermore, in the figure (e), in step S501, "1" is added to the advantageous section counter value. In the next step S502, it is determined whether or not the advantageous section counter value is "1500" or more. When it is determined that the advantageous section counter value is "1500" or more, it means that the upper limit of the advantageous section has been reached, so that the process proceeds to step S504 in order to end the advantageous section and AT. On the other hand, when it is determined that the advantageous section counter value is not "1500" or more, the process proceeds to step S503.

In step S503, it is determined whether or not the advantageous section counter value is equal to or greater than the additional counter value. Similar to step S482 of FIG. 45 (Example 3), when the advantageous section counter value becomes equal to or more than the additional counter value, it means that there is no remaining number of games of AT. If "Yes" is determined in step S503, the process proceeds to step S483, and if "No" is determined, the process according to this flowchart is terminated (the next game also continues the advantageous section and AT).
Step S483 is the same process as in FIG. 45 (Example 3). If "Yes" is determined in step S483, the process proceeds to step S504, and if "No" is determined, the process according to this flowchart is terminated.
Proceeding to step S504, the advantageous section counter value is cleared. The next steps S447 and S471 are the same processes as in FIG. 45 (Example 3).

(Example 5)
FIG. 47 is a flowchart showing Example 5 of the control process on the main control board 50 side.
In Example 5 of FIG. 47, the counters are an AT counter (a decrement counter set to an initial value “100” and subtracted by “1” during AT) and an addition counter (set to an initial value “0” and added. It is provided with an increment counter that adds an additional number for each game) and an upper limit counter (a decrement counter that is set to an initial value of "1500" and is decremented by "1" for each game during an advantageous section). Furthermore, the specified number is set to "1000".

In Example 5 of FIG. 47, (a) and (b) are the same processes as in FIG. 43 (Example 1).
Further, in the figure (c), two types of lottery tables A and B are provided when the additional number is drawn. The lottery table is not limited to two types, and three or more types (for example, ultra-high accuracy, high accuracy, normal, low accuracy, etc.) may be provided.

The lottery table A is a lottery table in which the probability that the number of AT games is added is set to a normal probability or a high probability. On the other hand, the lottery table B is a lottery table in which the probability that the number of AT games is added is set lower than that of the lottery table A.
Not limited to this, the lottery table A may have the expected value of the additional number set to x1, and the lottery table B may have the expected value of the additional number set to x2 (x2 <x1).
Further, by combining both, the lottery table A has a high probability of additional winning and the expected value of the number of additional winnings is set to medium to large, and the lottery table B has a low probability of winning additional winnings and the expected value of the number of additional winnings is set. It may be set to small.

In FIG. 3C, first, in step S511, the lottery table A is set as a standard lottery table for addition. In the next step S451, it is determined whether or not the additional counter value is equal to or greater than the specified number (“1000”). When it is determined that the additional counter value is not equal to or more than the specified number, the process proceeds to step S422, and when it is determined that the additional counter value is not equal to or more than the specified number, the process proceeds to step S512.

In step S512, the lottery table A set in step S511 is reset to the lottery table B. Then, the process proceeds to step S422. By this process, when the number of additions is less than "1000", the addition lottery is performed using the lottery table A, and when the number of additions is "1000" or more, the addition lottery is performed using the lottery table B. Therefore, the ease of addition is changed with the addition number "1000" as a threshold value.
The processing after step S422 is the same processing as in FIG. 44 (example) 2. Further, FIGS. (D) and (e) are the same processes as in FIG. 44 (Example 2).

(Example 6)
FIG. 48 is a flowchart showing Example 6 of the control process on the main control board 50 side.
In Example 6 of FIG. 48, the counters are an AT counter (an increment counter set to an initial value “0” and incremented by “1” during AT) and an addition counter (set to an initial value “100” and added. It is provided with an increment counter that adds an additional number for each game) and an upper limit counter (a decrement counter that is set to an initial value of "1500" and is decremented by "1" for each game during an advantageous section). Furthermore, the specified number is set to "1000" as in FIG. 47 (Example 5).

Comparing Example 6 of FIG. 48 with Example 5 of FIG. 47, they differ in the following points.
Since the AT counter is an increment counter having an initial value of “0” as in FIG. 45 (Example 3), the additional number is not added to the AT counter when the additional lottery is performed.
In Example 6 of FIG. 48, (a) and (b) are the same processes as in FIG. 47 (Example 5).
Further, in FIG. 48 (c), after the addition lottery in step S422, the process proceeds to step S452, the addition number is added to the addition counter value, and the process according to this flowchart ends (step S423 in FIG. 47 (Example 5)). No processing is performed).
Further, FIG. 4D is the same process as in FIG. 47 (Example 5). Furthermore, FIG. 5E is the same process as in FIG. 45 (Example 3).

(Example 7)
FIG. 49 is a flowchart showing Example 7 of the control process on the main control board 50 side.
In Example 7 of FIG. 49, the counter does not have an AT counter and is set to an additional counter (initial value “100”, and an increment that adds the number of additional counters each time it is added, as in FIG. 46 (Example 4). A counter) and an upper limit counter (an increment counter that is set to an initial value of "0" and is incremented by "1" for each game during an advantageous section) are provided. Furthermore, the specified number is set to "1000" as in FIG. 47 (Example 5).
In Example 7 of FIG. 49, the upper limit counter also serves as an AT counter (a counter that counts the number of AT games played).

In Example 7 of FIG. 49, (a), (b), and (d) are the same processes as in FIG. 46 (Example 4). Further, FIG. 4C is the same process as in FIG. 48 (Example 6).
Furthermore, in the figure (e), in step S521, "1" is added to the upper limit counter value. Next, the process proceeds to step S522, and it is determined whether or not the upper limit counter value is “1500” or more. When it is determined that the upper limit counter value is "1500" or more, the continuation upper limit of the advantageous section has been reached, so the process proceeds to step S446 in order to end the advantageous section and AT.

On the other hand, when it is determined as "No" in step S522, the process proceeds to step S523. In step S523, it is determined whether or not the upper limit counter value is equal to or greater than the additional counter value. The upper limit counter is a counter that adds "1" for each game during the advantageous section, while the addition counter is a counter that adds the number of additions with the initial value "100". Therefore, the "upper limit counter value" When “≧ additional counter value”, it means that there is no remaining number of games of AT. If "Yes" is determined in step S523, the process proceeds to step S483, and if "No" is determined, AT is continued in the next game, so that the process according to this flowchart is terminated.

In step S483, similarly to the above, it is determined whether or not the instruction function operating game has been executed one or more times, and if it is executed, the process proceeds to step S446 in order to end the advantageous section and AT. On the other hand, when it is determined as "No" in step S483, the process according to this flowchart is terminated in order to continue the AT in the next game.
The processing of steps S446, S447, and S471 is the same as that of FIG. 47 (Example 3). Then, the process according to this flowchart is completed.

(Example 8)
FIG. 50 is a flowchart showing an example 8 of control processing on the main control board 50 side.
In Example 8 of FIG. 50, the counter includes the same AT counter, additional counter, and upper limit counter as in FIG. 44 (Example 2). Further, the specified number is set to "1000" as in FIG. 47 (Example 5).
In Example 8 of FIG. 50, in the flowchart of (a), after the internal lottery in step S403, the process proceeds to step S531 and the condition device group set process is performed. The other processes in (a) are the same as those in FIG. 43 (Example 1).
Further, FIG. 4B is the same process as in FIG. 44 (Example 2).

FIG. 3C is a flowchart showing the condition device group set process in step S531.
First, in step S541, "0" is set as the condition device group number.
Here, the "conditional device group number" is a number assigned to each of the plurality of conditional devices drawn in the internal lottery by dividing the conditional devices to be added to the lottery into a plurality of groups.

In this example, two condition device group numbers, "0" and "1", are illustrated. Then, a lottery table for additional lottery is provided for each condition device group number.
Further, the lottery table corresponding to the condition device group number "0" is referred to as the lottery table A, and the lottery table corresponding to the condition device group number "1" is referred to as the lottery table B.
Further, the lottery table B is set so that the expected value of the number of additions is smaller than that of the lottery table A.

Specifically, for example, in the first embodiment, the expected value of the additional number when the small winning combination E1 is won alone is set to "x1", and the expected value of the additional number when the small winning combination D is won is set to "x2". It is assumed that it has been done. Then, it is assumed that "x1>x2" (the expected value of the number of additions is higher when the small winning combination E1 is won than when the small winning combination D is won).
In this case, the conditional device group number corresponding to the small winning combination D is "1", and the conditional device group number corresponding to the small winning combination E1 is "0".

Therefore, when the small winning combination D is won, the lottery table B is set because the condition device group number is "1". On the other hand, when the small winning combination E1 is won, the lottery table A is set because the condition device group number is "0".
Then, the expected value of the additional number when the additional lottery is performed using the lottery table A is "x1", and the expected value of the additional number when the additional lottery is performed using the lottery table B is "x2". ..

The description returns to FIG. 50 (c).
When the condition device group number “0” is set in step S541, the process proceeds to step S542. In step S542, it is determined whether or not the additional counter value is equal to or greater than the specified number (“1000”). When it is determined that the number is not more than the specified number, the process according to this flowchart is terminated. On the other hand, when it is determined that the additional counter value is equal to or greater than the specified number, the process proceeds to step S543 and the condition device group number “1” is set. Then, the process according to this flowchart is completed.

Therefore, in the above example, when the small winning combination D is won, the condition device group number corresponding to the small winning combination D is originally "1", so it remains "1". On the other hand, when the small winning combination E1 is won, the conditional device group number "0" is set in principle, but when the additional counter value is "1000" or more, the conditional device group number "1" is re-set. Set.

In the additional lottery shown in FIG. 3D, first, in step S551, a lottery table corresponding to the condition device group number is set. In the above example, the lottery table A (expected value "x1") is set when the condition device group number is "0", and the lottery table B (expected value "x2") is set when the condition device group number is "1". NS. Subsequent processes after step S422 are the same as those in FIG. 44 (Example 2).
Further, in Example 8 of FIG. 50, (e) and (f) are the same processes as (d) and (e) of FIG. 44 (Example 2), respectively.

In the above example, two types of condition device group numbers, "0" and "1", are mentioned, but three or more types may be provided. For example, the expected value of the number of additions is "x1> x2> x3", and if the addition counter value is less than "1000", the lottery table with the expected value "x1" is used, and the addition counter value is "1000" or more and less than "1200". Then, a lottery table with an expected value of "x2" is used, and when the additional counter value is "1200" or more, a lottery table with an expected value of "x3" is used.

As described above, in FIG. 50 (Example 8), when the small winning combination E1 is won, the additional lottery is performed so as to correspond to the expected value of the small winning combination E1, but when the additional counter value is "1000" or more. Will be added to the lottery so as to correspond to the expected value of the small winning combination D. That is, when the number of additional games increases and approaches the upper limit value "1500" of the advantageous section, the grade of the winning combination is lowered and the additional lottery is performed.

(Example 9)
FIG. 51 is a flowchart showing an example 9 of control processing on the main control board 50 side.
In Example 9 of FIG. 51, the counter includes an AT counter, an additional counter, and an upper limit counter similar to those of FIG. 45 (Example 3). Further, the specified number is set to "1000" as in FIG. 47 (Example 5).
In FIG. 51, the processes of (a), (b), (e), and (f) are the same as those of (a), (b), (d), and (e) of FIG. 45 (Example 3), respectively. It is a process.
Further, in FIG. 51, the process of (c) is the same as the process of (c) of FIG. 50 (Example 8).
Furthermore, in FIG. 51, the process of (d) is different from (d) of FIG. 50 (Example 8) in that it does not have step S423. Others are the same processing as in (d) of FIG. 50 (Example 8).

(Example 10)
FIG. 52 is a flowchart showing Example 10 of the control process on the main control board 50 side.
In Example 10 of FIG. 52, the counter includes an additional counter and an upper limit counter similar to those of FIG. 49 (Example 7) (there is no AT counter). Further, the specified number is also set to "1000" as in FIG. 49 (Example 7).
In FIG. 52, the processes of (a), (b), (e), and (f) are the same as those of (a), (b), (d), and (e) of FIG. 49 (Example 7), respectively. It is a process.
Further, in FIG. 52, the process of (c) is the same as the process of (c) of FIG. 50 (Example 8).
Furthermore, in FIG. 52, the process of (d) is the same process as that of FIG. 51 (Example 9).

Although FIGS. 43 (Example 1) to 52 (Example 10) have been described above, basically, an AT counter that counts the number of AT games, an additional counter that counts the additional number of AT games, and an advantage. An upper limit counter (advantageous section counter) for counting the upper limit "1500" of the section is provided.
Also, these counters may be increments or decrements.
Furthermore, the AT counter does not have to be provided as shown in FIG. 46 (Example 4) and FIG. 49 (Example 7). In this case, the number of AT games is substantially counted by another counter.
Further, in Examples 1 to 10 described above, an additional lottery is performed according to the winning condition device. Here, when the condition device to be added is won, a predetermined number may be added unconditionally without performing a lottery.

Further, when performing the additional lottery, as shown in FIG. 43 (Example 1), the additional number may be determined regardless of the additional number up to now.
On the other hand, when performing the additional lottery, as shown in FIG. 47 (Example 5) and FIG. 50 (Example 8), the additional number may be determined in consideration of the additional number up to the present.
"Considering the number of additions" means that the larger the number of additions, the smaller the number of additions (the expected value of the number of additions becomes smaller) in the subsequent addition lottery. As a result, the rate of increase in the number of additions as the game progresses can be moderated.

On the other hand, as shown in FIG. 43 (Example 1), it is also possible to execute the addition indefinitely. If the addition is executed indefinitely, for example, the number of remaining AT games may be "2000", "3000", or the like. However, even if such a number of games is reached, the upper limit number of games "1500" in the advantageous section is prioritized (step S443 in FIG. 43 (e)), so that the AT ends at that point.

However, when the number of AT games is added indefinitely as shown in FIG. 43 (Example 1), if the number of added AT games is notified to the player as it is, the number of games added exceeds the upper limit of the number of games "1500" in the advantageous section. The number may be notified. In this case, the player may misunderstand that the game can be played in excess of the maximum number of games "1500".
Therefore, the sub-control board 80 performs various controls as shown below with respect to the notification of the number of AT games and the number of additions in response to the above points.

FIG. 53 is a flowchart showing an advantageous section and AT on the sub control board 80 side, and Example 1 of the control process relating to the addition.
In Example 1 of FIG. 53, (a) is a process of receiving a command transmitted from the main control board 50.
For example, taking FIG. 43 (Example 1) as an example, the process of receiving the command transmitted in steps S411 to S413 of FIG. 43 (b) and step S431 of FIG. 43 (d) is executed.
In the above Examples 1 to 10, the AT counter value or the additional counter value is transmitted, but in the examples of FIGS. 53 and 54, the AT counter value and the additional number are transmitted.

In FIG. 53A, in step S601, a process of receiving the AT counter value is executed. This process is a process of receiving the AT counter value and storing it in the RWM 83 of the sub control board 80. In the next step S602, a process of receiving the additional number ((b) in the figure) is executed. In the next step S603, the reception process of the advantageous section flag is executed. Similar to step S601, this process is a process of receiving the value of the advantageous section flag (“0” or “1”) and storing it in the RWM 83 of the sub control board 80. Further, in the next step S604, a process ((d) in the figure) for receiving the effect group number (see FIG. 21) is executed.

Proceeding to step S602, the process (b) in the figure is executed.
First, in step S611, the received addition number is added to the addition counter. The additional counter is provided on the sub control board 80 side. Next, the process proceeds to step S612, and it is determined whether or not the additional counter value exceeds the specified number. Here, the specified number is set to "1500". Therefore, in this example, as in FIG. 45 (Example 3), when the additional counter value exceeds "1500", it is determined that the upper limit of the advantageous section has been reached. If it is determined in step S612 that the additional counter value exceeds the specified number (“1500”), the process proceeds to step S613, and if it is determined that the number is equal to or less than the specified number, the process proceeds to step S614.

In step S613, "1" is set in the additional effect suppression flag. Then, the process proceeds to step S614. Here, the "additional effect suppression flag" is used so that the additional effect is not output when the number of additional effects is already "1500", and the additional effect can be output when the number of additional effects is "1500" or less. , A flag for making that judgment.
In step S614, the number of additions in the game is stored (in the RWM83 of the sub-control board 80). Then, the process according to this flowchart is completed.

Further, when the process proceeds to step S604, the process (c) in the figure is executed.
First, in step S621, it is determined whether or not the game has an additional number. This determination is made by determining whether or not the additional number saved in step S614 is "0". Then, when it is determined that the additional number is present, the process proceeds to step S622, and when it is determined that the additional number is not present, the process proceeds to step S625.
In step S622, it is determined whether or not the additional effect suppression flag is "1". If it is determined to be "1", the process proceeds to step S623, and if it is determined that the value is not "1", the process proceeds to step S624.

In step S623, an effect without an additional effect is selected. That is, even if the number of additions has reached the specified number (“1500”) and the additional lottery is won in the game, it is not possible to add more than the current number, so control is performed so that the additional effect is not output. The effect selected here is a normal effect or an effect corresponding to the received effect group number (for example, when the replay is won, an effect suggesting the replay is won (blue or the like)) is output. Then, the process according to this flowchart is completed.

On the other hand, when it is determined as "No" in step S622 and the process proceeds to step S624, it is possible to select an effect with an additional effect. For example, there is an effect of notifying all or part of the additional number in the game. It should be noted that it is not always necessary to select an effect with an additional effect in the game in which the number of additional effects has been determined. May be good.
On the other hand, when it is determined in step S621 that the game does not have an additional number and the process proceeds to step S625, a normal effect is output. As a normal effect, as described above, it is possible to output an effect corresponding to the winning combination (effect group number) in the game. Then, the process according to this flowchart is completed.

FIG. 54 is a flowchart showing an advantageous section and AT on the sub control board 80 side, and Example 2 of the control process relating to the addition.
In Example 2 of FIG. 54, (a) is a process of receiving a command transmitted from the main control board 50. First, in step S631, a process of receiving the ball ejection suppression flag is executed. Here, the ball ejection suppression flag is a flag (command) transmitted from the main control board 60 to the sub control board 80, and when it is "1", it means that the addition effect is suppressed, and " When it is "0", it means that the additional effect is not suppressed. That is, when the ball ejection suppression flag "1" is transmitted from the main control board 50, it is an instruction to suppress the addition effect.
In Example 1 of FIG. 53, as shown in (b), the additional effect suppression flag is set on the sub-control board 80 side. On the other hand, in Example 2 of FIG. 54, the main control board 60 determines whether or not to suppress the additional effect, and the determination result is transmitted to the sub control board 80 as a ball ejection suppression flag.

Examples of the method in which the main control board 50 transmits the ball ejection suppression flag include the following methods.
Taking FIG. 44 (Example 2) as an example, in FIG. 44 (c), when it is determined as “Yes” in step S451, the ball ejection suppression flag provided on the main control board 50 is turned on. Then, in FIG. 44 (d), after step S461, the ball ejection suppression flag is transmitted.

In Example 2 of FIG. 54, the same as in Example 1 of FIG. 53 except for step S631 and step S632.
In step S631, the process (b) in the figure is executed.
First, in step S641, when the ball ejection suppression flag is received, it is determined whether or not the value is "1". If it is determined to be "1", the process proceeds to step S642, and if it is determined that the value is not "1", the process proceeds to step S643.

In step S642, "1" is set in the additional effect suppression flag stored in the RWM83 of the sub-control board 80, and the process according to this flowchart is completed. On the other hand, when the process proceeds to step S643, "0" is set in the additional effect suppression flag, and the process according to this flowchart is completed.
Therefore, when the received ball ejection suppression flag is "1", the additional effect suppression flag on the sub control board 80 side is set to "1", and when the received ball ejection suppression flag is "0", the additional effect suppression flag is set. Is set to "0". Therefore, in Example 2 of FIG. 54, the additional effect suppression flag is switched according to the information transmitted from the main control board 60.

In FIG. 54 (c), as shown in FIG. 53 (Example 1), it is not necessary to determine whether or not the additional counter value exceeds the specified number. Therefore, in step S611, the additional number is added to the additional counter, and the next step. The additional number is saved in S614.
Further, the effect group number receiving process in FIG. 53 (d) is the same process as in FIG. 53 (Example 1).

When the sub-control board 80 outputs the additional effect, for example, when the additional number determined in the game is "200", all the additional numbers ("200") may be notified in the effect of the game. However, it is also possible to notify in small steps (notify by dividing the number of additions) in a plurality of games (for example, continuous production) including the game. Specifically, when the additional number is "200" in the game, the additional number "100" is notified in the game, "50" is notified in the next game, and "50" is further notified in the next game. For example, to notify.

FIG. 55 is a diagram showing an image display example of the image display device 23 by the sub-control board 80 with respect to the addition during AT, and is a diagram showing Examples 1 to 4.
First, in Example 1, the image display device 23 before the addition has "digestion G (meaning" AT digestion game count ") 1200" and "remaining G (meaning" AT remaining game count ") 300". Is shown as an example. Therefore, since "the number of AT digested games + the number of remaining games = 1500", the number of AT games that can be performed has already reached the upper limit.
In this case, in Example 1, even if 500 games are added internally (for example, it means a case such as step S423 in FIG. 43C), the display of the number of additions is changed and the effect related to the addition is performed. No. Therefore, the display after the addition remains the same as the display before the addition.

Of course, "500" may be added to the counters (AT counters, addition counters, etc.) on the sub control board 80 side when 500 games are added. As for the number of AT games and the number of additions, real values may be managed by a counter, and only display may be performed as in Example 1. In the case of such control, an internal counter and a display counter are provided on the sub control board 80 side.
Alternatively, even if 500 games are added, the counter may not be updated.
If the image display is controlled as in Example 1, it is possible to suppress an effect related to unnecessary addition.

In Example 2, when the number of digested games of AT is 1200 games and the number of remaining games is 200 games, and 500 games are added internally, the correct value (the number of remaining games after the addition) is obtained. ) Is not displayed and the display is switched to another display. In Example 2, the number of remaining games may be displayed as "celebration" or "congratulations". In addition, it may be displayed as "?".

In Example 2, when the total number of digested games and the number of remaining games of the AT is "1500" or less, the number of remaining games is displayed. If it exceeds "1500", the display of the number of remaining games is not displayed so that the player can grasp it. The player can grasp that the addition has been performed because the display of the number of remaining games of the AT is changed from a specific numerical value to a display other than the numerical value. However, since a specific numerical value is not displayed for the remaining number of games of the AT, the player cannot grasp the remaining number of games of the AT.

In the case where the number of digested games of AT is "1200" and the number of remaining games is "200" before the addition, when "500" is added, the number of remaining games of AT may be set to "700" on the counter. , Or it may be "300".
In addition, when the display of the remaining number of games of AT is "celebration" or "congratulations", if it is a specification that it is confirmed that AT will continue up to the upper limit of 1500 times, "1500-AT digestion game" By calculating the "number of times" by the player, it is possible to grasp the number of remaining games of the AT.
Furthermore, the display of "celebration" or "congratulations" informs the player that the total number of AT games has exceeded "1500", and also serves to indicate that no further additions will be made. It becomes.

Example 3 shows an example in which "500" is added when the number of digested games of AT is "1200" and the number of remaining games is "200", as in Example 2. Then, in Example 3, the number of remaining AT games (although not displayed in FIG. 55) is "+100", which is "300". That is, with this addition, the total number of AT games has reached "1500".

In Example 3, when the total number of AT games is "1500" or more, the display of both the number of digested games and the number of remaining games of the AT is stopped and replaced with the ending effect (movie). The ending effect is such that at least a plurality of games (for example, dozens of games) are continued, and is executed until the number of digested games of the AT reaches "1500". If the final image of the ending effect prepared in advance is reached before the number of digestion games of the AT reaches "1500", the final image is continuously displayed, or the image is returned to the beginning of the ending effect and the image is repeated. The method can be mentioned.
By outputting the ending effect, it is possible to play a role of notifying the player that the number of games is not added any more.

In Example 4, as shown in Example 2, when only the number of digested games of AT is displayed and the number of remaining games is displayed as "celebration" or the like, as described above, the player is the remaining AT. Although the number of games cannot be grasped, for example, when the number of remaining games of the AT becomes "10", game information indicating that the AT will not be executed in excess of 1500 games, such as "It will end in 10 more games", is provided. It is to be displayed. The "remaining 10 games" shown in Example 4 is an example, and it is arbitrary as to how many games are left to start displaying the game information. By displaying the game information indicating that the number of AT games is not executed exceeding "1500", the player can know the remaining number of AT games.
In addition, Example 4 can also be used in combination with Example 1 to Example 3.

In addition, when an additional game exceeding 1500 games occurs, the additional effect itself may be displayed as "Congratulations", "Congratulations", or the like.
Furthermore, when an addition exceeding 1500 games occurs, a privilege image that can be displayed only when an addition exceeding 1500 games occurs may be displayed.
Further, "occurrence of addition exceeding 1500 games" may be set as a mission in the Mythro game. For example, when "the occurrence of an additional game exceeding 1500 games" is generated a predetermined number of times, the mission is completed and some privilege is given to the player.

In this way, even if an additional game exceeding 1500 games occurs, the additional game cannot be executed, but instead, a privilege (profit) for preventing a decrease in the motivation of the player is set. It is preferable to keep it.
In particular, when an additional game exceeding 1500 games occurs, it is assumed that the rare role is won, but when the rare role is won, no effect is output because the total number of games is "1500" or more. It is unnatural not to do it.
The "mythro game" is, for example, as described in paragraph number "0680" of "Japanese Patent Laid-Open No. 2016-104442".

FIG. 56 is a diagram for explaining how the effect and the like change as the number of AT games increases in the third embodiment.
Since "AT = advantageous section" is set in the third embodiment, the number of acquired sheets continues to increase during the advantageous section (AT). Then, in the example of FIG. 56, in order to simplify the graph, the AT continues from the number of games of "0G" to "1500G", and the number of acquired cards continues to increase.
In FIG. 56, FIG. 56A is a diagram showing the relationship between the number of AT games and the effect.
In FIG. 56, the horizontal axis represents the number of AT games and the vertical axis represents the number of acquired games. The example of (a) is an example in which 500 games are added when the number of digestion games in the AT (advantageous section) reaches "1200", as shown in Example 2 of FIG. 55.

When the number of games played in the advantageous section reaches 1500 games, the AT ends at the same time as the end of the advantageous section, even if it has the remaining number of games at that time.
In addition, the additional effect is performed up to 1200 games, but when the additional effect of 500 games is won, the additional effect for the winning is not performed. In addition, even if a person wins a further addition after that, the additional production will not be performed.

On the other hand, the production related to AT during AT continues until the number of games played in the advantageous section reaches 1500 games. Further, the number of digested games and the number of remaining games of AT are displayed up to 1200 games, but when the additional 500 games are won in the 1200th game, the number of remaining AT games is displayed as shown in Example 2 of FIG. Or stop displaying both the number of digested games and the number of remaining games of AT as in Example 3 of FIG. 55, and other displays (“celebration” shown in Example 2 of FIG. 55 and Example 3 Switch to the ending effect shown).

FIG. 56 (b) shows an example (shown by a solid line in the figure) of (1) gradually lowering the additional lottery probability as the number of AT games is exhausted when the AT continues to play "1500", and (2). It is a figure which shows the example (indicated by a dotted line in the figure) which gradually reduces the instruction frequency.
In the above (1), for example, as shown in FIG. 47 (c), the lottery table A is used until the number of AT games is less than "1000" games, and when the number of AT games is "1000" or more, the lottery table B is used. Or, as shown in FIG. 50 (c), until the number of AT games is less than "1000" games, an additional lottery is performed with a grade corresponding to the winning combination, but the number of AT games is "1000" or more. In this case, it corresponds to an example in which the grade of the winning combination is lowered and an additional lottery is performed.

Further, in the example of (1), when the number of AT games is less than "500" games, the additional lottery probability is set to a high probability, and when the number of AT games is more than "500" games and less than "1000" games, the additional lottery probability is set to the normal probability. When the game is "1000" or more, the additional lottery probability is set to a low probability. Even if the probability of adding AT is gradually reduced as the number of games is exhausted, the rate of increase in the number of acquired cards with respect to the number of games does not change as long as the remaining number of games of AT is available. , The same as in FIG. 56 (a).

On the other hand, in the example of (2), the instruction frequency is controlled to be gradually lowered according to the digestion of the number of AT games.
Here, the "instruction frequency" is how often the instruction function is activated when the small winning combination B group or the small winning combination C group (pushing order bell) is won during AT (correct answer pressing order). Whether to display) is specified. For example, when the number of AT games is less than "500" games, the instruction frequency is set to 100% (instruction frequency "high"), and when the number of AT games is more than "500" games and less than "1000" games, the instruction frequency is 90% (instruction frequency). The frequency is set to "medium"), and when the game is "1000" or more, the instruction frequency is set to 80% (instruction frequency "low").

For example, when the instruction frequency is 90%, a lottery (90% probability of winning) is performed on the small winning combination B group or the small winning combination C group (pushing order bell) to determine whether or not to activate the instruction function. When the lottery is won, the instruction function is activated.
In addition, when the instruction frequency is less than 100% and the replay duplicate winning for promotion or maintenance of RT is obtained, the correct answer pressing order may always be instructed, or the same as when the pressing order bell is won. The frequency may determine whether or not to instruct.

If the instruction function does not work when the replay duplicate is won, it may fall to a disadvantageous RT. For example, in the first embodiment (FIG. 22), the replay 03 is displayed when the replay C group is won during RT3, and the player falls to RT2.
Further, as in the first embodiment, when the pattern symbol is displayed in RT3, it falls to RT2. Therefore, in an example such as the first embodiment, if the instruction function does not operate when the push order bell is won, the RT may fall to a disadvantage.
If the instruction frequency is gradually reduced as the number of AT games is exhausted, the number of cases where the push order is incorrect when the push order bell is won will gradually increase. Therefore, it becomes difficult to increase. (2) of FIG. 56 (b) shows this state.

In the third embodiment, "AT = advantageous section" was set.
On the other hand, as in the first embodiment described above and the fourth embodiment described later, a case where the section is advantageous but is a non-AT period (precursor, CZ, pullback period, special game, etc. The same shall apply hereinafter). Of course, to have.
For example, it is a case where an advantageous section is started, the above-mentioned non-AT period is executed for "n" games, and then AT is started.
In this case, at the start of the AT, the advantageous section has already digested the "n" game.
In this case, when the number of digested games and the like is displayed as an image as shown in FIG. 55, the number of digested games in the advantageous section including a part or all of the "n" game is displayed (Example 1), and " n ”The digestion of the game is reflected in the internal counter (upper limit counter or the like shown in FIG. 43 or the like), but the image is not displayed (Example 2).
In the case of Example 1, the specification is such that the number of digested games in a part or all of the advantageous sections other than the AT is displayed to the player, and in the case of Example 2, only the number of digested games of AT is displayed to the player. Become.
Further, in the case of Example 1, both a) the number of digested games in the advantageous section is displayed (the number of digested games in the AT is not displayed) and b) the number of digested games in the advantageous section and the number of digested games in the AT are displayed. There are cases where it is displayed.

Further, in the third embodiment, for example, as shown in FIG. 56B, when the number of games is less than "500", the additional lottery probability is set to a high probability, and when the number of games is "500" or more and less than "1000", the additional lottery is performed. The probability was set as the normal probability, and when the number of games played was "1000" or more, the additional lottery probability was set as the low probability.
Here, it is assumed that AT is started after a non-AT period of 600 games after shifting to the advantageous section in the same manner as described above.
In addition, when the instruction function operating game is hardly executed from the start of the advantageous section to 600 games, the graph of FIG. 56 is a graph in which the number of acquired cards decreases as the number of games is consumed (lower right). Become. Then, when the AT is started from 600 games, the graph (upper right) shows that the number of acquired cards starts to increase after 600 games.

In the above example, since 600 games have already been consumed in the advantageous section at the start of AT, the maximum number of remaining games in the advantageous section at the start of AT is 900 games. Therefore, when this example is applied to FIG. 56 (b), for example, when the number of AT digestion games is less than "300", the additional lottery probability is set to a high probability, and when the number of AT digestion games is "300" or more and less than "600", the additional lottery is performed. The probability is set as the normal probability, and when the number of AT digestion games is "600" or more, the additional lottery probability is set to a low probability.

Furthermore, similarly to the above, when the AT is started after the non-AT period of 600 games after shifting to the advantageous section, for example, in the “(c) additional lottery” of FIG. 47, the additional counter is set to the specified number “600”. When the number is equal to or greater than that (“Yes” in step S451), the lottery table B may be set.
Here, the specified number is set to "600" when the maximum number of remaining games in the advantageous section at the start of AT is "900" as described above, and the number of games is "2/3" at the time of digestion. Is set as the threshold value.
In this way, when the advantageous section is not necessarily AT, for example, when AT is not started at the start of the advantageous section and AT is started after a predetermined number of games, the expected additional value (additional lottery probability, etc.) is added to the AT game. When changing based on the number of times played, it is necessary to take into account the number of remaining games in the advantageous section.

<Fourth Embodiment>
Subsequently, the fourth embodiment will be described.
As shown in FIG. 1, in the first embodiment, the main control board 50 includes an external signal transmitting means 70, and an external signal (sometimes referred to as an “outer end”) with respect to the external centralized terminal plate 100. To send. The fourth embodiment is specifically characterized in what kind of external signal is output and at what timing it is turned on / off.
Further, the BB in the fourth embodiment is the 1BBA, 1BBB, etc. of the 1st embodiment, and the BB game is the 1BBA game, the 1BBB game, and the like.

FIG. 57 is a diagram showing Example 1 (upper row) and Example 2 (lower row) of the time chart of the external signal in the fourth embodiment. Further, FIG. 58 is a diagram showing Example 3 of a time chart of an external signal.
In the examples of FIGS. 57 and 58, an external signal 1 indicating that the BB is operating (during the BB game) and an external signal 2 indicating that the AT is in progress are output as external signals. In addition to these external signals, it is also possible to provide an external signal indicating that the player is in an advantageous state (for example, a signal that is turned on when either AT or special game is satisfied). Is.

In the third embodiment, the AT is started at the same time as the start of the advantageous section, and the advantageous section is ended at the same time as the end of the AT. On the other hand, in the fourth embodiment, even if the advantageous section is started, the AT is not always started immediately. For example, when the AT start condition is satisfied during the advantageous section, the AT is started. However, the point that the advantageous section ends when the AT ends is the same as in the third embodiment.

In Example 1 of FIG. 57, AT is started after a predetermined number of games have elapsed after starting the advantageous section. When AT is started, the external signal 2 which means the AT signal is turned on. Then, it is assumed that the BB is won during the AT and the BB game is started. With the start of the BB game, the external signal 1 indicating that the BB game is in progress is turned on. The AT is interrupted based on the start of the BB game, and the AT is restarted after the end of the BB game. However, the external signal 2 remains on even during the BB game.
When the BB game is completed, the external signal 1 is turned off. After that, when the AT ends, the external signal 2 is turned off. With the end of the AT, the advantageous section also ends (the advantageous section display LED 77 goes out). In this example, the AT and the advantageous section are completed before reaching the 1500 game, which is the upper limit of the advantageous section.
When the 1500 games, which is the upper limit of the advantageous section, is reached, the advantageous section and the AT are ended even if the remaining number of games of the AT is reached at that time.

In Example 2 of FIG. 57, the point that AT is started after the lapse of a predetermined number of games after starting the advantageous section is the same as that of Example 1. Further, the point of shifting to the BB game during AT is also the same as in Example 1. Then, Example 2 is an example in which the end condition of the advantageous section is satisfied during the BB game. Therefore, when the end condition of the advantageous section is reached, the BB game has not been completed yet. Then, after the lapse of the end condition of the advantageous section, the BB game is completed.

In this case, both the external signal 1 indicating that the BB game is in progress and the external signal 2 indicating that the AT is in progress are on until the end of the BB game. Then, with the end of the BB game, the external signal 1 and the external signal 2 are turned off. Of course, the advantageous section ends when the end condition of the advantageous section is satisfied. Therefore, at the end of the advantageous section, the advantageous section display LED 77 is also turned off. Further, since the AT is executed within the advantageous section, the AT also ends with the end of the advantageous section.
As described above, in Example 2, the AT ends when the end condition of the advantageous section is reached, but the external signal 2 is turned on even after the end condition of the advantageous section has passed. This makes it possible to prevent the output of the external signal 2 from being turned off at an unnatural timing.

As an example of satisfying the end condition of the advantageous section during the BB game as in Example 2, for example, first, the number of AT games is set in advance at the start of the AT, and the number of games is set during the BB game. However, there are cases where it is subtracted. Secondly, there is a case where the upper limit of the advantageous section (1500 games) is reached during the BB game. For example, when the number of AT games is set to "50" and the AT is started, and when the game shifts to the BB game during the AT, the counting of the number of AT games may be interrupted. However, the count of the upper limit "1500" games in the advantageous section is continued even during the BB game.

Example 3 shown in FIG. 58 is an example in which AT is started after a predetermined number of games have elapsed after the start of the advantageous section, as in Example 1 of FIG. When the AT is started, the external signal 2 is turned on. In Example 3, it is assumed that the BB is not won during the advantageous section (the game does not shift to the BB game).
Further, Example 3 is an example in which the number of games is added during the AT, and the number of remaining games of the AT is held even when the upper limit of the advantageous section of 1500 games is reached. Even if the AT has the remaining number of games when the 1500 games, which is the upper limit of the advantageous section, is reached, the advantageous section and the AT are ended. Based on this, the external signal 2 is turned off when the 1500 game, which is the upper limit of the advantageous section, is reached.

In addition, when the special role is won just before the end of the advantageous section, if the 1500 game of the advantageous section is completed while the special role is inside, during the special game in which the special role wins and shifts, the "advantageous section" It is not possible to output a production such as "How many times is the special game inside?" This is because the data related to the advantageous section is reset when the 1500 game of the advantageous section is reached. However, although the actual advantageous section ends, it is possible to output the effect as if the advantageous section (AT) continues even during the special game in terms of the appearance of the effect.

At the end of the advantageous section, the data related to the advantageous section stored on the main control board 50 side is cleared, but the data related to the advantageous section stored on the sub control board 80 side (transmitted from the main control board 50). Regarding the data (data stored based on the incoming command), there are cases where it is cleared and cases where it is not cleared.
If it is not cleared, it is possible to display a numerical value exceeding "1500" for the number of games played in the advantageous section during the special game.
Further, in the case where a special role is won just before the end of the advantageous section, if an effect such as an ending effect is output, the ending effect may be stopped and the winning of the special role may be announced immediately.

<Fifth Embodiment>
Subsequently, the fifth embodiment will be described. In the fifth embodiment, the AT is started or ended with the transition of the gaming state (RT or control state). In the fifth embodiment, the following Examples 1 and 2 will be described.
FIG. 59 is a diagram showing the RT transition in Example 1 of the fifth embodiment, and is a diagram corresponding to FIG. 22 of the first embodiment.
In Example 1 of the fifth embodiment, the advantageous section is started at the same time as the start of the BB game. Therefore, in the figure, it is an advantageous section during 1BBA operation and 1BBB operation.
Further, both at the end of the 1BBA operation and at the end of the 1BBB operation shift to non-RT (in this respect, it differs from the first embodiment).

Non-RT maintains an advantageous section. Further, in the non-RT, the replay A alone is not drawn, and the replay C group is drawn (as in RT3 of the first embodiment). When the replay C group is won, the instruction function is not activated. Therefore, the replay 01 or the replay 03 wins a prize by the operation (luck) of the stop switch 42 of the player. Then, when the replay 01 wins, it shifts to RT5 (RT newly provided in the fifth embodiment), and when the replay 03 wins, it shifts to RT2.

When the replay C group is won in the non-RT, the instruction function may not always be activated, and the instruction function may always be activated (the push order for winning the replay 01 is displayed). Alternatively, it may be decided by lottery whether or not to activate the instruction function when the replay C group is won.
Or, when shifting to non-RT based on the end of operation of 1BBA, the instruction function is activated when the replay C group is elected, and when shifting to non-RT based on the end of operation of 1BBB, the instruction function is activated when the replay C group is elected. May not be activated, and so on.

RT5 is a finite RT and continues 50 games. When 50 games are digested at RT5, the game shifts to RT2.
Then, in the fifth embodiment, RT5 is used as an advantageous section and AT is executed. On the other hand, when shifting from non-RT or RT5 to RT2, the normal section (non-AT) is set.
Therefore, when the replay 01 wins in the non-RT (advantageous section and non-AT), the game shifts to RT5 from the next game, and the advantageous section and AT (50 games) are executed. Then, when 50 games have been digested, the process shifts to RT2 (normal section and non-AT).
On the other hand, when the replay 03 wins in the non-RT (advantageous section and non-AT), the game shifts to RT2 (normal section and non-AT) from the next game.
Then, in RT2, a lottery for an advantageous section and AT is performed.

FIG. 60 is a time chart showing the relationship between the above RT transition and AT. (A) shows an example of shifting to AT. In addition, the example of FIG. 60 shows an example in which 1BB was won in RT2 and the game shifted to 1BB game without going through RT4 (inside). When the game shifts from RT2 to 1BB, the advantageous section starts. Then, when the 1BB game is completed, the game shifts to the non-RT, and when the replay 01 wins in this non-RT, the game shifts to the RT5. At RT5, AT of 50 games is executed. When the AT of 50 games is completed, the advantageous section and the AT are ended, and the game shifts to RT2.
On the other hand, in the example of FIG. 3B, the 1BB game is completed and the game shifts to the non-RT, and the replay 03 wins the prize in this non-RT. In this case, it does not shift to RT5 (AT), but shifts to RT2 and ends the advantageous section.

FIG. 61 is a diagram showing Example 2 ((a) to (c)) of the fifth embodiment.
In the fifth embodiment, as described above, the advantageous section and the start and end of the AT are controlled and managed by the RT (lottery state) or the main control board 50 (regardless of whether the RTs are different or the same). In Example 1 of FIG. 60 described above, the advantageous section and AT are started by the RT transition, and the advantageous section and AT are ended by the RT transition.
On the other hand, in Example 2 of FIG. 61, the advantageous section and AT are started by the transition of the control state, and further, the advantageous section and AT are ended by the transition of the control state.

In FIG. 61, (a) includes control states of states 1 to 3. In this example, state 1 and state 2 are advantageous sections, and state 3 is a normal section.
The states 1 to 3 are mainly states when the RT2 and the RT3 are switched back and forth in the first embodiment (FIG. 22). State 3 is so-called normal, state 2 is a precursor or a pullback period after the end of AT, and state 1 is AT.

In the state 3 (normal), the lottery of the advantageous section is executed. The lottery for the advantageous section is the same as that shown in the first embodiment, for example. Then, when the advantageous section is won in the state 3 and the section shifts to the advantageous section, the precursor shifts to the state 2. Therefore, when the transition to the precursor occurs, the advantageous section display LED 77 lights up.
The precursor corresponds to the preparation period until the AT is started. For example, the number of games of the precursor is determined at the time of transition from the state 3 to the state 2, and the precursor in the state 2 stays until the number of games is exhausted. do. The instruction function does not operate during the omen. Then, when the number of games in the state 2 (precursor) is exhausted, the game shifts to the AT in the state 1 from the next game. During state 1 (AT), the instruction function is activated.

Further, the state 1 (AT) continues until the end condition of the state 1 (AT) is satisfied. The number of games played in the state 1 (AT) may be fixed, for example, "50", or may be added as shown in the third embodiment.
Then, when the end condition of the state 1 (AT) is satisfied, the period shifts to the pullback period of the AT in the state 2. In this pullback period, the maximum number of games is predetermined (for example, "20" games).

If a predetermined condition is satisfied during the period of this state 2 (pull-back period) (for example, when a rare role is won, or when an AT lottery executed when a rare role is won, for example), the state 1 (for example, Move to AT). On the other hand, when the predetermined condition is not satisfied during the pullback period in the state 2, the state shifts to the normal state 3. Then, at the same time as the transition to the state 3, the advantageous section is terminated and the normal section is shifted.
As described above, the normal section, which is the state 3, is set as the normal section, the other states 1 and 2 are set as the advantageous sections, and when the transition to the advantageous section is performed, the transition condition is satisfied or not. It shifts to AT (state 1) or shifts to state 2 (AT pullback period).

In the example of FIG. 61A, it is also possible to set an upper limit on the number of AT transitions. For example, when the upper limit of the number of ATs is set to "5", after the end of the fifth AT, the state 1 is changed to the state 3 without shifting to the AT pullback period (state 2). Then, it is also possible to end the AT and the advantageous section.

FIG. 61 (b) has AT, CZ (chance zone), precursor, and normal as control states.
And usually, it is a normal section, and the precursor, CZ, and AT are advantageous sections.
First, during normal times, a lottery for shifting to an advantageous section is performed as in the first embodiment, and when the advantageous section is won, the game is shifted to the advantageous section from the next game and a precursor is started. The precursor is a maximum of 32 games (the number of precursor games is determined by lottery). Then, after digesting the number of games of the precursor, it shifts to CZ. CZ is executed until the transition condition to AT is satisfied or the end condition of CZ is satisfied. When the conditions for transition to AT are satisfied during CZ, the transition to AT is performed. Further, if the end condition of CZ is satisfied before the transition condition to AT is satisfied during CZ, the transition is normal.

Specifically, as conditions for transitioning to AT during CZ, for example, (a) when a transition lottery according to a winning combination is won, (b) when a transition lottery performed for each game regardless of the winning combination is won, (C) When a predetermined specific combination is won, (d) When the number of times a predetermined specific combination is won exceeds the specified number, (e) When shifting to a specific RT, (f) Predetermined Various transition conditions can be set according to the playability, such as when a special role is won.
Similarly, the end conditions of CZ are as follows: (a) when the conditions for transition to AT during CZ are not satisfied, (b) when a specific falling combination is won, and (c) for each game regardless of the winning combination. Various termination conditions can be set according to the playability, such as when a fall lottery is won.
Further, the conditions for shifting to AT in CZ and the conditions for ending CZ mentioned here may be set as opposite conditions to each other.

AT is executed in the same manner as in (a) above. Then, when the AT termination condition is satisfied, the system shifts to CZ. The CZ after the end of AT is positioned in the pullback period of (a) above. If the transition condition to AT is satisfied again during this CZ, the transition to AT can be performed, but if the termination condition of CZ is satisfied without satisfying the transition condition to AT, the transition to normal is performed. At the same time as this transition to normal, the advantageous section ends and the normal section is started.

In principle, the instruction function operation game is executed during AT, but since the instruction function is also advantageous in the state 2 of FIG. 61 (a) or the CZ or omen of FIG. 61 (b). It is possible to perform an actuating game.
In particular, since it is necessary to execute the instruction function operating game at least once after shifting to the advantageous section, in the example of FIG. The game in which the role B group is won may be regarded as an instruction function operating game.
Similarly, in the example of FIG. 61 (b), among the 32 games of the precursor, the game in which the small winning combination B group is first won is set as the instruction function operating game.

FIG. 61 (c) is an example having a control state of a precursor, CZ, and AT, as in FIG. 61 (b). However, in this example, unlike (b), an example in which the transition to AT could not be performed is shown.
As shown in (c) in the figure, when shifting from normal to precursory, the game shifts to CZ after a predetermined number of games (up to 32 games). If the transition condition to AT is satisfied during this CZ, the transition to AT is performed as shown in (b), but when the end condition of CZ is satisfied before the transition condition to AT is satisfied (for example, the predetermined number of games (32 games)). ) Digestion) shifts to the pullback period. In the pullback period, the lottery for transition to CZ is performed again, and if the transition condition to CZ is satisfied before the transition condition to normal (for example, digestion of a predetermined number of games (32 games)) is satisfied, the transition to CZ is performed (for example, the transition to CZ is performed. In the figure, (c) shows an example of shifting to CZ again (successful pullback example)).

Then, during the CZ, as described above, the lottery for the transition to the AT is performed, but if the end condition of the CZ is satisfied before the transition condition to the AT is satisfied, the transition to the withdrawal period is performed again. Then, in the example of (c) in the figure, in the second pullback period, the end condition of CZ (for example, digestion of a predetermined number of games (32 games)) is satisfied (pullback failure) before the transition condition to CZ is satisfied. This is an example of a normal transition.

As described above, in the fifth embodiment, the start and end of the advantageous section can be controlled with the transition to RT, and AT or the like can be freely executed during the advantageous section.
Alternatively, when a plurality of control states not related to RT are provided, a control state corresponding to normal is set as a normal section, a lottery for transition to an advantageous section is performed during this normal section, and a lottery for transition to an advantageous section is won, it is advantageous. Shift to one of the control states corresponding to the section. Then, in the control state corresponding to the advantageous section, the end condition is set (for example, digestion of a predetermined number of games), and the control state is shifted to another control state corresponding to the advantageous section, or the advantageous section is ended. It shifts to the control state corresponding to the normal section.

In the example of FIG. 61, when the AT is executed, the ART can be executed if the AT is executed at the RT with a high probability of replay. Therefore, for example, in the case of realizing the example of FIG. 61 in the RT transition of the first embodiment, when the transition condition to AT is satisfied, the instruction function is activated at the time of winning the replay B group in RT2, and the replay 02 is performed. It is possible to display the push order to be displayed and shift to RT3.

In this way, by arbitrarily determining the end condition of the advantageous section, a plurality of control states (precursor, CZ, AT) can be freely designed. Further, not limited to the examples shown in FIGS. 60 and 61, it is also possible to combine all of them. Furthermore, it is also possible to set a plurality of end conditions in one advantageous section, and by doing so, a wider range of playability can be designed.
For example, the example of FIG. 60A shows that the advantageous section ends when the number of games of RT5 executed during the advantageous section reaches 50 games.
Further, the example of FIG. 60B shows that the advantageous section ends by shifting from the non-RT to the RT2 by displaying the replay 03 during the non-RT. That is, in the example of FIG. 60, two conditions, "digestion of 50 games at RT5" and "transition from non-RT to RT2", are set as the end conditions of the advantageous section. In other words, it positions non-RT as a CZ whether it is promoted to AT (RT5) or falls to normal (RT2). The big concept is that the advantageous section is terminated when a specific RT shift is triggered.

Furthermore, in the example of FIG. 61, the advantageous section and the normal section are shifted according to the control state regardless of which RT the user is staying at.
In the example of FIG. 61A, the state 1 and the state 2 (precursor or AT pullback period) are advantageous sections, and the state 3 is set as a normal section. Then, it is shown that the advantageous section starts by shifting from the state 3 to the state 1 or the state 2, and the advantageous section ends by shifting from the state 1 or the state 2 to the state 3.
Similarly, in the examples of FIGS. 61 (b) and 61 (c), the normal section of the control state is the normal section, and the precursor of the control state, CZ, and AT are the advantageous sections. Then, it is shown that the advantageous section starts by shifting from the normal to the precursor, CZ, or AT, and the advantageous section ends by shifting from the precursor, CZ, or AT to normal.

As described above, in the example of FIG. 61, when the control state is normal, it is a normal section, but when the control state is different from the normal state, the advantageous section is executed. However, even during the advantageous section, AT is not executed in the precursor or CZ, and in order for AT to be executed, it is necessary to satisfy the transition condition of AT in the precursor or CZ. On the other hand, even if the vehicle falls from AT to CZ (FIG. 61 (b)) or falls from CZ to the pullback period (precursor) (FIG. 61 (c)), the advantageous section does not end. The advantageous section ends when the control state shifts to normal.

Further, in addition to the examples described with reference to FIGS. 60 and 61, the following examples can be given.
(1) An example in which a first finite RT (20 games) and a second finite RT (60 games) are provided and the end condition of the advantageous section is set to the digestion of the first finite RT or the second finite RT. Such an advantageous section By setting the end condition of, for example, by providing a case of shifting from a non-RT in an advantageous section to a first finite RT of 20 games and a case of shifting to a second finite RT of 60 games, a benefit to the player. Can be different.
More specifically, a specific replay is drawn in a non-RT in an advantageous section, and a symbol combination that shifts to the first finite RT or a symbol combination that shifts to the second finite RT is displayed depending on the push order when the specific replay is won. Let me. Then, at the time of winning the specific replay, by shifting to the first finite RT of 20 games or the second finite RT of 60 games according to the push order operated by the player, it is about 3 depending on which finite RT is shifted. It is possible to make the game playable so that a double profit difference can be generated.

Further, when the specific replay is won during non-RT, the main control board 50 may notify the player of the push order. In that case, a specification that determines whether to notify the push order to shift to the first finite RT or the second finite RT is considered in consideration of the winning combination and the game situation before the specific replay winning during non-RT. Be done. At this time, the winning probability of the specific replay may be either one having a setting difference or one having no setting difference.
Further, the end condition of the advantageous section is set only for the digestion of the first finite RT, and the end condition of the advantageous section is set so as not to end in the digestion of the second finite RT. As a result, when shifting from non-RT to the second finite RT of 60 games, the advantageous section is not terminated even after the digestion of the 60 games, and by shifting to non-RT again, the second finite RT and non-RT It is conceivable that the game can be played in a loop.

In this case, when the non-RT is changed to the first finite RT, the advantageous section ends when the finite RT of 20 games is exhausted, but when the non-RT is changed to the second finite RT, the finite of 60 games is finite. After digesting RT, it is possible to give a feeling of expectation to shift from non-RT to the second RT again. As described above, it is not possible to add an advantageous section by winning a combination having a setting difference in the advantageous section, but in the case of such playability, if there is a setting difference in a specific replay, there is a case. However, there is no problem because it only serves as a transition role to a finite RT with a different number of games. In this way, by devising the end condition of the advantageous section, a substantial addition of 20 games or 60 games by the winning combination having a setting difference (transition of 20 games to the first finite RT, or a second of 60 games). (Transition to finite RT) can be realized.

(2) Example in which the end condition of the advantageous section is set to the digestion of CZ or the transition from non-RT to RT1 after the end of the special game By setting the end condition of such an advantageous section, for example, during the advantageous section A maximum of 32 games of CZ are executed, and the conditions for clearing this CZ are set as the winning of a special role. Then, if 32 games are digested without winning a special role during CZ, the advantageous section ends. On the other hand, if a special role is won during CZ, after the special game is completed, the game is shifted to non-RT. Depending on the order, the symbol combination that shifts to RT1 or the symbol combination that shifts to RT2 is displayed.

Then, "the transition from non-RT to RT1 after the end of the special game" is set as the end condition of the advantageous section. Therefore, when the specific replay is won, if the player shifts to RT1 depending on the push order, the advantageous section ends. On the other hand, when the game shifts from non-RT to RT2 after the end of the special game, AT is started. Here, depending on the control state and the winning combination, it is possible to notify the push order of shifting to RT2 at the time of winning a specific replay having no setting difference. This means that the special role won during CZ is not limited to the special role having no setting difference, and may be a special role having a setting difference. By winning a special combination regardless of the presence or absence of a setting difference during CZ in the advantageous section, it is possible to substantially grant AT (identification of winning during non-RT after the end of the special game) By replaying, it is possible to notify the push order in which the symbol combination that shifts to RT2 is displayed).

Further, in the above-mentioned examples (1) and (2), although RT is used as the control state, various control states may be used instead of RT. For example, in the example of (1), a non-RT and two types of finite RTs (first finite RT and second finite RT) having different numbers of games are adopted, and these are used as a game state 1, a game state 2, and a game. It may be replaced with the state 3. Here, the game state is a control state executed during the advantageous section and is the above-mentioned CZ, AT, or the like, but unlike RT, the winning probability of the replay does not fluctuate.
By this replacement, the game state 1 in which the instruction function does not operate in the advantageous section, the game state 2 in 20 games in which the instruction function operates in the advantageous section, and the game state 3 in 60 games in which the instruction function operates in the advantageous section can be obtained. .. Also, unlike RT, there are no restrictions on the transition conditions (for example, a specific symbol combination is displayed, special role winning, special role winning, end of special game, digestion of the number of games, etc.), so various conditions are free. Can be set to.
Specifically, taking the above (1) as an example, conditions such as "winning the bell 5 times within 20 games" and "winning the bell 3 games in a row" in the game state 1 in the advantageous section. It is also possible to design so as to shift to the game state 2 when the above is achieved.

<Sixth Embodiment>
In the sixth embodiment, when the advantageous section approaches the upper limit of 1500 games during AT, the advantageous section is terminated before the upper limit of 1500 games is reached, and the advantageous section is relatively advantageous after the end of the advantageous section. By providing a situation in which it is easy to win a section and an AT, it is possible to repeatedly execute an advantageous section and an AT that does not reach the maximum number of games. As a result, it is possible to create an advantageous section in which the upper limit of 1500 games is executed and a more advantageous state than AT.

FIG. 62 is a diagram showing the RT transition in the sixth embodiment, and is a diagram corresponding to FIG. 22 in the first embodiment. In the RT transition diagram of the sixth embodiment, the difference from the first embodiment is that it has RT6. RT6 is a finite RT and ends with the digestion of 50 games.
RT6 can be migrated only from RT3. Further, after the end of RT6, it shifts to non-RT.

In the sixth embodiment, in any RT except the internal section (RT4), a lottery for transition to an advantageous section is performed during the normal section. In addition, the transition lottery from the normal section to the advantageous section is executed regardless of the winning of the conditional device. That is, the lottery of the advantageous section is executed without being linked to the winning of the conditional device having no setting difference. The winning probability is "1/32", which is common to all RTs.

In addition, after the 1BBA operation and the 1BBB operation are completed, the user has the right to execute the AT. After the operation of 1BBA is completed, it shifts to non-RT, and after the operation of 1BBB is completed, it shifts to RT1. Further, when the pattern symbol is displayed in non-RT or RT1, the process shifts to RT2. After that, it goes back and forth between RT2 and RT3 (here, it is assumed that the rare case of accidentally shifting from RT3 to RT6 is not considered).

In the above, in the non-RT, RT1, RT2, and RT3, the transition lottery to the advantageous section is executed with the winning probability of "1/32". Therefore, if the transition lottery to the advantageous section is won, 1BBA operation or 1BBB is performed. In the situation where the execution right of AT is held based on the operation, the advantageous section and AT are started. Since AT can be executed on condition that it is an advantageous section (because it is necessary to activate the instruction function), it is advantageous to shift to non-RT or RT1 after the operation of 1BBA or 1BBB is completed, respectively. Before winning the section, AT will not start even if you have the right to AT.

When the advantageous section and AT are started in non-RT or RT1, the instruction function is not activated at the time of winning the small winning combination B group until the pattern symbol is displayed. This is to display the pattern and to shift to RT2 as soon as possible. When the small winning combination C group is won, the instruction function is activated. After shifting from non-RT or RT1 to RT2, the instruction function is activated in both the small winning combination B group and the small winning combination C group. Further, when the replay B group is won in RT2, the instruction function is activated so as to shift to RT3. In this way, the AT is executed until the end condition of the AT is satisfied.

In the sixth embodiment, unlike the first embodiment, in RT3, the replay D group is drawn instead of the replay C group. FIG. 63 is a diagram showing the type of the replay D group drawn in RT3, the winning combination, and the relationship between the pushing order and the display combination, and is a diagram corresponding to FIG. 13 of the first embodiment.
The replay D group has replays D1 to D3, and replays D1 to D3 include replay 01, replay 03, and replay 06, respectively.
Then, in the case where any of the replay D groups is won, the replay 01 wins in one push order, the replay 03 wins in the other push order, and the replay 06 wins in the other push order. Is set to win a prize.

Here, the point that RT3 is maintained when replay 01 is displayed in RT3 and falls to RT2 when replay 02 is displayed is the same as in the replay C group of the first embodiment. On the other hand, when the replay 06 wins in RT3, it shifts to RT6 (see FIG. 62).
In the sixth embodiment, unlike the first embodiment, the lottery for replay 06 is not performed during the operation of 1BBA and the operation of 1BBB. In the sixth embodiment, the replay 06 is included only in the replay D group.

In the sixth embodiment, in the case of staying in RT3 and having an advantageous section and AT, when the number of games played in the advantageous section is less than "1400" and the replay D group is won, the replay 01 is won. The push order to be operated, that is, the push order to maintain RT3 is displayed by the operation of the instruction function.
On the other hand, in the case of staying in RT3 and having an advantageous section and AT, when the number of digestion games in the advantageous section is "1400" or more, that is, when the remaining advantageous section is "100" games or less. Displays the push order for winning the replay 06 by the operation of the instruction function in the subsequent games in which the replay D group is won.

As a result, the replay 06 wins in the game, so the game shifts to RT6 from the next game. The transition from RT3 to RT6 is set in the advantageous section and the end condition of AT. Therefore, with the transition to RT6, the advantageous section and AT are terminated.
As described above, since the replay D group is a duplicate winning of the replay that has the possibility of shifting the RT, it is desirable that there is no setting difference (of course, there is a setting difference in the winning probability of the replay D group). It does not prevent you from doing it).

RT6 is a finite RT, and 50 games are executed. When 50 games are digested in RT6, it is judged that the end condition of RT6 is satisfied, and the game shifts to non-RT.
Further, as described above, in RT6 as well, as in other RTs, a lottery of an advantageous section is performed with a winning probability of "1/32". Then, if the advantageous section is won in RT6, the right to execute AT is granted. That is, when the number of games in the advantageous section becomes "1400" or more in RT3 and the game shifts to RT6, the advantageous section and AT are terminated, and "winning the lottery in the advantageous section in RT6" is the execution (restart) of AT. ) It is set in the condition.
In RT6, the winning probability of the advantageous section is "1/32" and the number of games is "50". Therefore, the probability of winning the advantageous section during RT6 is about 79.6%.

When the advantageous section is won in RT6, it becomes an advantageous section from the next game and the execution condition of AT is satisfied. In this case, the AT may start at any time. For example, the AT may be started during the next game of the game won in the advantageous section, that is, while staying at RT6. Alternatively, the AT may be started from the non-RT when the transition to the non-RT, or further, the AT may be started after the transition from the non-RT to the RT2. Here, for the sake of simplification of the explanation, it is assumed that the AT is started from the next game of the game in which the advantageous section is won.

In RT6, when the advantageous section and the AT are started at the same time from the next game of the game won in the advantageous section, the AT can be continued up to the limit of 1500 games, which is the maximum number of games in the advantageous section. Can be done. Since 1500 games in the advantageous section are counted even in the control state such as precursors and CZ performed in the advantageous section, the AT is compared with the game playability in which the AT is performed via such a control state. It can be executed for a long time.

When RT6 ends, it shifts to non-RT. Non-RT continues until the pattern symbol is displayed. Then, when the pattern symbol is displayed in the non-RT, the process shifts to RT2. When the lottery of the advantageous section is won in RT6, the push order for activating the instruction function and shifting to RT3 at the time of winning the replay B group is displayed in RT2.

Then, when the AT is won in RT6, when the transition to RT3 is performed, AT is executed while maintaining RT3. AT is executed up to a predetermined number of games. When the AT is completed a predetermined number of games, the AT is ended and the advantageous section is ended, and the normal section is started from the next game.
An initial value of the number of AT games is determined when the AT is won, and the number of games is added by the above-mentioned addition during AT execution. Then, during the execution of AT, when 1400 games or more have been played since the start of the advantageous section, the game is shifted to RT6 in the same manner as described above.

On the other hand, during the normal section, the lottery for the advantageous section is also performed in RT2 and RT3 with a winning probability of "1/32". That is, in the sixth embodiment, the lottery of the advantageous section is performed with a probability of "1/32" regardless of staying in any RT except RT4, and if the lottery of the advantageous section is won, the advantageous section is started from the next game. Move to.

In RT2 and RT3, when only the transition to the advantageous section is performed, the instruction function is activated at the time of winning the first small winning combination B group. As a result, since the condition that the advantageous section of "execution of the instruction function operating game at least once" can be terminated is satisfied, the advantageous section is terminated in the game, and the game shifts from the next game to the normal section.
Therefore, in RT2 and RT3 (normal section) that do not go through 1BBA game or 1BBB game, an advantageous section is drawn with a winning probability of "1/32", and if the advantageous section is won, the advantageous section is started from the next game, and the advantageous section is started. When the instruction function operating game (when the small winning combination B group is won) is executed once in the section, the transition from the next game to the normal section is repeated.
Not limited to this, when shifting to the advantageous section, the predetermined number of games (for example, 32 games) may be continued, and after the predetermined number of games has been exhausted, the section may shift to the normal section. In this case, it is necessary to execute the instruction function operating game at least once in a predetermined number of games.

Further, in RT2 and RT3 (so-called normal), an AT lottery is separately executed. Then, when the AT lottery is won, the player has the right to execute the AT. For example, when the small winning combination E1 shown in the first embodiment is won, it is possible to have the right to execute the AT. Alternatively, when the small winning combination E1 is won, it may be decided by lottery whether or not to grant the execution right of the AT, and when the lottery is won, the execution right of the AT may be granted.
The initial value of the number of AT games is set first, and then the number of games is added by performing an additional lottery as shown in the third embodiment.

Further, if the game in which the AT is won is an advantageous section, the advantageous section and the AT can be started from the next game. The AT may be started from the next game of the game in which the AT is won, or as shown in the fifth embodiment, the AT may be started after passing through a precursor or a CZ. After starting the AT, the AT is executed while staying at the RT3 in the same manner as described above (ART). If the AT is still ongoing even after 1400 games or more after the transition to the advantageous section, the transition to RT6 is performed in the same manner as described above.
On the other hand, if the game won in the AT is a normal section, the player has the right to execute the AT and waits to win the advantageous section. Then, when the advantageous section is won, AT is executed thereafter.

Further, when the AT lottery is performed as described above during the stay of RT2 or RT3, it is possible to set the AT start condition to be via RT6.
Therefore, in RT2 and RT3, "the right to execute AT" is given based on the fact that the small winning combination E1 or the like is won. When this right is won, if it is not an advantageous section, wait for the advantageous section to be won, if it becomes an advantageous section or if it is an advantageous section, activate the instruction function, and if it is RT2, replay group B The push order to shift to RT3 at the time of winning is displayed. Further, when it is RT3, the push order for shifting to RT6 is displayed when the replay D group is won. When shifting to RT6, the advantageous section ends as described above. Then, when the advantageous section is won between the 50 games of RT6, it is assumed that the start condition of AT is satisfied. The flow after the AT start condition is satisfied in RT6 is the same as described above.

The lottery for the advantageous section is not limited to the above, and a specific combination having a winning probability of "1/32" may be drawn at all RTs, and the advantageous section may be started based on the winning of this specific combination. .. The specific combination in this case is a combination having no setting difference as described in the first embodiment.

When the above sixth embodiment is rearranged, it has the following features (including effects).
(1) By intentionally ending the advantageous section and shifting to the re-lottery state of the advantageous section before reaching the upper limit of the advantageous section (1500 games), 1500 games, which is the upper limit of the advantageous section, can be effectively achieved. It is possible to execute an advantageous section beyond that. For example, a game such as "advantageous section (1200 games)-> non-advantageous section (50 games)-> advantageous section (1200 games)" is possible.
In particular, since the transition to RT6 (finite RT) is set as the end condition of the advantageous section, the advantageous section ends when the transition from RT3 to RT6, but during the 50 games of RT6, the replay winning probability is A high favorable condition can be maintained.
(2) In addition, at normal times, a lottery for transition to an advantageous section is performed with a winning probability of "1/32" for each game. In particular, as an opportunity to shift to an advantageous section, a transition opportunity that does not have a setting difference is required, but in both RT6 and normal times, a lottery to shift to an advantageous section is always made with a winning probability of "1/32". It can be realized by doing.

Furthermore, depending on the design, "start of AT = start of advantageous section" can be set as in the third embodiment. Therefore, 1500 games, which is the maximum number of games in the advantageous section, are fully used, for example, 1500 games. AT becomes feasible (except when starting AT when a special role is won).
(3) At the time of transition to the advantageous section, it is possible to determine whether or not to execute the AT by referring to the RT being executed. The transition lottery of the advantageous section is performed with the winning probability of each game "1/32", but when winning this transition lottery, refer to the RT (whether or not it is RT6) staying at the time of winning. Therefore, it is possible to determine whether or not to execute AT at the time of transition to the advantageous section.

<7th Embodiment>
The seventh embodiment brings benefits to the player even when the total number of games played by the AT exceeds "1500" as a result of adding the number of games during the AT, and further, the total number of games of the AT. It is a feature that the more times the number of games is added exceeding "1500", the more the player is benefited.

In the seventh embodiment, the "over 1500 counter" is provided, which counts the number of times the total number of games of the AT exceeds "1500" due to the addition during the AT. At the start of the advantageous section and AT, the counter value over 1500 is "0".
Further, in the seventh embodiment, as shown in FIG. 44 (Example 2) of the third embodiment, when the total number of AT games exceeds "1500" as a result of the additional lottery, the determined additional number is used. It shall be cleared without adding.

Therefore, when the total number of AT games is "1500" or less, the counter over 1500 remains "0". Here, for example, in step S451 of FIG. 44 (b), if it is determined that the number of additions exceeds the specified number, the “over 1500 counter” changes from “0” to “1”. Similarly, after that, in step S451 of FIG. 44 (b), when it is determined that the number of additions exceeds the specified number, the “over 1500 counter” changes from “1” to “2”. In this way, every time the total number of AT games exceeds "1500", a counter over 1500 is added.

On the other hand, in the seventh embodiment, after the advantageous section and the AT are started, the game at the time of winning the first small winning combination B group activates the instruction function. After that, when the counter over 1500 is "0", that is, when the total number of AT games has never exceeded "1500" by the lottery, whether to activate the instruction function when the small winning combination B group is won. Whether or not to decide by lottery.
Here, the rate at which the instruction function is activated when the small winning combination B group is won is referred to as an "instruction function operation rate".

Then, the instruction function operating rate when the counter over 1500 is "0" is set to "95%". Therefore, during the advantageous section and during AT, when the small winning combination B group is won, for example, a lottery for whether or not to activate the instruction function (a lottery for winning at 95%) is performed. As a result, the instruction function is activated with a probability of 95%, and the instruction function is not activated with a probability of 5%. Assuming that the winning rate of the small winning combination B group when the instruction function is activated is 100% and the winning rate of the small winning combination B group when the instruction function is not activated is "1/3", the instruction function operating rate is 95%. The winning rate of the small role B group in the above is about 96.7%.

Next, it is assumed that the total number of AT games exceeds "1500" as a result of the addition during AT. Then, it is assumed that the counter over 1500 becomes "1". Here, the instruction function operating rate when the counter over 1500 is "1" is set to "97.5%". Therefore, in the advantageous section and during AT, when the small winning combination B group is won, the instruction function is activated with a probability of 97.5%, and the instruction function is not activated with a probability of 2.5%.

After that, as a result of further addition, when the total number of AT games exceeds "1500" again, the counter over 1500 becomes "2". The instruction function operation rate in this case is set to "98.75%". Therefore, in the advantageous section and during AT, when the small winning combination B group is won, the instruction function is activated with a probability of 98.75%, and the instruction function is not activated with a probability of 1.25%.
As described above, for the counter values over 1500 = "0", "1", "2", ..., The instruction function operating rate = "95", "97.5", "98.75". , ... is defined.

With the above settings, the more the total number of AT games exceeds "1500", that is, the larger the counter value over 1500, the closer the instruction function operation rate becomes to 100%. Here, even if the total number of AT games exceeds "1500", the upper limit of the advantageous section is actually "1500", so it is certain that the games exceeding "1500" cannot be executed. Is. However, according to the seventh embodiment, when the total number of AT games exceeds "1500", it is more advantageous to the player than before the addition (expected number of acquired cards). It is possible to set to increase the value).

<8th Embodiment>
In the eighth embodiment, the winning of the BB having no setting difference in the winning probability (for example, in the first embodiment, the single winning of 1BBA, the overlapping winning of 1BBA and the small winning combination D, and the overlapping of the 1BBA and the small winning combination E1). When it is decided to shift to the advantageous section based on the winning), the advantageous section is started after that. In addition, there is a case where AT is started after the end of the BB game.
Further, regarding the end of the advantageous section, the following Examples 1 to 5 can be mentioned.
(1) An example in which the advantageous section ends before the end of the 1BB game (Example 1)
(2) An example in which the advantageous section ends at the end of the 1BB game (Example 2)
(3) An example in which the advantageous section does not end at the end of the 1BB game, the AT starts after the end of the 1BB game, and the advantageous section also ends at the end of the AT (Example 3).
(4) An example in which the advantageous section does not end at the end of the 1BB game, and the advantageous section ends after the lapse of a predetermined number of games (for example, 5 games) after the end of the 1BB game (Example 4).
(5) An example in which the advantageous section does not end at the end of the 1BB game, the AT is started after a predetermined number of games (for example, 5 games) have elapsed since the end of the 1BB game, and the advantageous section also ends at the end of the AT (Example 5).
Then, when it is decided to shift to the advantageous section, it is determined at the same time which of Examples 1 to 5 ends the advantageous section. Of course, it is not necessary to determine from the five of Examples 1 to 5, for example, it may be determined from the three of Examples 1 to 3, or it may be determined from the two of Examples 2 and 3. You may.

64 to 66 are time charts showing Examples 1 to 5 described above.
In Example 1 of FIG. 64, after winning 1BBA, the advantageous section is started from the start of the 1BBA game (when the 1BBA is activated). The start timing of this advantageous section is at the start of the 1BBA game, but as described in the first embodiment, from the start of the next game of the game in which the 1BBA is won to the start of the next game of the game in which the 1BBA wins (1BBA). The advantageous section may be started at any timing as long as it is until (at the start of the first game of 1BBA game). Further, as described in the first embodiment, when the advantageous section is started, the advantageous section display LED 77 is turned on.
Further, the advantageous section is started at the same time as the start of the 1BBA game, but the AT is not started because the 1BBA is in operation (in the first place, in Example 1, the AT is not started during the advantageous section).

Then, in Example 1, the advantageous section ends before the end of the 1BBA game, for example, at the end of the previous game of the final game of the 1BBA game, or at the start of the final game of the 1BBA game.
Further, in this example 1, the output of the continuous effect is started from the middle of the 1BBA game. Similar to the first embodiment, the continuous production is a series of productions over a plurality of games (a production that raises the expectation of whether or not the AT will be executed after the end of the 1BBA game), and at the end of the continuous production, 1 Outputs an effect of notifying the player whether or not to start AT after the end of the BBA game. In addition, the advantageous section ends when the continuous production ends.

Therefore, in Example 1, in the middle of the final game of the 1BBA game or in the previous game, the continuous production is ended (finally, it is notified that the AT is not started), and at the end of the game in which the continuous production is finished, or continuously. When the production is finished, the advantageous section is finished. In Example 1, the advantageous section is ended before the end of the 1BBA game, and AT is not started after the end of the 1BBA game.
However, at the start of the 1BBA game, even if it is decided to end the advantageous section before the end of the 1BBA game, a rare role (for example, a small role D) is won during the 1BBA game, etc. When the condition for extending the advantageous section (also referred to as the condition for changing the advantageous section; the same applies hereinafter) is satisfied, the advantageous section is not ended before the end of the 1BBA game, and the advantageous section is continued even after the end of the 1BBA game. good. Of course, AT may be started after the end of the 1BBA game. For example, changing the end of the advantageous section from Example 1 to Example 3 can be mentioned.

Example 2 of FIG. 64 is an example in which the end time of the 1BBA game and the end time of the advantageous section are matched. In this example 2, as in the case of the first example, the continuous production is started from the middle of the 1BBA game, and at the end of the final game of the 1BBA game (may be when the last stop switch 42 is operated, etc.), the 1BBA game. Notifies whether or not to start the AT game after the end of. In Example 2, since the advantageous section ends at the same time as the end of the 1BBA game, the AT is not started after the end of the 1BBA game. Therefore, at the end of the continuous production, it is notified that the AT will not be started.

When the advantageous section ends by the end of the special game (1BBA game) as in Example 1 and Example 2, the advantageous section ends even if the instruction function operating game has not been performed even once. It is possible. This is because many medals have already been won during the special game (1BBA game), so it is not necessary to postpone the end of the advantageous section just for performing one instruction function operating game. Rather, the extension may increase player dissatisfaction.
Further, as in Example 1, at the start of the 1BBA game, even when it is decided to end the advantageous section at the end of the 1BBA game, when the extension condition of the advantageous section is satisfied during the 1BBA game ( For example, when a rare role is won), the advantageous section may not be ended at the end of the 1BBA game, and the advantageous section may be continued even after the end of the 1BBA game. Of course, AT may be started after the end of the 1BBA game. For example, changing the end of the advantageous section from Example 2 to Example 3 can be mentioned.

In Example 3 of FIG. 65, as in Example 2, continuous production is started from the middle of the 1BBA game. Example 3 is an example in which AT is started after the end of the 1BBA game. In this case, at the end of the final game of the 1BBA game (may be when the last stop switch 42 is operated, etc.), it is notified that the AT will be started after the end of the 1BBA game. Then, the AT is started from the next game of the final game of the 1BBA game. Of course, it is not necessary to start AT immediately after the end of the 1BBA game. For example, the AT may be started from the next game of the game shifted to RT3, the next game of the game shifted to RT3, or the next game of the game won in any of the replay B group. In this case, it is preferable that at least the instruction function for shifting to RT3 is activated even before the start of AT.
The AT ends when the end conditions of the AT such as the digestion of the predetermined number of games are satisfied, and the advantageous section also ends at the same time when the AT ends. However, even if the AT is terminated, the advantageous section may be continued thereafter.

Whether it is the above Example 1, Example 2, or Example 3 is not known at the start of the 1BBA game, but at the start of the 1BBA game, the advantageous section display LED 77 lights up, so that it is possible to shift to the advantageous section. When it is decided, the advantageous section display LED 77 lights up (determined to shift to the advantageous section) or does not light up (advantageous section) at the start of the 1BBA game, as in the case where it was always made to be Example 3. It is possible to arouse the expectation of the player even during the 1BBA game by eliminating the monotonous playability that arouses the expectation just because it is decided not to shift to.

In Example 4 of FIG. 66, the advantageous section is continued even after the end of the 1BBA game, the continuous production is started after the end of the 1BBA game, and in the continuous production, whether or not to start AT from now on (the advantageous section continues). This is an example of notifying (whether or not to do). After the end of the 1BBA game, the continuous production is started, and Example 4 shows an example in which the continuous production is performed for 5 games. Of course, the continuous production may be any number of games. Then, in the final game of the continuous production, it is notified whether or not to start the AT. Example 4 shows an example in which AT is not started. Then, the advantageous section ends with the game at the end of the continuous production. Of course, the continuous production may be started from the next game after the end of the 1BBA game, or may be started from the next game or the like.

As described above, in Example 4, the advantageous section is continued even after the end of the 1BBA game, and the advantageous section is executed for 5 games during the normal game (the game after the end of the 1BBA game).
On the other hand, as described above, it is necessary to "execute the instruction function operating game at least once during the advantageous section".
Here, when it is decided to shift to the advantageous section based on the winning of the BB, and the advantageous section is started at the same time (of course, not necessarily at the same time) as the start of the BB game, the end of the BB game. Later, when ending the advantageous section in several games, it is conceivable to control as follows.

(1) If the small winning combination B group is never won between the five games, the advantageous section is ended without executing the instruction function operating game even once.
(2) When the small winning combination B group is won during the five games, the instruction function operating game is executed in that game.
(3) Even when the small winning combination B group is won during the five games, the advantageous section is ended without executing the instruction function operating game.
(4) If you have never won the small role B group between the 5 games, extend the advantageous section until you first win the small role B group, and instruct when you first win the small role B group. The function-operated game is executed, and the advantageous section is ended in the game.
Any of the above controls may be used.
As described above, since it is necessary to "execute the instruction function operating game at least once during the advantageous section", the control of (1) to (3) may seem unfavorable, but in Example 4. As described above, when the BB game is performed during the advantageous section, many medals have already been won during the BB game, so the end of the advantageous section is terminated only for one instruction function operation game. This is because it is considered that there is no need to extend it. Rather, the extension may increase player dissatisfaction.
In Example 4 of FIG. 66, the case where an instruction is given (the instruction function operating game is executed) during the five games is shown by a two-dot chain line.

In Example 5 of FIG. 66, similarly to Example 4, the advantageous section is continued even after the end of the 1BBA game, the continuous production is started after the end of the 1BBA game, and whether or not the AT is started by the continuous production is determined. This is an example of notifying. Then, in Example 5, it is notified that the AT will be started in the final game of the continuous production. Then, from the next game, AT is started. When the AT ends, the advantageous section also ends. Of course, it is not necessary to start AT from the next game. For example, the AT may be started from the next game of the game shifted to RT3, the next game of the game shifted to RT3, the next game of the game won in any of the replay B group, and the like. In this case, it is preferable that at least the instruction function for shifting to RT3 is activated even before the start of AT.
Whether it is the above Example 4 or Example 5 is not known at the start of the 1BBA game, but at the start of the 1BBA game, the advantageous section display LED77 lights up, so that both during the 1BBA game and after the end of the 1BB game It is possible to fuel the expectations of the player.

In the eighth embodiment, whether or not to execute the AT (Examples 1 to 5) and the initial number of games of the AT are set before the start of the 1BBA game (for example, when the 1BBA is won) or the start of the 1BBA game. Occasionally, it may be decided by lottery or the like, or it may be decided whether or not to execute the AT based on the conditional device won during the 1BBA game. For example, when 1BBA is won, it is decided in Example 1, Example 2, or Example 4, and it is decided whether or not to change to Example 3 or Example 5 based on the conditional device won during the 1BBA game. .. Further, for example, when the "1BBA + small winning combination E1" in the first embodiment is won, the AT may be confirmed (Example 3 or Example 5).
Furthermore, whether or not to execute the AT and the initial number of games of the AT may be determined based on the conditions satisfied during the 1BBA game. After deciding to execute the AT (in the case of Example 3 or Example 5), the number of AT games may be added during the 1BBA game or during the AT based on the winning of the conditional device.
Further, although it was determined as in Example 4 at the start of the 1BBA game, when the condition for extending the advantageous section is satisfied during the 1BBA game or during the continuous production period of the 5 games after the end of the 1BBA game (for example,). (At the time of winning the rare role) may be changed to Example 5 (execution of AT).

At the start of the 1BBA game, it is not necessary to determine whether or not to execute the AT after the end of the 1BBA game. In this case, it is determined whether or not to execute the AT after the end of the 1BBA game depending on whether or not the extension condition of the advantageous section is satisfied during the 1BBA game.
When deciding whether or not to execute AT after the end of the 1BBA game during the 1BBA game, the end of the advantageous section is set at the end of the 1BBA game as shown in Example 2 of FIG. Then, when it is decided to execute the AT during the 1BBA game, the end of the advantageous section is extended (changed), and the advantageous section is continued even after the end of the 1BBA game, and the AT is executed.

<9th embodiment>
The ninth embodiment defines when to start the advantageous section (timing to start the advantageous section) when the advantageous section is started based on the winning of the conditional device including the special combination (for example, 1BBA). Yes, in particular, it is characterized in that the advantageous section is started from the game in which the winning special role can win a prize.
In the ninth embodiment, as in the first embodiment, the condition device including the winning of the special combination (1BBA) is won, and the advantageous section is started based on the decision to shift to the advantageous section. Here, in the first embodiment, when the condition device including the special combination is won and it is decided to shift to the advantageous section, the betting state and the settlement possible state in the next game of the winning game are set. By that time, you can bet in the next game of the game in which the advantageous section display LED 77 is turned on or the combination of symbols corresponding to the special combination is stopped (or the combination of symbols corresponding to the special combination is stopped). The advantageous section display LED 77 is turned on when the state and the state where the payment can be made are reached).

Further, the advantageous section is started at the start of the next game (when the start switch 41 is operated) of the game in which the condition device including the special combination is won, or at the start of the first game of the special game (for example, 1BBA game) (for example, 1BBA game). It was (when the start switch 41 was operated). Therefore, in the latter case, when the advantageous section is started based on the winning of the special combination, the start timing has a range.
Then, in the ninth embodiment, when the condition device including the special combination is won and it is decided to shift to the advantageous section, the advantageous section is started from the game in which the special combination can win a prize. do.

Therefore, for example, in the first embodiment, when 1BBA is won alone, 1BBA can be won in the game, so that the advantageous section is started from the game.
On the other hand, when "1BBA + small winning combination E1" is won, the winning of the small winning combination E1 is prioritized in the game, and the combination of symbols corresponding to 1BBA cannot be stopped. do not. In particular, in the first embodiment, in the game in which "1BBA + small winning combination E1" is won, the winning of the small winning combination E1 is prioritized over 1BBA, and the small winning combination E1 is "PB = 1". 1BBA never wins. The 1BBA won in the game will be carried over to the next game.

Furthermore, when "1BBA + small winning combination D" is won, the winning of the small winning combination D is prioritized in the game, but the small winning combination 35 (watermelon) corresponding to the small winning combination D is "PB ≠ 1". Therefore, when the stop switch 42 is operated at the timing when the symbol related to the small winning combination 35 (“watermelon”) cannot be stopped and at the timing when the symbol related to 1BBA (“red 7”) can be stopped, 1BBA is set in the game. It is possible to win a prize. For example, in FIG. 5, the middle stop switch 42 is operated at the timing when the middle first stop is set and the third “red 7” can stop at the effective line.

However, when the stop switch 42 is operated at a position where both the symbols of 1BBA and the small winning combination 35 can be stopped, the priority is given to stopping the symbols related to the small winning combination 35. For example, it is the case where the right stop switch 42 is operated at the timing when both the 2nd "red 7" and the 5th "watermelon" can be stopped at the effective line with the right first stop.
On the other hand, at the time of the first left stop, even if the left stop switch 42 is operated at the timing when the 7th "red 7" can stop at the effective line, the 4th or 9th "watermelon" is stopped at the effective line. Is prioritized, so the 7th "Red 7" does not stop at the valid line.
Therefore, when the left stop switch 42 is operated at the above timing, the stop control that does not substantially stop the 7th "red 7" on the effective line is executed. As a result, the game at the time of winning "1BBA + small winning combination D" in the first embodiment is set so as not to correspond to "a game in which 1BBA can be won". Of course, when the middle stop switch 42 is operated at the timing when the middle first stop is set and the third "red 7" can stop at the effective line, 1 BBA can be won in the game, so "1 BBA". May be a game that can win a prize.

If it is decided to win a conditional device including a special role and shift to an advantageous section, and the game does not correspond to a game in which a special role can be won, for example, in the lottery of the conditional device in the next game, for example. In the case of non-winning, the special role carried over from winning can be won, so the advantageous section is started from the game. In the above example, when the start switch 41 is operated in the next game, the lottery of the condition device is performed and the player is not elected. Therefore, the advantageous section immediately after the start switch 41 is operated and the lottery of the condition device is performed. (At the same time or just before that, the advantageous section display LED 77 lights up).

On the other hand, as a result of winning a small role or replay in the next game and giving priority to winning the small role or replay won in the game, the advantageous section is not started in the game in which the special role cannot be won.
In addition, for example, in a game in which the winning of a special role is carried over, a small role of "PB ≠ 1" is won, and when the small role cannot be won, the special role carrying over the winning can be won. , As in the case of winning the above-mentioned "1BBA + small winning combination D", the advantageous section is not started in the game. Of course, in a game in which a special role carrying over the winning can be won, an advantageous section may be started in the game.

FIG. 67 is a diagram illustrating a flow of the game according to the ninth embodiment. In the example of FIG. 67, an example is shown in which "1BBA + small winning combination E1" is won in the "N" game and 1BBA is won in the "N + 3" game.
First, when "1BBA + small winning combination E1" is won in the "N" game, only the small winning combination E1 can win in the game, and 1BBA cannot win, so that the advantageous section is not started in the game.

Next, after the "N + 1" game, the winning of 1BBA is carried over. In the "N + 1" game, an example of winning Replay A is shown. At the time of winning Replay A, Replay 01 wins with "PB = 1", and 1BBA carrying over the winning cannot win, so the advantageous section is not started in the game.

Next, in the "N + 2" game, an example is shown in which the winning combination is not won by the winning combination lottery means 61. Therefore, in the game, 1 BBA carrying over the winning can be won. Therefore, the advantageous section is started from the "N + 2" game. Here, it is advantageous based on the fact that the "N + 2" game starts, that is, the start switch 41 is operated and the condition device is drawn, and as a result, the player is not elected (1 BBA can be won). Since the section is started, the lighting of the advantageous section display LED 77 is also started when the start switch 41 is operated.

A player who wins 1 BBA in the "N + 2" game can eliminate the wasteful consumption of the number of games in the advantageous section. As described above, the player who has won 1 BBA in the "N + 2" game is an internal medium game that cannot be added (including a lottery for whether or not to execute the AT in the eighth embodiment). It is not necessary to start the advantageous section. Further, as described above, the upper limit number of games (for example, 1500 games) is set for the advantageous section, and when the advantageous section starts in the internal middle game, the maximum advantage that can be executed after the end of the 1BBA game. The number of games in the section is reduced by the amount consumed in the internal games. For example, if 10 games are played in the internal middle game, 1 game is played in the game in which 1 BBA is won, and 16 games are played in the 1 BBA game, in the game after the 1 BBA game, only 1473 games can be played in the advantageous section at the maximum. I can't do it.

However, the player who won 1 BBA in the "N + 2" game does not consume the amount consumed in the internal medium game (0 game in the internal game, 1 game in the game in which 1 BBA is won, 16 games in 1 BBA game). In the game after the 1BBA game is completed, a maximum of 1483 games can be played in the advantageous section), so that the player who could not win the 1BBA in the "N + 2" game , May be advantageous. On the other hand, the player who could not win 1 BBA in the "N + 2" game will continue the internal middle game while starting the advantageous section. The example of FIG. 67 shows an example in which 1 BBA could not be won in the "N + 2" game.

Further, in the "N + 3" game, as in the "N + 2" game, an example is shown in which the winning combination is not won by the winning combination lottery means 61. Therefore, in the game, 1 BBA carrying over the winning can be won. Then, an example in which 1 BBA can be won in the "N + 3" game is shown. As a result, the 1BBA game is started from the "N + 4" game.

Here, for example, if the advantageous section is set to start uniformly from the start of the 1BBA game, the number of games is changed depending on the skill of the player's eyes from the time of winning the 1BBA to the winning (medal consumption). Although there is a difference in the number of medals), there is no difference in the length of the advantageous section after the end of the 1BBA game.
On the other hand, by setting as in the ninth embodiment, the skill of the player (whether or not he / she noticed the winning of the special role, or when he / she knew that the special role was won, he / she became a special role without any mistakes in pressing. The number of games in the advantageous section that is wasted varies depending on whether or not the combination of the corresponding symbols can be stopped at the effective line).

For example, if the special role can be won in the first game in which the special role can be won, the advantageous section will not be wasted in the internal middle game after the advantageous section is started.
On the other hand, in the first game in which a special role can be won, if the special role cannot be won due to a failure to press the button, etc., the special role can be won again in the next game or later. You have to wait until. However, since the advantageous section starts from the first game in which the special role can be won, the advantageous section is wasted during that period.
In this way, the actual number of games played in the advantageous section (the number of games played after the end of the special game) can be made different according to the skill of the player.

Examples of modifications of the ninth embodiment include the following examples.
(Modification example 1)
When it is decided to shift to the advantageous section based on the winning of the special role (or when shifting to the waiting section), the number of games until the transition to the advantageous section is determined by lottery or the like. Then, the game shifts to the advantageous section at the earlier of the game in which the number of games is exhausted, the next game thereof, or the special game starts (the next game of the game in which the combination of symbols corresponding to the special role is stopped). ..
(Modification 2)
When it is decided to shift to the advantageous section based on the winning of the special role (or when shifting to the waiting section), the number of games until the transition to the advantageous section is determined by lottery or the like. Then, the game shifts to the advantageous section, whichever comes first, the game that has exhausted the number of games, the next game, or the first game in which the winning special role can win a prize.

(Modification example 3)
Even if the winning special role starts the advantageous section from the first game in which the winning special role can be won, the end condition of the advantageous section may not be affected.
For example, it is assumed that, based on the winning of the special role, the player wins the advantageous section in which the AT of 50 games is executed after the end of the special game. In this case, for the AT of 50 games after the end of the special game, 50 games are counted at the same time as the start of the AT. Therefore, even if the advantageous section is started from the first game in which the winning special combination can be won, the 50 games of AT start counting at the same time as the start of AT after the end of the special game. On the other hand, the "1500" game, which is the upper limit of the advantageous section, is counted from the first game in which the winning special role can be won. By doing so, as the number of games in the advantageous section approaches 1500 games (as the number of AT games is added), the skill of the player is affected.

(Modification example 4)
In the ninth embodiment, when the condition device including the special combination is won and it is decided to shift to the advantageous section, the advantageous section is started from the game in which the special combination can win a prize. The advantageous section may be started from the next game of the game in which the special role can be won (the advantageous section display LED 77 lights up by the time when the bet is possible and the settlement is possible in the next game. ). By doing so, when the special role is won in the first game in which the special role can be won, the game in which the special role is won is not counted as the game in the advantageous section, so that the player with skill May be even more advantageous than an unskilled player.

In the ninth embodiment, a game in which a condition device (for example, 1BBA + small role E1) including the winning of a special role (1BBA) is won, or a continuous production (for example, 3 games) from the next game to a plurality of games (for example, 3 games) It is an effect of inciting whether or not 1BBA) has been won, and an effect indicating that a special role (1BBA) has been won in the final game) may be output. Of course, the game that won the condition device (for example, small role E1) that does not include the winning of the special role (1BBA), or the continuous production (special role (1BBA)) from the next game to multiple games (for example, 3 games) is won. It is a production that encourages whether or not it is done, and it is necessary to output a production (a production that indicates that the special role (1BBA) has not been won in the final game).

Then, when the continuous effect is output (in particular, before the effect indicating that the special role (1BBA) has been won is performed, for example, when the continuous effect over 3 games is output from the next game, 2 games When 1BBA can be won in the eyes (that is, "N + 2" game), the advantageous section display LED77 lights up for the game, and it is known that the player has won 1BBA. Therefore, instead of this continuous effect, an effect indicating that 1 BBA has been won may be output. When it is the last game of the continuous effect, the continuous effect may be output as it is, or instead of the continuous effect, an effect indicating that 1 BBA has been won may be output.

Alternatively, during the plurality of games in which the continuous effect is output, even if 1 BBA can be won, the advantageous section may not be started and the advantageous section display LED 77 may not be turned on. Specifically, a game that wins a conditional device (for example, 1BBA + small role E1) including a special combination (1BBA), or a predetermined number of games (the same number or more as the number of games that output a continuous effect) from the next game. During the period, even if the special role (1BBA) can be won, the advantageous section is not started (the advantageous section display LED77 is not turned on), but after a predetermined number of games, the special role (1BBA) can be won first. When it becomes, the advantageous section may be started (the advantageous section display LED 77 is also turned on).

<10th Embodiment>
In the tenth embodiment, when 1BBA is won during the execution of AT (that is, during the advantageous section) and the game shifts to the 1BBA game, the game shifts from RT2 to RT3 (returns to AT) after the end of the 1BBA game. At times, it is characterized in that the number of AT games (that is, the number of games in an advantageous section) can be added.
In the tenth embodiment, the RT transition diagram is the same as that of the first embodiment (FIG. 22).
Here, when the AT is being executed in RT3 (for example, when it is decided to shift to the AT of 100 games (that is, the advantageous section) at the time of winning the small winning combination E1 and the AT is being executed), It is assumed that 1BBA is won (either 1BBA alone or 1BBA and small winning combination E1 are duplicated). If 1BBA is won and 1BBA is not won in the game, it shifts to RT4 (inside). Then, when 1BBA wins, it shifts to 1BBA operation (1BBA game). When the end condition during 1BBA operation (1BBA game) is satisfied, the game shifts to non-RT.

1 When the BBA game is completed and the game shifts to non-RT, the AT is restarted from that point, or the AT is being prepared (for example, the game shifted to RT3, the next game of the game shifted to RT3, or the replay B group). The AT is restarted from the next game of the winning game, etc. Therefore, it is preferable to operate at least the instruction function for shifting to RT3 during AT preparation, even before starting AT. Of course, it is an advantageous section even during AT preparation.) When the AT is set to start from that point, when the pattern symbol is displayed in the non-RT, the process shifts to RT2. When any of the replay B groups is won in RT2, the instruction function is activated to display the push order for winning the replay 02. When Replay 02 wins in RT2, it shifts to RT3. Then, after that, AT is continued while maintaining RT3. If RT2 is set during AT preparation, basically, AT is restarted after shifting to RT3.

Here, based on the shift from RT2 to RT3, it is possible to add the number of AT games (that is, the advantageous section). This addition may be performed at all times, or it may be decided by lottery whether or not to add. As an opportunity to add, the replay B group will be elected (that is, it will be added even if it does not shift from RT2 to RT3. Of course, when AT is being prepared, AT can be started from this point. ), Replay 02 winning, and transition from RT2 to RT3.

Further, in the tenth embodiment, the addition can be executed based on the transition from RT2 to RT3 via the non-RT after the end of the 1BBA game. Therefore, the winning of 1BBA, the execution of the 1BBA game, or the non-RT stay is stored. For example, it can be stored using a flag. Then, when shifting from RT2 to RT3 (may be when the replay group B is won or when the replay 02 is won), it is determined whether or not the flag is on, and it is determined that the flag is on. It is possible to add the number of AT games to the condition. In addition, when an additional or additional lottery is executed, the flag is turned from on to off.

In this way, if it is determined whether or not it is possible to add by using the flag, for example, the state of just going back and forth between RT2 and RT3 (simply, during the execution of AT, the push order is mistaken and the process shifts to RT2. (When shifting to RT3 again), since the flag is off, it is not added when shifting from RT2 to RT3.

In the above example, 1BBA is taken as an example, but even when 1BBB, that is, a conditional device including a special combination having a setting difference is won, it can be executed if the above addition is made.
In the same manner as above, the winning of 1BBB, the execution of the 1BBB game, or the stay of RT1 is stored in the flag. Then, after the end of the 1BBB game, when the game shifts from RT1 to RT2 and then to RT3 (may be when the replay B group is won or when the replay 02 wins), the addition can be executed. .. As a result, even when a player wins 1BBB (when the game shifts to 1BBB game), which has a setting difference that should not be able to be added during the winning or BB game, the player is expected to be added. Can be done.

Further, the addition may be made feasible based on the transition from non-RT or RT1 to RT2. For example, the addition may be executed based on the fact that the small winning combination B group is won in non-RT or RT1, the pattern symbol is displayed, and the transition from non-RT or RT1 to RT2.
As shown in FIG. 22, it shifts to non-RT even when the RWM53 is initialized, but since the above-mentioned flag is turned off with the initialization of the RWM53, it shifts from non-RT to RT2 and further from RT2 to RT3. Even if it does, the addition will not be executed. Moreover, if it is a normal section in the first place, the addition is not executed.
Further, when 1BBA or 1BBB is won during the execution of AT and the game shifts to RT4 (internal), the number of AT games is not added to RT4.

Furthermore, in the tenth embodiment (first embodiment), after the end of the 1BBA game, the game shifts to non-RT, and after the end of the 1BBB game, the game shifts to RT1. However, the present invention is not limited to this, and the following methods are also possible.
After the end of the 1BBA game and after the end of the 1BBB game, the game is shifted to RT5 (newly added). Then, in RT5, a condition device that is a duplicate winning of a plurality of replays is drawn, the condition device is won, and it is possible to shift from RT5 to RT3 based on the winning of a predetermined replay. Alternatively, it is possible to shift from RT5 to RT3 based on the fact that the pattern symbol is displayed. In addition, it is set so that non-RT, RT2 and RT3 do not shift to RT5.
In this way, the transition from RT5 to RT3 (the condition device was won in RT5, the predetermined replay was displayed, the small winning combination B group was won in RT5, and the pattern symbol was displayed. Based on this, or the transition from RT5 to RT3), the number of AT games can be added, and it is not necessary to set the above-mentioned flag.

<11th Embodiment>
In the first embodiment, as shown in FIG. 17, as a single winning of the small winning combination E1, the small winning combination E1 (number of positions "250") that shifts to the advantageous section when winning in the normal section and the winning in the normal section are won. Also provided a small winning combination E1 (number of positions "750") that does not shift to the advantageous section.
On the other hand, in the eleventh embodiment, if any small winning combination E1 is won in the normal section, it shifts to the advantageous section. Here, in the eleventh embodiment, the small winning combination E1 having the number "250" is referred to as "small winning combination E1a", and the small winning combination E1 having the number "750" is referred to as "small winning combination E1b".
Further, the small winning combination E2, 1BBA and the small winning combination E2 were deleted.
By doing so, in the game in which the small winning combination 36 wins, the game always shifts from the next game to the advantageous section (by then, the advantageous section display LED 77 lights up).

Further, the advantageous section when the small winning combination E1b is won can be ended only by executing the instruction function operating game once (for example, the instruction function operating game is executed once and then ended in 5 games). be. Such an advantageous section may be referred to as an AT gasse precursor among the AT precursors.
On the other hand, the advantageous section when the small winning combination E1a is won is the advantageous section in which the AT is executed after the AT precursor, and the number of games is after the AT precursor (By the way, the AT precursor is the instruction function operating game once. (Ends in 5 games after execution) 50 games are set. The count of the 50 games may be started immediately after the AT precursor, when the game shifts to RT3 (or the next game), or when the replay group B is won (or the next game). It may be started at, or it may be started by staying at RT3 (or its next game). Further, in the 50 games, when the conditional device (small winning combination B group, small winning combination C group, replay B group, or replay C group) having an advantageous operation mode is won, in principle, the instruction function operating game is executed.

Further, it has a small winning combination E1 (number of positions "250") that shifts to the advantageous section, a small winning combination E1 (number of positions "750") that does not shift to the advantageous section, and a small winning combination E2 that does not shift to the advantageous section. , When the small winning combination E1 (number of positions "250") that shifts to the advantageous section is won, the small winning combination 36 wins the winning game or the next game when the AT of 50 games is shifted to the feasible advantageous section. , There is no point in outputting a continuous production to arouse the expectations of the player as in the past. This is because it is possible to determine whether or not to shift to the advantageous section by looking at whether or not the advantageous section display LED 77 is lit. The eleventh embodiment is conceived in order to output a continuous effect for arousing the expectation of the player as in the conventional case.

FIG. 68 is a time chart showing advantageous sections and the like at the time of winning the small winning combination E1b (Example 1) and the small winning combination E1a (Example 2) in the eleventh embodiment.
In Example 1 of FIG. 68, when the small winning combination E1b is won, the advantageous section is started from the next game (the advantageous section display LED 77 lights up). Then, wait until the small role B group is won. After the start of the advantageous section, in the game in which the first small winning combination B group is won, the instruction function is activated and the advantageous push order is displayed (execution of the instruction function operation game). From the next game of this instruction function operation game, a continuous effect is output (even during the continuous effect, the AT precursor is in progress). Of course, a continuous effect may be output from the instruction function operating game. In this example, the continuous production executes five games. Then, in the fifth game, an effect of whether or not the advantageous section (AT) continues after that is output. When the small role E1b is won, the advantageous section (AT precursor) can be ended in one instruction function operation game, so the advantageous section (AT precursor) is ended in the game in which the continuous production is completed, and the normal section is entered. ..
In addition, when the small winning combination B group is further won between the five games during the continuous production, the instruction function operation game may be executed, but in the present embodiment, the instruction function operation game is not executed.

On the other hand, in Example 2 of FIG. 68, when the small winning combination E1a is won, the advantageous section is started (the advantageous section display LED77 is turned on), and the instruction function operating game is executed in the game in which the first small winning combination B group is won. The continuous production (5 games) from the next game is output (the above is the same as when the small role E1b is won). Then, when the small winning combination E1a is won, the fifth game of the continuous production is output, which means that the advantageous section (AT) is continued thereafter. Then, the AT is started from the next game after the continuous production is completed.
When the small winning combination B group is further won between the five games during the continuous production, the instruction function operating game is not executed as in the case of winning the small winning combination E1b. Of course, if the instruction function operating game is to be executed between the five games during the continuous production after winning the small role E1b, and when the small role B group is won, after winning the small role E1a. It is preferable that the instruction function operating game is executed even when the small winning combination B group is won between the five games during the continuous production of. This is done when the small winning combination E1b is won and when the small winning combination E1a is won. This is because it is possible to determine whether or not to continue the advantageous section (AT) after that.

Here, when the small role E1a is won, it is stipulated that the AT of 50 games is executed. Instead of this, the advantageous section (AT without AT precursor) may be ended at the 50th game from the start of the advantageous section (the next game when the small winning combination E1a is won). Alternatively, after the transition to the advantageous section, 50 games may be counted with the first instruction function operating game as the first game (AT precursors up to the previous game of this game, and AT is started from this game).
Further, 50 games may be counted from the next game of the game in which the winning combination (replay B group including the replay 02) that can be transferred to a specific RT (for example, RT3 in FIG. 22) is won. When the next game that wins the replay that can be transferred to a specific RT is set to 50 games, the game that wins the replay group B notifies the push order for shifting to the specific RT. Furthermore, even if the player does not follow the notification in the game that won the replay B group (even if the replay 02 is not displayed), the AT of 50 games will be executed from the next game. Become. As a result, it is possible to prevent the player from taking a stop operation so as not to intentionally shift to a specific RT.

Furthermore, in the specification that the advantageous section starts from the next game of the game that won the small role E1a, if the small role E1a is won while staying at a specific RT, another from the specific RT. Notification for maintaining a specific RT when a winning combination (pattern symbol 01 to 03 or a winning combination that can display replay 03) that may shift to RT (for example, RT2 in FIG. 22) is won. May be done. Then, the AT count may be started from the game in which the notification for maintaining the specific RT is performed, or the predetermined game (the next game may be used) after the notification for maintaining the specific RT is performed. ) May be used. By setting in this way, the number of games to be transferred to a specific RT after being transferred to another RT can be reduced, which is advantageous up to the upper limit number of advantageous sections (1500 games). You can increase the chances of giving a game.

In the above example, the continuous production is set to 5 games in both the small winning combination E1a and the small winning combination E1b. It may be a game (1 game) that outputs an effect of whether or not to execute. Further, the number of AT games is not limited to 50 games, and may be determined by lottery or the like.
Furthermore, when the small winning combination E1b (number of positions "750") is won, the advantageous section (AT after the sign of AT) is set to execute the AT of 50 games after the AT precursor, and when the small winning combination E1a (number of placements "250") is won, 1 It may be an advantageous section (AT precursor) that can be completed by the instruction function operation game of the times.

Further, when the small winning combination E1a is won, the number of AT games "m" is determined, and when the small winning combination E1a and the small winning combination E1b are won, the number of games "n" until the first instruction function operating game can be executed is determined. It will be decided by lottery. Then, when the number of games "n" is determined, the instruction function is not activated even when the small winning combination B group is won until the number of games "n" has elapsed. After the number of games "n" has elapsed, the instruction function operating game is executed in the game when the first small winning combination B group is won.
Further, when the determined number of games "n" is, for example, "n1" and "n2" (n1 <n2), and the number of AT games determined at the time of winning the small winning combination E1a is "m1". Is easy to determine "n1", and when the determined number of AT games is "m2", which is larger than "m1", "n2" may be easily determined. Further, "n1" may be easily determined even when the small winning combination E1b is won. Further, when the small winning combination E1a is won, "n1" may be more easily determined when the small winning combination E1b is won than when the determined number of AT games is "m1".
In this way, the longer the number of games "n" from the transition to the advantageous section to the execution of the first instruction function operating game, the higher the possibility that the number of games of a larger AT is determined. You can expect it. Of course, the shorter the number of games "n" until the first instruction function operating game is executed, the higher the possibility that the number of games of a larger AT has been determined may be increased.

In the eleventh embodiment, the continuous production is output from the next game when the first small role B group is won. The reason for doing this is that, as in the past, the continuous effect is simply output from the next game of the game in which the small role E1a or the small role E1b is won (the continuous effect executes 5 games). , The advantageous section (AT) when the small role E1a is won may be such that the AT after the AT precursor (by the way, the AT precursor ends in 5 games) ends in 50 games. Even if the advantageous section (AT precursor) when winning E1b is to be completed in 5 games, if the instruction function operating game is not executed even once during the 5 games, it is the 5th game of continuous production. After that, even though the effect indicating that the advantageous section (AT) is not continued is output, there is a possibility that an inconvenience such as the advantageous section (AT precursor) not ending may occur.

Further, even if the advantageous section (AT precursor) when the small winning combination E1b is won is to be terminated by one instruction function operation game, if the instruction function operation game is always executed in the fifth game of continuous production. Therefore, there is a possibility that the advantageous section (AT precursor) will end in the third game of the continuous production, and the advantageous section (AT precursor) will not end even after the fifth game of the continuous production. Because there is. Of course, even if the advantageous section (AT precursor) when the small role E1b is won is terminated in 5 games after one execution of the instruction function operation game, the instruction function operation game is always executed in the first game of the continuous production. This is because there is a possibility that the advantageous section (AT precursor) will not end even after the fifth game of the continuous production because it is not always performed.

However, in the advantageous section (AT) when the small role E1a is won, it is assumed that the AT after the AT precursor (by the way, the AT precursor ends with one execution of the instruction function operating game) ends in 50 games. If the advantageous section (AT precursor) when the small role E1b is won is to be terminated by one instruction function operation game, the continuous production is started from the game that started the advantageous section regardless of which one is won. , The continuous production is continued until the first small role B group is won, and when the first small role B group is won, the instruction function is activated, and in the game or the next game, the advantageous section (AT) is continued. ) May be notified.
In this case, since the number of games until the first small role B group is won is indefinite, the production image meaning that the continuous production used in the continuous production is continued and the advantageous section An effect image meaning that (AT) is not continued and an effect image meaning that the advantageous section (AT) is continued may be prepared and a continuous effect may be output.
In addition, when the small role E1a (small role E1b is also possible) is won during the advantageous section (AT precursor) based on the winning of the small role E1b (for example, during continuous production), the AT of 50 games after the AT precursor. May be changed to execute (continue the advantageous section).

FIG. 69 is a time chart showing Examples 3 and 4 of the eleventh embodiment.
As described above, when the small role E1 is won, the continuous effect is not output until the first small role B group is won, and the continuous effect is output from the next game when the small role B group is won.
On the other hand, in Example 3 of FIG. 69, when the small role E1 is won, the continuous production is not output until the first small role B group is won, and from the next game when the small role B group is won. This is an example in which the continuous effect is not output, and when the small winning combination E1 is won, the advantageous section that ends when the AT of 30 games is executed is started from the next game. Of course, the end condition of the advantageous section in Example 3 is not limited to this, and AT of 30 games (the number of games is free) is executed after the AT precursor (by the way, the AT precursor may end in 5 games). In addition, the end conditions of various advantageous sections described above may be applied. Of course, the advantageous section with different end conditions may be started when the small winning combination E1a is won and when the small winning combination E1b is won.

Further, when the small winning combination E1 is won, there may be a time when the advantageous section is started and a time when the advantageous section is not started. In Example 3 of FIG. 69, after starting the advantageous section, the player never wins the small winning combination B group until the end condition of the initially set advantageous section (for example, executing AT of 30 games) is reached. This is an example. If the small winning combination B group is won before the end condition of the advantageous section is reached and the instruction function operating game is executed, as shown by the alternate long and short dash line in Example 3 of FIG. 69, the advantageous section When the end condition is reached (when the AT of 30 games is executed), the advantageous section is ended.

On the other hand, when the end condition of the advantageous section is reached and the instruction function operating game has not been executed even once (for example, when the small winning combination B group has never been won), then the small winning combination B At least the advantageous section will be extended until the group is elected and the instruction function operating game is executed. In Example 3 of FIG. 69, an example is shown in which the advantageous section is extended, then the instruction function operating game is executed (by winning the small winning combination B group), and the advantageous section is ended in the game. In Example 3, the advantageous section ends in less than 1500 games from the start of the advantageous section.

On the other hand, in Example 4 of FIG. 69, after the advantageous section is started, the instruction function operating game is not executed even once (without winning the small winning combination B group even once), and the upper limit of the advantageous section is 1500. This is an example of reaching a game. In other words, the end condition of the advantageous section was reached, but when the upper limit was reached because the advantageous section was extended, or there was an addition during the advantageous section, the end condition of the advantageous section was not reached and the upper limit was reached. This is an example when it arrives.
In a rare case such as Example 4, unlike the case of Example 3, the advantageous section ends when the upper limit is reached, even if the instruction function operating game is not executed even once. This prioritizes "terminating the advantageous section when the upper limit of the advantageous section (1500 games) is reached" rather than "performing at least one instruction function operating game during the advantageous section". To do. This is because, as in Example 3, when the upper limit of the advantageous section is not reached, even if the advantageous section is extended, if a rare role such as a small role E1 is won during that time, the advantageous section can be reached. It is possible to add, etc. (of course, it is not necessary), but as in Example 4, when the upper limit of the advantageous section is reached, even if the advantageous section is extended, depending on the rare role won during that time. , Because it is not possible to add an advantageous section, etc., the normal section is more advantageous for the player (if a rare role is won during the normal section, a new advantageous section will start. Because there is).

<12th Embodiment>
The twelfth embodiment is when the game continues up to 1500 games, which is the upper limit of the advantageous section (for example, when a small winning combination E1 or the like is won, an addition is performed during the started advantageous section, and the continuation is confirmed. Or, when it is confirmed that the game will be continued due to the 1BB game being performed during the advantageous section, for example, the ending effect is output from the 1450th game (when the upper limit is approached). It is a feature (the point of outputting the ending effect is the same as in Example 3 of FIG. 55 (third embodiment)). The game is not limited to the 1450 game, and various settings such as the 1400 game, the 1470 game, and the like can be set.
Then, the ending effect starts from the 1450th game and ends at the 1500th game. Here, the "ending effect" is, for example, a moving image, which is also called a movie image and is not divided for each game (a moving image in which the time is set in advance, not switching the image for each unit game). ..

By the way, the length of the ending effect is set so that even if the player plays the game at the shortest, it can be seen to the end in exactly 50 games (games in which the advantageous section ends). When it reaches the end, it repeats from the beginning or displays the last image as a still image. As described above, it is preferable that the ending effect is set to a length that allows the player to see the game to the end by the end of the advantageous section even if the player plays the game in the shortest time. At the end of the ending production (at the end of the 1500th game), the total number of medals won in the advantageous section, the difference between the total number of medals won and the total number of medals inserted, and the total number of games (1500 games) are displayed. indicate. Of course, the total number of medals won in the advantageous section (total number of medals won), the difference between the total number of medals won and the total number of medals inserted (total number of medals won), and the total number of games (1500 games) are the ending effects. It may be displayed as another effect output after that (such as an effect output during a freeze executed at the end of the advantageous section (at the end of the 1500th game)) instead of as the end of. ..

FIG. 70 is a time chart showing an example in which the ending effect is started from the 1450th game, the ending effect is ended at the 1500th game, and the advantageous section is ended in the advantageous section.
In FIG. 70, (a) shows an example in which 1BB (1BBA, 1BBB, etc. of the first embodiment) is won in the middle of an advantageous section and a 1BB game is executed. In the example of (a), at the end of the 1BB game, the 1450th game in the advantageous section has not been reached. In such a case, the execution of the 1BB game does not affect the end of the ending effect. Therefore, the ending effect is started from the 1450th game, and the ending effect is ended at the 1500th game (the ending effect ends at the end of the advantageous section).

On the other hand, in FIG. 70, FIG. 70 shows an example in which the ending effect is started from the 1450th game in the advantageous section, then the 1BB is won in the 1490th game, and the 1BB game is executed. Then, an example is shown in which the end of the 1BB game exceeds the 1500 game, which is the upper limit of the advantageous section.
Even in such a case, since there is no exception to the upper limit of the advantageous section, the advantageous section is ended with 1500 games (the advantageous section display LED 77 is turned off). By the way, even when the advantageous section is finished, the freeze is not executed. Therefore, the advantageous section ends in the middle of the 1BB game, and the 1BB game continues even after the end of the advantageous section (which is a normal section).

In such a case, the ending effect in the present embodiment ends at the end of the 1BB game (not at the end of the advantageous section). This is because, as in (a), when the upper limit of the number of games in the advantageous section is reached when not playing 1BB, it is advantageous in the effect output at the end of the ending effect or during the freeze at the end of the advantageous section. It is necessary to display the total number of games played in the section, the total number of acquired cards, etc. (in particular, the number of AT sets executed in the advantageous section, the total number of games played during AT, the total number of acquired cards during AT, etc.). On the other hand, as in (b), when the maximum number of games in the advantageous section is reached during the 1BB game, the 1BB game is executed after that (it is a normal section), and the ending effect ends at this point. In this way, the freeze is executed at the end of the ending effect or at the end of the advantageous section, and in the effect output during the freeze, displaying the total number of games played and the total number of acquired cards in the advantageous section is 1BB. This is not preferable because it interferes with the game.

In the first place, when the 1BB game is finished, the freeze is executed at the end of the production during the 1BB game or at the end of the 1BB game, and in the production output during the freeze, the total number of games and the total number of games during the 1BB game. Since the number of acquired cards is displayed, in the case of (b), even when the maximum number of games in the advantageous section is reached, the ending effect is not finished at this point, and when the 1BB game is finished, The ending effect is finished, and the freeze is executed at the end of the ending effect or at the end of the 1BB game. In the effect output during the freeze, the total number of games and the total number of acquired games in the advantageous section (especially) , The number of AT sets executed in the advantageous section, the total number of games played during AT, the total number of acquired cards during AT, etc.) are considered to be preferable.

Further, since the 1BB game after reaching the upper limit number of games in the advantageous section is a 1BB game in the normal section, strictly speaking, the total number of games played in the advantageous section, the total number of acquired games, etc. (particularly, the game was executed in the advantageous section). If you want to display the number of AT sets, the total number of games during AT, the total number of games acquired during AT, etc., it is better not to include the total number of games and the total number of games acquired during that period (normal section and during 1BB games). However, if it is not particular about the exact display, the total number of games and the total number of acquired games during that period (during the normal section and 1BB game) may be included in the display. The player is more satisfied when the display is included. For example, the advantageous section can only be executed up to 1500 games, but on the display, it exceeds 1500 games, so there is a sense of satisfaction.

Furthermore, during the 1BB game, when the total number of games and the total number of acquisitions during the 1BB game are displayed together with the ending effect, the total number of games and the total number of acquisitions during the advantageous section, etc. (particularly, the advantageous section). When the number of AT sets executed in, the total number of games played during AT, the total number of games acquired during AT, etc.) is displayed, the display is during 1BB games after reaching the maximum number of games in the advantageous section. Will continue. On the other hand, as shown in FIG. 55 (Example 3) described above, at the time of output of the ending effect, the total number of games and the total number of acquired games during the 1BB game, the total number of games and the total number of acquired cards in the advantageous section, etc. (particularly, When the number of AT sets executed in the advantageous section, the total number of games played during AT, the total number of games acquired during AT, etc.) is not displayed, those are during 1BB games after reaching the maximum number of games in the advantageous section. Do not display.

In addition, the length of the ending effect is generally set so that even if the player plays the shortest game, the player can watch the game until the end of the advantageous section (when the game reaches the end, after that). (Repeat from the beginning or display the last image as a still image), but when the ending effect is output even after the advantageous section ends as in the example of (b), the ending effect is repeated from the beginning or The last image of the ending effect may be continuously displayed as a still image.
The ending effect is not to switch the image for each unit game (separate for each game), but for a moving image with a predetermined time, a moving image for dividing each predetermined number of games, or a still image that is not divided for each game. It may be any of a still image or the like that is divided into a predetermined number of games.

<13th Embodiment>
In the thirteenth embodiment, the same RT transition as in FIG. 22 shown in the first embodiment is performed.
The thirteenth embodiment is characterized by the following points.
(1) The winning probabilities of the condition devices (replay B group, replay C group, small winning combination B group) related to RT transition are set so as not to have a setting difference.
(2) In RT2 that has transitioned from non-RT or RT1, an advantageous section is added (possible) based on winning the replay B group. On the other hand, in the case of shifting from RT3 to RT2, when shifting from RT2 to RT3, the addition of the advantageous section is not executed.
(3) The winning probability of Replay A is set to have a difference.
(4) The winning probability of the small winning combination D is set to have a difference.

FIG. 71 is a diagram showing a numerical table (2) of the thirteenth embodiment, and is a diagram corresponding to FIG. 18 of the first embodiment. In the first embodiment, the condition device of "small winning combination D" is provided in FIG. 17, but in this embodiment, since the small winning combination D has a setting difference, the small winning combination D is set as a mathematical table (2). ). Also in the thirteenth embodiment, the same number table (1) as in FIG. 17 shown in the first embodiment is provided (there is no number of small winning combination D).

Similar to the first embodiment (FIG. 22), when shifting from non-RT or RT1 to RT2, it is necessary to win the small winning combination B group and display the pattern symbol. Here, in order to display the pattern pattern, it is necessary to win the small winning combination B group. When there is a setting difference in the winning probability of the small winning combination B group, the ease of transition from non-RT or RT1 to RT2 differs depending on the set value (the ease of transition from RT3 to RT2 also differs). ). Therefore, in the thirteenth embodiment, in the non-RT and RT1, the winning probability of the small winning combination B group is set so as not to have a setting difference. In the example of FIG. 71, each position of the small winning combination B1 to the small winning combination B12 is set to "770" (not limited to this value), which is common to all the settings. In order to make the appearance rates of the small combinations B1 to B12 the same, the small combinations B1 to B12 are all set to the same number.

Furthermore, as shown in FIG. 71, the replay group B is drawn only at RT2, and the number of replays B1 to B3 is "2800", which is common to all settings. Further, the replay C group is drawn only at RT3, and the number of replays C1 to C3 is "12000" common to all settings. These points are the same as those in the first embodiment.
Further, in the thirteenth embodiment, in the non-RT or RT2 shifted from RT1, when the replay B group is won (may be when the replay 02 is displayed or when the transition from RT2 to RT3 is performed), the addition of the advantageous section is executed. In addition, the addition of the advantageous section may always be added, or whether or not to add may be decided by lottery. Further, the number of additional games may be a predetermined number of games, and the number of games may be determined by lottery.

In addition, "addition of advantageous section" can be replaced with "addition of AT" in all embodiments. For example, when a special role is won during AT (for example, the number of remaining games of AT is "5"), and when the replay B group is won in non-RT after the special game is completed or RT2 shifted from RT1. An additional lottery for increasing the number of remaining AT games is executed, and when this lottery is won, the number of remaining AT games can be increased (for example, the number of remaining AT games is set to "25").

It should be noted that, in RT2 that has transitioned from non-RT or RT1, executing the addition of the advantageous section at the time of winning the replay B group is similar to the tenth embodiment described above.
In the thirteenth embodiment, since the replay group B is a conditional device having no setting difference in the winning probability (placement number), it is possible to carry out the addition of the advantageous section in association with the winning of the conditional device. As a result, it is possible to prevent the probability of addition from having a setting difference.
Further, as in the tenth embodiment, when the transition from RT3 to RT2 is performed, even if the replay B group is won in the RT2 (even if the replay 02 is displayed or the transition from RT2 to RT3). , Do not add advantageous sections.
Further, in RT2, when the replay group B is elected, RT2 is maintained or RT3 is transferred. Therefore, the replay group B is a condition device capable of shifting the RT. Since the replay group B is a condition device having no setting difference in the winning probability, it is possible to prevent the replay B group from having a setting difference in the probability of transition from RT2 to RT3 (easiness of transition).

In RT3, when the replay C group is elected, RT3 is maintained or RT2 is transferred. Therefore, the replay group C is a condition device capable of shifting the RT. Since the replay C group is a condition device having no setting difference in the winning probability, it is possible to prevent the replay C group from having a setting difference in the probability of transition from RT3 to RT2 (easiness of transition).

Similarly, when the small winning combination B group is won in non-RT, RT1 or RT3 and the pattern symbol is displayed, the process shifts to RT2. Therefore, the small winning combination B group is a conditional device capable of transferring RT. Since the small winning combination B group is a conditional device having no setting difference in the winning probability, the probability of transitioning from non-RT, RT1, RT3 to RT2 (easiness of transition) should not have a setting difference. can do.
Since the small winning combination C group does not correspond to the condition device capable of shifting the RT, it may have a setting difference or may not have a setting difference. In the example of FIG. 71, there is a setting difference.

As described above, the RT transition rate is not affected by the setting difference by not giving a setting difference to the winning probability of the condition device (condition device related to RT transition) that enables RT migration. can do.
However, RT4 (inside) that shifts based on the winning of a special role is excluded. For example, as shown in FIG. 71, the winning probabilities of "1BBA + small winning combination E2", 1BBB, and "1BBBB + small winning combination D" have different settings, but RT4 (internally) shifts due to the carryover of the winning of the special combination. ) Is an exception (may be affected by the setting difference). This is because RT4 (inside) shifts based on the winning of a special role, and does not shift depending on the push order of the player, so that the properties are different from those described above. Furthermore, since RT4 (inside the inside) is intended to stay only for a short period of time until 1BB is won, the properties are different from those described above. Further, RT4 (inside the inside) cannot determine the transition to the advantageous section even during the normal section, and cannot add or the like even during the advantageous section, so that the RT4 (inside the inside) cannot be added to the advantageous section. This is because there is no difference in setting between the probability of transition and the probability of addition.

Furthermore, in the thirteenth embodiment, there is a setting difference in the winning probability (number of places) of the replay A. In Replay A, the winning probability (number of places) is different for each RT. Since RT does not shift when Replay A is won, the RT transition rate will not be affected even if a setting difference is provided. In this way, the higher the winning probability of Replay A, the higher the probability of replaying. Therefore, when calculating the payout rate including the replay, the higher the winning probability of Replay A, the higher the payout rate. It gets higher.
Then, in the example of FIG. 71, the winning probability of the replay A is set higher in the setting 6 than in the setting 1. Therefore, since the non-winning probability (probability of losing) can be made lower in the setting 6 than in the setting 1, the ball output rate can be increased accordingly.

In the first embodiment, as shown in FIG. 17, as a single winning of the small winning combination E1, the small winning combination E1 (number "250") that shifts to the advantageous section when winning in the normal section and the winning in the normal section are won. Also provided a small winning combination E1 (number of positions "750") that does not shift to the advantageous section. If the small winning combination E1 with the number "250" is won, the advantageous section for executing the AT of 50 games (the count of 50 games may start immediately, and when the game shifts to RT3 (or the next game). ), When the replay group B is won (or the next game), or when staying at RT3 (or the next game). It is assumed that the transition is made (in addition, the above-mentioned various advantageous section termination conditions may be applied). Even if the AT has the same 50 games, a higher probability of winning Replay A (low probability of non-winning) will result in a new medal being inserted than when the probability of winning Replay A is low (higher non-winning probability). Since there is no need to (consume), the payout rate will increase accordingly. In this way, even if there is no setting difference in the probability of deciding to shift to the advantageous section, it is possible to make a setting difference in the ball output rate in the advantageous section.

Furthermore, in the first embodiment described above, as shown in FIG. 17, the small winning combination D is a conditional device having no setting difference. On the other hand, in the thirteenth embodiment, the condition device has a setting difference. Further, although not shown in FIG. 71, the number of payouts when the small winning combination D is won and the small winning combination 35 (watermelon) wins is set to 15 (5 in the first embodiment). Therefore, the small winning combination D is the small winning combination having the maximum number of payouts among the small winning combination.

Further, since the small winning combination 35 related to the small winning combination D is "PB ≠ 1", the small winning combination 35 cannot be won unless it is pressed. Therefore, for example, when the small winning combination D is won, a green notification may be output to indicate that the small winning combination D has been won. Here, when the winning combination of "PB ≠ 1" is won in the conditional device, it is not "the operation of the instruction function" to output the effect suggesting the winning. It is true that there are cases where the small role 35 wins and cases where the small role 35 does not win at the timing of the push, but the small role 35 is correct regardless of whether the small role D is won or not. If the stop switch 42 is operated at the operation timing, it is a role that can always win a prize. In this respect, it is different from the small winning combination B, in which the winning rate differs depending on whether or not the instruction function is activated, as in the small winning combination B group of the present invention. For example, if the operation is always left first in order to win the small winning combination 01 when the small winning combination B1 is won, the small winning combination 01 cannot be won when the small winning combination B5 is won.

For example, when the left reel 31 is stopped, the left stop switch 42 is operated at a timing when the "watermelon" No. 4, 9, or 14 in FIG. 5 can stop at the effective line, and when the middle reel 31 is stopped, the left stop switch 42 is operated. If the middle stop switch 42 is operated at the timing when the 8th or 13th "watermelon" can stop at the effective line (on the right reel 31, "watermelon" is "PB = 1", so any timing is acceptable). At any time (without any notice), the small winning combination 35 can be won.
In the present invention, there is no combination of "PB ≠ 1" other than the small combination 35 (excluding the case where the push order is incorrect when the small combination B group is won), so each game is stopped at the above timing. If the switch 42 is operated, the small winning combination 35 will not be missed.
From the above, the game at the time of winning the small winning combination D does not correspond to the "game having an advantageous operation mode of the stop switch" in the present invention.

As a result, when the advantageous section is started, it is necessary to activate the instruction function at least once during the advantageous section when the condition device, which is the maximum payout by the operation of the instruction function, is won. The "conditional device that becomes the maximum payout by the method" is not the small winning combination D but the small winning combination B group.
Although not shown in FIG. 71, as in the first embodiment, a small combination E1 (two payouts) is provided as a condition device having no setting difference.

From the above, in the thirteenth embodiment,
Winning probability of small role D: There is a setting difference (15 payouts)
Winning probability of small role B group: There is no setting difference (when the push order is correct, the number of payouts is 9)
Winning probability of small role E1: No setting difference (2 payouts)
And the size relationship of the number of payouts is
Small role D> Small role B group (when the push order is correct)> Small role E1
Will be.

If the game at the time of winning the small winning combination D corresponds to the "game having an advantageous operation mode of the stop switch" in the present invention (the small winning combination has a different winning rate depending on whether or not the instruction function is activated). In the case), the "conditional device that maximizes the payout by the operation of the instruction function" is not the small winning combination B group but the small winning combination D. In that case, since the winning probability of the small winning combination D is low, it is likely that the small winning combination D has not been won by the time the end condition of the advantageous section is satisfied (the advantage section cannot be ended even though it is desired to end). However, if the winning probability of the small role D is increased (if it is higher than the winning probability of the small role B group), there is a high possibility that the small role D is duplicated with 1BBB (rare role). (Because most of the single wins of the small role D cannot be expected to be duplicated with 1BBB).

For this reason, the number of payouts when the small win D wins must be less than the number of payouts when the push order of the small win B group is correct. Then, even if the winning probability of the small winning combination D has a setting difference, the payout rate does not change significantly (because the small winning combination with a large number of payouts has a setting difference, the payout rate changes significantly. Because it will be done). However, if there is a setting difference in the winning probability of the small winning combination B group, which has a large number of payouts when the push order is correct, then there will be a setting difference in the ease of RT transition.
Therefore, in the thirteenth embodiment, the small winning combination D with a large number of payouts is used, and the payout rate differs according to the set value (the higher the setting, the higher the payout rate (the higher the set value, the higher the payout rate). It can be set to change)), and the RT transition can be prevented from being affected by the setting difference.

In the thirteenth embodiment, the small winning combination D is "PB ≠ 1", but for example, if "watermelon" is arranged as "PB = 1" for all reels 31, regardless of the push (player's). You will be able to win prizes (regardless of skill).
Further, as shown in FIG. 71, since the small winning combination D may be elected in duplicate with 1BBB, the higher the setting, the easier it is for the small winning combination 35 to appear, and when the small winning combination 35 appears, the winning of 1BBB is expected. be able to. Specifically, when the set value is set to "1", the probability that 1BBB is won at the time of the appearance of the small winning combination 35 is "20/520" = "0.038 (about 3.8%). ) ”, And when the set value is set to“ 6 ”, the probability that 1BBB will be won at the time of the appearance of the small winning combination 35 is“ 25/625 ”=“ 0.040 (about 4.0%). ) ”. Therefore, when the small winning combination 35 appears, the higher the set value, the higher the possibility that 1BBB has been won. Therefore, the player is provided with an element for estimating the set value, and the operating rate of the gaming machine is increased. You can also.

As can be said for all embodiments, in FIGS. 17, 18, and 71, the portion marked with "○" can be freely changed to "x" and is marked with "x". It is free to set the place to "○" unless the condition device has no setting difference and it is not won only at a specific RT (except during RT4, 1BBA game, 1BBB game), and "x". It is free to change the part marked with "Δ" as long as the condition device has no setting difference.

<14th Embodiment>
In the 14th embodiment, when the condition for changing the end condition of the advantageous section (extension condition of the advantageous section) is satisfied after starting the advantageous section and before the end of the advantageous section (before reaching the end condition). Is characterized by extending the advantageous section.
For example, when the number of games (initial value) of the advantageous section is 30 at the start of the advantageous section (for example, the previous game was the winning of the small winning combination D in the first embodiment), it is advantageous during the advantageous section. When the section extension condition (for example, winning of the small winning combination E1 in the first embodiment) is satisfied, the number of games is further added to extend the advantageous section. In the 14th embodiment, the end condition of the advantageous section is set to 30 games, but other various end conditions of the advantageous section described above may be applied.

FIG. 72 is a time chart illustrating the 14th embodiment.
In Example 1 of FIG. 72, when the advantageous section is started, the instruction function operating game is executed in the game at the time of winning the first small winning combination B group. Then, in Example 1, the number of games in the initially set advantageous section is set to 30 games. Example 1 shows an example in which the extension condition of the advantageous section is satisfied and the number of games is added by "50" during the 30 games. If the extension condition is not satisfied during the first 30 games of the advantageous section, the advantageous section ends at the 30th game as shown by the alternate long and short dash line in the figure. On the other hand, in Example 1, since the condition for extending the advantageous section is satisfied, the number of games played in the advantageous section is extended by 50 games.

In this case, if the instruction function operating game is executed at least once at the end of the first 30 games, even if the small winning combination B group is never won in the subsequent 50 games, that is, 1 The advantageous section can be ended without executing the instruction function operation game many times. This is because the instruction function operating game is executed once in a total of 80 games.

On the other hand, in FIG. 72, in Example 2, similarly to Example 1, the number of games in the advantageous section initially set is 30 games, and the extension condition of the advantageous section is satisfied during the 30 games, and 50 games are extended. An example is shown.
Then, in Example 2, in the first 30 games and the extended 50 games (total 80 games), the small winning combination B group was never won (that is, the instruction function operating game was not executed even once). This is an example. In such a case, even if the end condition of the advantageous section is satisfied (80 games are reached), the advantageous section is not ended.

In Example 2 of FIG. 72, when the small winning combination B group is won between the extended 50 games and the instruction function operating game is executed (two-dot chain line A in the figure), the advantageous section is obtained in the extended 50 games. Can be terminated (two-dot chain line B in the figure).
On the other hand, when a total of 80 games, that is, when the instruction function operation game has not been executed even once from the start of the advantageous section, wait for the small role B group to be won, and when the small role B group is won, the instruction function operation is activated. Play the game. Then, the advantageous section ends.

In the example of FIG. 72, the number of games played in the first advantageous section was set to 30 games, and the number of extended games was set to 50 games. If the transition conditions are not met, 32 games (the number of games is free), or one (the number of games is free) instruction function operation game, etc.), AT precursors (for example, the conditions for transition to AT) Even if it is not satisfied, after 32 games (the number of games is free), 50 games (the number of games is free, the start timing of counting the number of games may be the various timings described above), etc.) , CZ (for example, if the transition condition to AT is not satisfied, the game ends in 10 games (the number of games is free), or the game ends in one instruction function operation game (the number of games is free). Compared to the precursors, it is easier to meet the transition conditions to AT), AT (if the extension conditions are not met, 30 games (the number of games is free, the start timing of counting the number of games is also the start timing of the above-mentioned various timings) It can be provided in various ways, such as those ending with (good).

For example, at the start of the advantageous section, the game shifts to CZ (corresponding to "30" game in FIG. 72), and when the transition condition to AT (corresponding to "extension condition") is satisfied during this CZ, AT (corresponding to "50") The transition to (corresponding to the extension of the game) (extending the end condition of the advantageous section) can be mentioned. On the other hand, when the transition condition to AT is not satisfied during CZ, the advantageous section is terminated when the end condition of CZ is satisfied, and the transition to the normal section (normal for CZ, AT, etc.) is performed (example). One, two-dot chain line) can be mentioned.

Furthermore, in addition to the above
(1) The first advantageous section is a CZ (for example, one that ends in 30 games), and when the extension condition of the advantageous section is satisfied during this CZ, a CZ with a longer number of games (the number of games is added by "20"). ).
(2) The first advantageous section is set as "advantageous section ending with a predetermined number of times (for example, once) of the instruction function operation game (Gase AT precursor or CZ)", and the advantageous section before the first instruction function operation game is executed. When the extension condition (CZ transition condition or AT transition condition, for example, winning of small winning combination E1) is satisfied, CZ (predetermined number of games or instruction function operating game ends in a predetermined number of times), Or change to AT (one that ends after the specified number of games).
(3) The first advantageous section is set as "advantageous section ending with a predetermined number of times (for example, once) of the instruction function operation game (Gase AT precursor or CZ)", and the advantageous section before the first instruction function operation game is executed. When the extension condition (extension condition or CZ transition condition) of is satisfied, "advantageous section (Gase AT precursor or CZ) that ends with a plurality of (for example, 3 times) instruction function operation game more than a predetermined number of times" Change to.
(4) The first advantageous section is set to the AT of 30 games, and when the extension condition of the advantageous section is satisfied during this AT, the AT is changed to the AT of 100 games (the number of games is added by "70").
That can be mentioned.

In FIG. 72, when the first 30 games of the advantageous section are CZ, the instruction function operating game is executed only when the first small winning combination B group is won, and after that (30 games from the first game), the small winning combination B group is executed. It is not necessary to execute the instruction function operating game even if the player wins the game.
On the other hand, during the CZ (between 30 games), the instruction function operating game may be executed two or more times.
Further, even when the transition condition to AT is satisfied during CZ, if the instruction function operation game has already been executed once during CZ, the instruction function operation game is not executed in the subsequent AT. You may. In addition, the same applies when the conditions for transition to CZ or AT are satisfied during the precursor of Gase AT. That is, it is sufficient to execute one instruction function operating game between the start and the end of the advantageous section.

<15th Embodiment>
The fifteenth embodiment is characterized in that it has a case where the freeze is executed and a case where the freeze is not executed at the end of the advantageous section.
FIG. 73 is a time chart showing the relationship between the advantageous section and the freeze in the fifteenth embodiment.
In the fifteenth embodiment, when it is decided to execute the advantageous section (for example, when the small winning combination E1 is won), CZ is started at the beginning of the advantageous section. Then, when the conditions for transition to AT are satisfied during CZ, AT is started after the end of CZ. Of course, it is not limited to this. Some may start CZ as the beginning of the advantageous section, while others may start AT from the beginning.

In FIG. 73, the first CZ (advantageous section) does not satisfy the transition condition to AT, and the advantageous section ends only with CZ. The next CZ (advantageous section) is an example in which the transition condition to AT is satisfied, AT is executed after the end of CZ, and the AT and the advantageous section are ended. When the conditions for transition to AT are satisfied during CZ, CZ may be terminated immediately and AT may be executed, or wait until CZ is completed and AT may be executed (this means that the fifteenth). Not limited to embodiments).
Although not shown in FIG. 73, even when the game ends only in CZ, it is necessary to execute the instruction function operating game at least once because the section has shifted to the advantageous section.
In the fifteenth embodiment, at the end of the first CZ (when the AT is not executed after the end of the CZ and the advantageous section is ended), the freeze is not executed (two-dot chain line in the figure). On the other hand, when shifting from CZ to AT, freeze is executed at the end of AT (advantageous section).
At the time of freezing, at least the total number of AT games and the total number of acquired ATs are displayed as images. Of course, an image including the total number of games played and the total number of acquired cards in CZ may be displayed, and when shifting from CZ to AT via AT precursor, it is in CZ and / or in AT precursor. An image may be displayed including the total number of games played and the total number of acquired cards.

In this way, it is determined in advance in what advantageous section the freeze is executed at the end and in what advantageous section the freeze is executed at the end.
For example, as expected values such as the total number of games played in the advantageous section and the total number of acquired cards, the first end condition (for example, the end of the advantageous section only by CZ (may be a precursor of Gase AT)) and the expected value than the first end condition. When there is a second end condition (for example, when AT is executed after CZ or when only AT is executed), when the advantageous section ends with the first end condition, the freeze is not executed and the advantageous section is not executed. Is executed under the second termination condition. This is because the freeze is executed until the expected value such as the total number of games and the total number of acquired games in the advantageous section is small (for example, the total number of games is 10 games and the total number of acquired cards is 12). This is because there is a high possibility that the player's disappointment will be increased (the interest will be reduced) if the total number of acquired sheets is displayed as an image.
Even in the advantageous section, unlike AT, there are some such as Gase AT precursor, AT precursor, and CZ that do not aim to give a lot of medals to the player (the total number of medals won increases). , It is not preferable to uniformly freeze at the end of the advantageous section.

As a determination of whether or not to execute freeze, for example, setting a freeze flag can be mentioned. This freeze flag remains off only at the start of CZ, but is turned on when AT is executed. Then, at the end of the advantageous section, it is determined whether or not the freeze flag is on, and when it is on, the freeze is executed, and when the freeze is executed, the freeze flag is turned off. Immediately before the end of the advantageous section, it is determined whether or not the freeze flag is on, and if it is on, the freeze is executed, and when the advantageous section is ended, information on the advantageous section including the freeze flag is displayed. It may be initialized.

By controlling in this way, it is possible to prevent the freeze from being executed at the end of the advantageous section, which does not bring much merit to the player, such as when the advantageous section is started but ends only with the CZ.
In addition, information that identifies the type of advantageous section (CZ, Gase AT precursor, AT precursor, AT, etc.) ("1" to "4", etc., or "0" to "4" including the normal section, etc. For example, "0" is a normal section, "1" is a CZ, "2" is a gasse AT precursor, "3" is an AT precursor, "4" is an AT, etc.). Then, at the end of the advantageous section or immediately before the end of the advantageous section, this information may be determined and the freeze may be executed.

Also, the freeze is not limited to one time. For example, if the AT executes 50 games as one break, it executes a freeze every 50 games (for example, even if it is an AT of 100 games), and during the execution of the freeze, the AT continues after the next game. It is possible to output an effect of whether or not to do it. Further, for each 50 games, the total number of games played and the total number of acquired games at that time can be displayed as an image, and an effect as if the advantageous section ends (it was an AT of 50 games) can be output.

In addition, when the upper limit of 1500 games of the advantageous section is reached during the execution of AT, the freeze is executed, and the total number of games and the total number of acquired games during the AT are displayed as an image during the freeze. ..
Also in this case, when CZ or AT precursor is executed before AT is executed, even if the image including the total number of games played and the total number of acquired cards during CZ and / or AT precursor is displayed. good.
In addition, even when the upper limit of 1500 games of the advantageous section is reached while executing the CZ or AT precursor, the freeze is executed, and during the freeze, a part of the advantageous section (a part of the advantageous section such as CZ) is executed. Or all), the total number of games played, the total number of acquired games, and the like may be displayed as an image.

However, as shown in FIG. 70 (b), when the 1500 game, which is the upper limit of the advantageous section, is reached during 1BB operation (for example, 1BB operates during AT execution and 1BB is operating). When the game reaches 1500 games, the freeze is not executed when the game reaches 1500 games (because 1BB game is in progress), and the freeze is executed at the end of the 1BB game (at least the total number of games during AT during the freeze). The total number of acquired sheets and the like are displayed as an image.)
When the freeze is executed, the advantageous section display LED 77 is turned off after the freeze is completed. Of course, the advantageous section display LED 77 may be turned off before the freeze is executed, or the advantageous section display LED 77 may be turned off during the freeze execution. The initialization timing is the same as the extinguishing timing of the advantageous section display LED 77.

Further, in FIG. 73, it is also possible to provide a condition device in which the advantageous section ends only by CZ and a condition device in which it is confirmed that both CZ and AT are executed. For example, in FIG. 17 of the first embodiment, when the small winning combination E1 of the number "750" is won alone, it is set as an advantageous section ending only with CZ, and when the small winning combination E1 of the number "250" is won alone, CZ and AT It can be mentioned as an advantageous section for executing. With this setting, it is possible to decide to execute the AT without performing a lottery as to whether or not the transition condition to the AT is satisfied during the CZ.
Of course, even in this case, a lottery may be performed during CZ to see if the conditions for transition to AT are satisfied (may be performed only in the advantageous section ending only in CZ). It is also possible to output a continuous effect of whether or not to execute AT before several games when CZ ends. Then, in this case as well, whether or not to execute the freeze is as described above.

Although the third to fifteenth embodiments of the present invention have been described above, the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the third embodiment (FIGS. 43 to 52), an example of information (command) transmitted from the main control board 50 to the sub control board 80 has been given, but the present invention is not limited to this, and the main control board is not limited to this. Reference numeral 50 denotes a sub-control board 80 that transmits parameters (number of digestion games, number of remaining games, number of additions, number of acquisitions, number of times of instruction function operation, etc.) necessary for display during the advantageous section (AT). ..

(2) Further, in FIGS. 43 to 52, in order to manage the advantageous section (AT) by the number of games, parameters related to the number of games (AT counter value, additional counter value, upper limit counter value, etc.) are transmitted. If the upper limit of (AT) is managed by, for example, the number of acquired cards (for example, 3000 cards), information on each game and the number of acquired cards is transmitted.
Further, each game, the main control board 50 transmits information indicating that the advantageous section is in progress and information indicating that the AT is in progress, and counts the number of games in the advantageous section and AT on the sub control board 80 side. It is also possible to provide a counter and count the number of games on the sub control board 80 side.

(3) In FIGS. 47 to 49 of the third embodiment, lottery tables A and B are provided as lottery tables used in the additional lottery, and the lottery is used depending on whether or not the specified number is "1000" or more as the threshold value. I switched the table. However, the present invention is not limited to this, and any number of types of lottery tables may be provided. Moreover, although the specified number "1000" is illustrated as a threshold value, it is not limited to this.
For example, four types of lottery tables A>B>C> D are provided as lottery tables having different sizes of expected values to be added. Then, when the specified number (AT game count) is less than 500, the lottery table A is used, when the specified number is 500 or more and less than 1000, the lottery table B is used, and when the specified number is 1000 or more and less than 1300. Can use the lottery table C, and when the specified number is 1300 or more, the lottery table D can be used.

(4) As shown in Examples 1 to 3 of FIG. 55, when the total number of games in the advantageous section (AT) reaches the upper limit, it is peculiar when the total number of games in the advantageous section (AT) reaches the upper limit. Information is displayed, but is not limited to these Examples 1 to 3.
a) A display that allows the player to identify that the total number of games played in the advantageous section (AT) has reached the upper limit b) A display different from the display before the total number of games played in the advantageous section (AT) reaches the upper limit. It does not have to be limited to the display contents of Examples 1 to 3.

(5) Further, in Example 1 of FIG. 55, when the total number of AT games exceeds 1500 due to the addition, the display of the number of digested games and the number of remaining games is not changed. The information itself of the number of digested games and the number of remaining games is not changed, such as different display fonts for the number of remaining games, different character sizes, different display colors, etc., but it can be added by changing the display mode. This may inform the player that the total number of AT games has exceeded 1500 games.

(6) In Example 4 of FIG. 55, when the advantageous section (AT) is running low, a display such as "It will end in 10 more games" is displayed, but at the start of the advantageous section (AT). , "This advantageous section (AT) cannot be played beyond 1500 games", etc., can be notified in advance.

(7) In the fourth embodiment, the AT signal is transmitted as the external signal 2, but for example, when the slot machine has specifications in which the advantageous section and the AT do not match, the advantageous section and the AT can be distinguished. An external signal may be transmitted. For example, using two external signals, it is possible to transmit an external signal that can distinguish "non-advantageous section (non-AT)", "advantageous section and non-AT", and "advantageous section and AT".

(8) In the fourth embodiment, the BB is won immediately before the upper limit of the advantageous section is reached, and the start time of the BB game is when the upper limit of the advantageous section is reached (the 1500th game from the start of the advantageous section) or immediately after the upper limit is reached (for example, advantageous). When it is the 1501st game from the start of the section, the BB game in the non-advantageous section is started, only the external signal 1 (BB) is turned on, and the external signal 2 (AT) is turned off (advantageous section and AT). To end).
If the end of the BB game is when the upper limit of the advantageous section is reached (the 1500th game from the start of the advantageous section) or immediately before the upper limit is reached (for example, the 1499th game from the start of the advantageous section), the outside at the end of the BB game. At the same time that the signal 1 (BB) is turned off, the external signal 2 (AT) is turned off (the advantageous section and the AT are ended).

(9) In the fifth embodiment, AT, CZ, precursors, and normal are exemplified as the control states controlled by the main control board 50. For example, an additional special zone that shifts when a predetermined condition is satisfied during AT. It is also possible to provide. This additional special zone is continued until, for example, the predetermined number of games is exhausted or the predetermined combination is won a predetermined number of times, and during that period, each time the condition device (for example, small combination B group) to be added is won. , The number of AT games can be added.

(10) In the fifth embodiment, in the example of (a) in FIG. 61, after the end of AT (state 1), the AT (state 1) is shifted to the AT pullback period (state 2), and the AT cannot be pulled back in this state 2. Has transitioned to normal (state 3). Further, in the example of (b), after the end of AT, the shift was made to CZ, and when the AT could not be pulled back in this CZ, the shift was made to normal. Furthermore, in the example of (c), after the end of CZ, the process was shifted to the CZ pullback period, and when the CZ could not be pulled back during this CZ pullback period, the shift was normal.
However, the above state transition is an example and is not limited to this.

For example, in FIG. 61 (a), after the end of AT (state 1), the transition to normal (state 3) may be performed without going through the AT pullback period (state 2).
Further, in FIG. 61 (b), the transition may be made from normal → CZ → AT, or may be shifted from normal → precursor → AT. After the end of AT, the transition may be made from AT to normal, or from AT to precursor (CZ pullback period) to normal.
Furthermore, in FIG. 61 (c), the transition from normal to CZ may be performed without going through a precursor. Further, it may be transferred from CZ to normal without going through the pullback period.

(11) In the eighth embodiment, the output of the continuous effect is started near the end of the 1BBA game. For example, the output of the continuous effect is started at the same time as the start of the 1BBA game, and the AT is continuously operated during the 1BBA game. You may continue to output an effect that encourages whether or not to start.
Further, the output of the continuous effect may be started from the start of the 1BBA game, and the effect of finally notifying whether or not to start the AT may be output until the first half of the 1BBA game. Alternatively, an effect may be provided in which the execution of the AT is determined when the effect is output during the continuous effect, and the effect may be output during the continuous effect.
In the eighth embodiment, the continuous production is not always a necessary production. Therefore, it is arbitrary whether or not to output the continuous effect. Further, for example, it is possible to output only one game as an effect of whether or not to continue the advantageous section.

(12) In the ninth embodiment, it is conceivable that the instruction function is activated when the advantageous section is started based on the winning of the condition device including the special combination, for example, when the small combination B group is elected in RT4 (internal middle). .. When the instruction function is activated at RT4, the ball output rate at RT4 exceeds "1". In such a case, it is necessary to start the advantageous section from (at the start of RT4, which is the next game of the game in which the special role is won).
On the other hand, if the instruction function is not activated even after shifting to RT4, the advantageous section may be started by the start of the special game.

(13) In the third embodiment, when the upper limit value of the advantageous section approaches, the design is made so that the winning probability of the AT additional lottery on the main control board 50 is low, or the additional effect on the sub control board 80 is suppressed. By doing so, even if the upper limit of the advantageous section approaches, it is possible to play the game without discouraging the player as much as possible.
As another method, there is also a method of not discouraging the player as much as possible by changing the execution probability of the freeze effect based on the number of execution games of the advantageous section and the like. For example, in FIG. 17, when a small winning combination E1 with a number of "250" is won, the number of additional games is set to "50" (50%), "100" (40%), or "200" (10%). Set so that the more the number of additional games, the higher the possibility that the freeze effect will be executed.

In such a specification, when the number of games in the advantageous section is less than a predetermined value (for example, 1300) and "200" is determined as the number of additional games, the freeze effect is performed with a probability X (including 100%). When the number of games in the advantageous section is equal to or greater than the predetermined value, the freeze effect is executed with a probability Y (including 0%) lower than the probability X when "200" is determined as the number of additional games.
With this configuration, when the upper limit of the advantageous section is approaching, the execution probability of the freeze effect can be lowered, and the player can be prevented from being excessively agitated by the freeze effect. That is, it is possible to prevent the player from being discouraged as much as possible when the freeze effect is executed.
(14) Each of the above-described embodiments is not limited to being implemented alone, and a plurality of embodiments can be combined and implemented as appropriate.

<16th Embodiment>
Subsequently, the 16th embodiment of the present invention will be described.
In the present embodiment, "advantageous section 1" and "advantageous section 2" are provided as advantageous sections. Then, if the player wins the advantageous section 1 (decides to move), the game state shifts to the game state of Gase, which does not have the right to move to the ART, and if the player wins the advantageous section 2, the game state allows the player to move to the ART (ART). It shifts to ART through the precursor).

In addition, although the content partially overlaps with that of the first embodiment, the meanings of the terms in this embodiment are as follows.
The "conditional device" is a lottery target consisting of one or more combinations. If one condition device is won, the winning combination included in the condition device is won.
The condition device related to the special role (bonus; bonus) is referred to as the "character condition device", the condition device related to the small role is referred to as the "winning condition device", and the condition device related to the replay is referred to as the "replay condition device". .. Further, the winning condition device and the replay condition device are collectively referred to as a "winning and replay condition device".

The "conditional device number" is a number for identifying the conditional device, and is defined for each conditional device.
The number for identifying the bonus condition device is called the "feature condition device number", the number for identifying the winning condition device is called the "winning condition device number", and the number for identifying the replay condition device is called. It is called "replay condition device number". Further, the winning condition device number and the replay condition device number are collectively referred to as "winning and replay condition device number".
The "winning number" is a number determined based on a random number value obtained from the random number generation means. One winning number is determined based on one random value.

Further, as described in the first embodiment, the winning combination lottery means 61 is a means for performing lottery (decision or selection) of the conditional device (winning combination). Therefore, the winning combination lottery means 61 is also referred to as a conditional device lottery (decision or selection) means, a winning combination lottery (decision or selection) means, and the like.
Further, the combination lottery means 61 includes a random number generation means and a random number acquisition means for acquiring the random numbers generated by the random number generation means, as in the first embodiment.
Further, in the present embodiment, the winning combination lottery means 61 is a winning number determining means for determining a winning number based on a random number value acquired by the random number acquiring means, and a conditional device for determining a conditional device number based on the determined winning number. It is equipped with a number determination means.

The random number generation means generates random numbers in a predetermined range (for example, "0" to "65535" in decimal). For example, a range of "0" to "65535" is set as one cycle, a counter that counts 1 in 200 n (nano) sec is provided, and the count value of this counter can be a random number. This counter keeps counting random numbers while the slot machine 10 is powered on. This point is the same as that of the first embodiment.

The random number acquisition means acquires the random numbers generated by the random number generation means when the start switch 41 is operated (on) by the player. This point is the same as that of the first embodiment.
Further, in the present embodiment, when the start switch 41 is operated (on), the random number acquisition means acquires (latch) a random number value from the above counter and stores (stores) it in the random number value register.
Here, the random number value register is a register built in the main CPU 55, and is a register that cannot be written by the program and can only be read.
Further, when the program reads the random number value stored in the random number value register, the random number value register is cleared.

The winning number determining means determines the winning number based on the random number value acquired by the random number acquiring means.
In the present embodiment, the winning number determining means corresponds to the processing of the internal lottery 1 of FIG. 87 and the lottery determination of FIG. 88, which will be described later.
The condition device number determining means determines the condition device number based on the winning number determined by the winning number determining means.
In the present embodiment, the condition device number determination means corresponds to the process of the condition device number set 1 of FIG. 89, which will be described later.

FIG. 74 (a) is a diagram showing the winning number definition (1) in the present embodiment. Further, FIG. 75 (a) is a diagram showing the winning number definition (2) in the present embodiment, and is a diagram following FIG. 74 (a).
The winning number definition defines the correspondence between the winning number and the conditional device number and the like.
As shown in FIG. 74 (b), in "@NB_REP_A EQU 1; replay A condition device number", "@NB_REP_A" indicates "replay A condition device number", and "replay A condition device number" is "1". It means that the winning number corresponding to "@NB_REP_A" is "1".
Then, when the winning number is determined to be "1", the "Replay A condition device" is independently won. The winning numbers "2" to "9" are the same as the winning numbers "1".

Further, as shown in FIG. 74 (c), in "@NB_WIN_A EQU 10; small winning combination A condition device number", "@NB_WIN_A" indicates "small winning combination A condition device number", and "small winning combination A condition device number". It means that the "number" is "10" and the winning number corresponding to "@NB_WIN_A" is "10".
Then, when the winning number is determined to be "10", the "small winning combination A condition device" is independently won. The winning numbers "11" to "30" are the same as the winning numbers "10".

Furthermore, as shown in FIG. 75 (b), "@ BBA_WIN_E2 EQU 31; 1BBA + small winning combination E2 duplicate winning" means that "@ BBA_WIN_E2" indicates "overlapping winning of 1BBA and small winning combination E2", "@ BBA_WIN_E2". It means that the winning number corresponding to "" is "31".
Then, when the winning number is determined to be "31", the "1BBA conditional device" and the "small winning combination E2 conditional device" are duplicated.

Further, as shown in FIG. 75 (c), in "@BBB EQU 32; 1BBB single winning", "@BBB" indicates "1BBB single winning", and the winning number corresponding to "@BBB" is "@BBB". It means that it is number 32 ".
Then, when the winning number is determined to be "32", the "1BBB condition device" is independently won.

Further, as shown in FIG. 75 (d), "@BBA EQU 34; 1BBA single winning + addition" means that "@BBA" indicates "1BBA single winning and addition of advantageous section", "@BBA". It means that the winning number corresponding to is "34".
Then, when the winning number is determined to be "34", it is determined that the "1BBA condition device" is independently elected and the number of games in the advantageous section is added.

Furthermore, as shown in FIG. 75 (e), in "@ AT1_BBA_WD EQU 44; 1BBA + small winning combination D duplicate winning + advantageous section 1", "@ AT1_BBA_WD" is "1BBA and small winning combination D overlapping winning and advantageous section 1". It means that the winning number corresponding to "@ AT1_BBA_WD" is "44".
Then, when the winning number is determined to be "44", the "1BBA condition device" and the "small winning combination D condition device" are duplicated, and it is determined to shift to the advantageous section 1.

As shown in FIGS. 74 (a) and 75 (a), in the present embodiment, the winning numbers are defined from "1" to "52". Then, the winning number determining means determines any one of the numerical values of "0" to "52" as the winning number.
Further, as shown in FIG. 74 (a), the winning numbers "1" to "9" correspond to the replay condition device numbers "1" to "9", respectively, and the winning numbers "10" to "10" The "30" numbers correspond to the winning condition device numbers "10" to "30", respectively.

Furthermore, as shown in FIG. 75 (a), the winning numbers "31" to "33" are for single winning of the character condition device or duplicate winning of the prize condition device and the winning and replay condition device. Correspondingly, the winning numbers "34" to "42" correspond to the addition of the advantageous section, and the winning numbers "43" to "47" correspond to the transition to the advantageous section 1, and the winning number " Nos. 48 "to" 52 "correspond to the transition to the advantageous section 2.

In the present embodiment, if the winning number is determined to be "34" to "42" during the advantageous section, the number of games played in the advantageous section is added, but the present invention is not limited to this. ..
For example, in the case where ART is executed during the advantageous section, when the winning numbers are determined to be "34" to "42", a game in which ART can be executed uniformly or by lottery. The number of times may be increased.

Further, for example, in the case of executing a Gase game (a game state in which the advantageous section display LED 77 is lit, although there is no right to shift to ART) during the advantageous section, the winning numbers are "34" to "34". When the number is decided to be "42", the right to move to ART may be granted uniformly or by lottery.
In this way, instead of adding the number of games in the advantageous section, the gaming state (performance of the advantageous section) in the advantageous section may be changed so as to be advantageous to the player.

In addition, "when the winning number is determined to be" 34 "to" 42 "" means when the winning number is determined to be any of "34" to "42".
Further, the number of games to be added to the number of games in the advantageous section and the content of the change in the game state (performance of the advantageous section) in the advantageous section can be appropriately set according to the type of the determined winning number.

FIG. 76A is a diagram showing a data definition for winning number conversion.
The data definition for winning number conversion defines the definition of data used when determining the condition device number from the winning number.
As shown in FIG. 76 (b), in "@NB_TRNS EQU @ BBA_WIN_E2; conversion start number", "@NB_TRNS" indicates "conversion start number", and the value corresponding to "@NB_TRNS" is "@ BBA_WIN_E2". Means that
As shown in FIG. 75 (a), “@ BBA_WIN_E2” = “31”.
Therefore, "@NB_TRNS" = "@BBA_WIN_E2" = "31".
Then, when the winning number determined by the winning number determining means is equal to or greater than the "conversion start number", the winning number conversion table is used to determine the conditional device number from the winning number.

Further, as shown in FIG. 76 (c), "@NB_TRNS_AT EQU @ AT1_BBA; advantageous section conversion start number" corresponds to "@NB_TRNS_AT" indicating "advantageous section conversion start number" and "@NB_TRNS_AT". It means that the value is "@ AT1_BBA".
As shown in FIG. 75 (a), “@ AT1_BBA” = “43”.
Therefore, "@NB_TRNS_AT" = "@ AT1_BBA" = "43".
Then, when the winning number determined by the winning number determining means is equal to or higher than the "advantageous section conversion start number", the winning number is won (decided to shift) to the advantageous section 1 or the advantageous section 2.

Furthermore, as shown in FIG. 76 (d), in "@ NB_1BBA EQU 1; 1BBA condition device number", "@ NB_1BBA" indicates "1BBA condition device number", and the value corresponding to "@ NB_1BBA" is It means that it is "1". That is, it means that the "1BBA condition device number" is the "1" number.
Further, as shown in FIG. 76 (e), in "@ NB_AT1 EQU 1; advantageous section number 1", "@ NB_AT1" indicates "advantageous section number 1", and the value corresponding to "@ NB_AT1" is "@ NB_AT1". It means that it is "1".

FIG. 77 (a) is a diagram showing a winning number conversion table.
The winning number conversion table is a table in which data to be used when determining the condition device number from the winning number is defined, and is stored in the ROM 54 of the main control board 50.
As shown in FIG. 77 (a), when the winning numbers determined by the winning number determining means are "31" to "52", the winning number conversion table corresponds to the determined winning numbers. It is used when determining the condition device number and the advantageous section number.
Here, "DEFB" is a pseudo-instruction in assembly language that "allocates an area of 1 byte (8 bits) in the memory and stores data in the area".
When multiple data are described in the DEFB line separated by commas, a plurality of 1-byte areas are secured in the memory in the order of addresses, and each data separated by commas is sequentially stored in each secured area. It means to do.

As shown in FIG. 77 (c), "DEFB @ NB_1BBA, @ NB_WIN_E2, 0; winning number 31" stores "@ NB_1BBA" in the address ### 0 (for example, address 1600 (H)), and the address # It means that "@NB_WIN_E2" is stored in ## 1 (for example, address 1601 (H)) and "0" is stored in address ## # 2 (for example, address 1602 (H)).

As shown in FIG. 76 (a), “@ NB_1BBA” = “1”, and as shown in FIG. 74 (a), “@ NB_WIN_E2” = “28”.
Therefore, "1" is stored in the address ### 0, and "28" is stored in the address ### 1.

That is,
Address ### 0 (1600 (H) address) 1: Character condition device number Address ### 1 (1601 (H) address) 28: Winning and replay condition device number Address ### 2 (1602 (H) address) ) 0: It becomes an advantageous section number.
Then, each data stored from the address ### 0 to the address ### 2 is used when the winning number is determined to be "31".

Further, as shown in FIG. 77 (d), "DEFB @ NB_1BBB, 0, 0; winning number 32" stores "@ NB_1BBB" in the address ### 3 (for example, address 1603 (H)), and the address. It means that "0" is stored in ### 4 (for example, address 1604 (H)) and "0" is stored in address ### 5 (for example, address 1605 (H)).
As shown in FIG. 76 (a), “@ NB_1BBB” = “2”.
Therefore, "2" is stored in the address ### 3.

That is,
Address ### 3 (address 1603 (H)) 2: Accessory condition device number Address ### 4 (address 1604 (H)) 0: Winning and replay condition device number Address ### 5 (address 1605 (H)) ) 0: It becomes an advantageous section number.
Then, each data stored from the address ### 3 to the address ### 5 is used when the winning number is determined to be "32".

FIG. 78A is a diagram showing a winning number lottery data definition.
The winning number lottery data definition defines the definition of the data used when the winning number is determined from the random number value in the lottery determination.
The "winning number identifier" is an identifier indicating that the data includes the winning number data.
The "winning number data" is data indicating the winning number determined in the lottery determination.

Then, "@LT_NUM EQU 10000000B; winning number identifier" means that "@LT_NUM" indicates a "winning number identifier" and that the data corresponding to "@LT_NUM" is "10000000 (B)".
Further, in "@BT_NUM EQU 7", the bit corresponding to the winning number identifier is "bit 7", and when the bit 7 is "1", the winning number identifier is on and the bit 7 is "0". In some cases it means that the winning number identifier is off.

The "repetition count identifier" is an identifier indicating that the data includes the repetition count data.
The "repetition number data" is data indicating the number of times the winning / failing determination process is repeated in the lottery determination.
Then, "@LT_LOP EQU 01000000B; repeat count identifier" means that "@LT_LOP" indicates a "repeat count identifier" and that the data corresponding to "@LT_LOP" is "01000000 (B)".
Further, in "@BT_LOP EQU 6", when the bit corresponding to the repetition count identifier is "bit 6", when the bit 6 is "1", the repetition count identifier is on, and when the bit 6 is "0". Means that the repeat identifier is off.

The "identifier for each set value" is an identifier indicating that the probability data is set for each set value.
The "probability data" is data indicating a winning range out of the entire range taken by the random number value.
Therefore, the winning probability = "the entire range of the probability data / random value".
For example, when the entire range taken by the random number value is "65536" and the probability data is "125", the winning probability is "125/65536".
The probability data may also be referred to as a judgment value, a judgment data, a number, or a number data.

Then, "@LT_RNK EQU 00100000B; identifier by set value" means that "@LT_RNK" indicates "identifier by set value" and that the data corresponding to "@LT_RNK" is "00100000 (B)". do.
Further, in "@BT_LOP EQU 5", the bit corresponding to the set value-specific identifier is "bit 5", and when bit 5 is "1", the set value-specific identifier is on and bit 5 is "0". When is, it means that the repeat count identifier is off.

The "2-byte data identifier" is an identifier indicating that the probability data is 2-byte data.
And, "@LT_WRD EQU 00010000B; 2-byte data identifier" means that "@LT_WRD" is a "2-byte data identifier" and the data corresponding to "@LT_WRD" is "00010000 (B)". do.
Further, in "@BT_WRD EQU 4", the bit corresponding to the 2-byte data identifier is "bit 4", and when the bit 4 is "1", the 2-byte data identifier is on and the bit 4 is "0". When is, it means that the 2-byte data identifier is off.

The "1-byte data identifier" is an identifier indicating that the probability data is 1-byte data.
And, "@LT_BYT EQU 000001000B; 1-byte data identifier" means that "@LT_BYT" is a "1-byte data identifier" and the data corresponding to "@LT_BYT" is "00001000 (B)". do.
Further, in "@BT_BYT EQU 3", the bit corresponding to the 1-byte data identifier is "bit 3", and when bit 3 is "1", the 1-byte data identifier is on and bit 3 is "0". When is, it means that the 1-byte data identifier is off.

The "determination end identifier" is an identifier indicating that the lottery determination is completed.
And, "@LT_END EQU 00H" means that "@LT_END" is a "determination end identifier" and the data corresponding to "@LT_END" is "00H".

FIG. 79 is a diagram showing a lottery table (1) common to all RTs. Further, FIG. 80 is a diagram showing a lottery table (2) common to all RTs, and is a diagram following FIG. 79. Furthermore, FIG. 81 is a diagram showing a lottery table (3) common to all RTs, and is a diagram following FIG. 80. Further, FIG. 82A is a diagram showing a lottery table (4) common to all RTs, and is a diagram following FIG. 81.

Further, FIG. 82B is a diagram showing a non-RT lottery table. Furthermore, FIG. 82 (c) is a diagram showing a lottery table at RT 1:00. Further, FIG. 83A is a diagram showing a lottery table at RT2. Further, FIG. 83 (b) is a diagram showing a lottery table at RT3. Furthermore, FIG. 84 (a) is a diagram showing a lottery table at RT4. Further, FIG. 84 (b) is a diagram showing a lottery table at 1 BBA. Further, FIG. 85 is a diagram showing a lottery table at the time of 1BBB.
These lottery tables are used in an internal lottery (a lottery in which a winning number is determined from a random number value) and are stored in the ROM 54 of the main control board 50.

Further, the lottery table common to all RTs is commonly used in non-RT, RT1, RT2, RT3, and RT4. That is, the lottery table common to all RTs is a lottery table used when determining the winning number regardless of the RT state, except when 1BB (first-class accessory continuous operation device; first-class big bonus) is activated. Means. Furthermore, the non-RT time lottery table is used in non-RT, the RT1 time lottery table is used in RT1, the RT2 time lottery table is used in RT2, and the RT3 time lottery is used. The table is used in RT3, and the RT4 o'clock lottery table is used in RT4.

At the time of non-RT, first, the lottery determination is performed using the lottery table common to all RTs. At this time, if the winning number is determined to be "00 (H)", then the lottery determination is performed using the non-RT lottery table.
On the other hand, if the winning number is determined to be a value other than "00 (H)" in the lottery determination using the lottery table common to all RTs, the internal lottery ends without using the non-RT lottery table.
Although the details will be described later, the fact that the winning number is "00 (H)" in the lottery judgment using the all RT common lottery table means that the winning number is not determined in the lottery judgment using the all RT common lottery table. It means that.
In addition, if the winning number is a value other than "00 (H)" in the lottery judgment using the all RT common lottery table, one of the winning numbers is determined by the lottery judgment using the all RT common lottery table. Means that.

At RT1, RT2, RT3, or RT4, the lottery determination is first performed using the lottery table common to all RTs, as in the case of non-RT. At this time, when the winning number is determined to be "00 (H)", the lottery determination is then performed using the lottery table corresponding to the RT.
On the other hand, if the winning number is determined to be a value other than "00 (H)" in the lottery determination using the lottery table common to all RTs, the internal lottery ends without using the lottery table according to RT. ..
Further, at the time of 1BBA, the lottery determination is performed using the 1BBA time lottery table, and at the time of 1BBB, the lottery determination is performed using the 1BBB time lottery table.

“TBL_LOT_DAT1” in FIG. 79 indicates a lottery table common to all RTs.
When the lottery table common to all RTs is set as the lottery table, first, the winning / failing determination is performed using "1BBA + small winning combination E2 condition device lottery data". At this time, if a winner is won, the winning number is determined to be "@ BBA_WIN_E2" (= "31"), and the lottery determination is completed.
On the other hand, if the winning / failing determination using "1BBA + small winning combination E2 condition device lottery data" is not successful, then the winning / failing determination is performed using "1BBB condition device lottery data".

Further, a winning / failing determination is made using "1BBB condition device lottery data", and if a winner is won at this time, the winning number is determined to be "31 + 1" (= "32"), and the lottery determination is completed.
On the other hand, if the winning / failing determination using the "1BBB condition device lottery data" is not successful, then the winning / failing determination is performed using the "1BBB + small winning combination D condition device lottery data".
Further, when the winning number data is included as in "1BBA + small winning combination E2 condition device lottery data", the winning / failing determination is performed using the winning number data.
Furthermore, when the winning number data is not included, such as "1BBB condition device lottery data", the winning / losing of this time is used by adding "1" to the winning number data used in the previous winning / failing judgment. Make a judgment.

In this way, when the winning number data becomes a serial number, the data obtained by adding "1" to the winning number data used in the previous winning / failing determination can be used for the current winning / failing determination, and thus the lottery table. Since it is not necessary to determine the winning number data, the amount of ROM 54 used by the lottery table can be reduced.
If the winning number data does not become a serial number, the winning number data is set in the lottery table and the winning / failing judgment is made using the winning number data, so that the winning number data is not a serial number (for example, jumping). (Even if it is or returns), you can get an appropriate lottery result.

The same applies to "1BBB + small winning combination D condition device lottery data" and thereafter as "1BBA + small winning combination E2 conditional device lottery data" and "1BBB conditional device lottery data".
Then, when the "judgment end" is reached without being judged as winning in the winning / failing judgment, the lottery judgment using the lottery table common to all RTs ends.

Further, in FIG. 79, "DEFB @LT_NUM OR @ BBA_WIN_E2; Winning number identifier ;; + Winning number data" is obtained by ORing "@LT_NUM" and "@ BBA_WIN_E2", and the data obtained is "1BBA + small winning combination". It is shown that it is stored in the first line of "E2 condition device lottery data".
Here, as shown in FIG. 78, “@LT_NUM” indicates a winning number identifier, and its value is “10000000 (B)”.
Further, as shown in FIG. 75 (a), "@BBA_WIN_E2" indicates a winning number corresponding to 1BBA + small winning combination E2 duplicate winning, and the value is "31" (binary number "00011111 (B)"). be.

Further, when "@LT_NUM" and "@BBA_WIN_E2" are OR-operated,
10000000 (B): @LT_NUM
000111111 (B): @ BBA_WIN_E2
10011111 (B): Data after OR calculation.
In other words, "DEFB @ LT_NUM OR @ BBA_WIN_E2" indicates that "10011111 (B)" is stored in a predetermined 1-byte storage area on the ROM 54.

Thereby, the winning number identifier and the winning number data can be represented by one 8-bit data. In this case, of the 8-bit data, bits 0 to 6 indicate winning number data, and bit 7 indicates a winning number identifier.
Further, the comment "; winning number identifier ;; + winning number data" indicates that the data includes the winning number identifier and the winning number data.
Then, when the bit 7 is "1" as in "10011111 (B)", it is determined that the winning number identifier is on, and it is determined that the data includes the winning number data, and the bits 0 to 0 Bit 6 is used as winning number data.

Further, in FIG. 79, "DEFB @LT_BYT OR @LT_RNK; 1-byte data identifier ;; + identifier by set value" is obtained by ORing "@LT_BYT" and "@LT_RNK" to obtain "1BBA +". It is shown that it is stored in the second line of the "small winning combination E2 condition device lottery data".
Here, as shown in FIG. 78, “@LT_BYT” indicates a 1-byte data identifier, and its value is “00001000 (B)”.
Further, "@LT_RNK" indicates an identifier for each set value, and the value is "00100000 (B)".

Further, when "@LT_BYT" and "@LT_RNK" are OR-operated,
00001000 (B): @LT_BYT
0010000 (B): @LT_RNK
00101000 (B): Data after OR calculation.

In other words, "DEFB @LT_BYT OR @ LT_RNK" indicates that "00101000 (B)" is stored in a predetermined 1-byte storage area on the ROM 54.
Thereby, the 1-byte data identifier and the set value-specific identifier can be represented by one 8-bit data.
Further, the comment "; 1-byte data identifier ;; + identifier for each set value" indicates that the data includes the 1-byte data identifier and the identifier for each set value.

When the probability data is 1 byte, the data in which the 1-byte data identifier is turned on (bit 3 is set to "1") is stored, and when the probability data is 2 bytes, the 2-byte data identifier is turned on. (Bit 4 is set to "1") and the data is stored.
In this way, the data in which either the 1-byte data identifier or the 2-byte data identifier is turned on is stored, and the data in which both the 1-byte data identifier and the 2-byte data identifier are turned on is not stored.
When the probability data is defined for each set value, the data in which the identifier for each set value is turned on (bit 5 is set to "1") is stored, and the common probability data is defined for all the set values. At this time, the data in which the set value-specific identifier is turned off (bit 5 is set to "0") is stored.

In this way, when the probability data differs between the settings 1 to 6, the probability data for each set value is set in the lottery table, and the data in which the set value-specific identifier is turned on is stored. As a result, the winning number can be drawn with a different probability for each set value.
When the probability data is common to the settings 1 to 6, one probability data is set in the lottery table, and the data in which the set value-specific identifier is turned off is stored. As a result, only one probability data needs to be set in the lottery table, so that the amount of ROM 54 used by the lottery table can be reduced.

Further, in the "DEFB 10; probability data (setting 1)" in FIG. 79, "10" (binary number "000001010 (B)") is stored as the probability data used at the time of setting 1. Shown.
Actually, the probability data is set for each setting value of setting 1 to setting 6, but in FIG. 79, the probability data of setting 1 and setting 6 is shown as a representative, and the probability of setting 2 to setting 5 is shown. The data is not shown. “:” In FIG. 79 means that the illustration of the probability data of settings 2 to 5 is omitted. The same applies to the lottery table after FIG. 80.

Then, based on whether the 1-byte data identifier or the 2-byte data identifier is on, whether the set value-specific identifier is on or off, and when the set value-specific identifier is on, the set value is used. The address of the probability data to be used is calculated (designated), and the winning / failing judgment is performed using the probability data corresponding to the calculated (designated) address.
The method of acquiring the probability data will be described later.

Here, in the present embodiment, the information regarding the set value is stored in a predetermined storage area (set value data storage area “_NB_RANK”) of the RWM 53.
Further, as the information regarding the set value, any one of "0" to "5" is stored in the set value data storage area "_NB_RANK".
When "0" is stored in the set value data storage area "_NB_RANK", "1" is displayed in the set value display LED 73, and "5" is stored in the set value data storage area "_NB_RANK". When it is, "6" is displayed on the set value display LED 73.

That is, when "N" (N is an integer) is stored in the set value data storage area "_NB_RANK", it is controlled by the main control board 50 so that "N + 1" is displayed on the set value display LED 73. NS.
Therefore, the description regarding the set value such as the set value "1" and the set value "6" is a numerical value displayed on the set value display LED 73, and is not necessarily the information stored in the set value data storage area "_NB_RANK". Is not always.
Of course, the specification may be such that any one of "1" to "6" is stored as the information related to the set value in the set value data storage area "_NB_RANK".

Further, in FIG. 81, “DEFB @LT_LOP OR 12; repeat count identifier ;; + repeat count data” is an OR of “@LT_LOP” and “12 (D)” (binary number “000001100 (B)”). It is shown that the data obtained by the calculation is stored in the first line of "small winning combination B1 conditional device lottery data to small winning combination B12 conditional device lottery data".
Here, as shown in FIG. 78, “@LT_LOP” indicates a repeat count identifier, and its value is “01000000 (B)”.

Further, when "@LT_LOP" and "12 (D)" (binary number "000001100 (B)") are OR-operated,
01000000 (B): @LT_LOP
000001100 (B): 12 (D)
0100100 (B): Data after OR calculation.
In other words, "DEFB @ LT_LOP OR 12" indicates that "0101001 (B)" is stored in a predetermined 1-byte storage area on the ROM 54.

Thereby, the repeat count identifier and the repeat count data can be represented by one 8-bit data. In this case, of the 8-bit data, bits 0 to bit 5 indicate the repetition count data, and bit 6 indicates the repetition count identifier.
Further, the comment "; repeat count identifier ;; + repeat count data" indicates that the data includes the repeat count identifier and the repeat count data.
Then, when the bit 6 is "1" as in "001001100 (B)", it is determined that the repetition count identifier is on, and it is determined that the data includes the repetition count data, and the bits 0 to 0 Bit 5 is used as the repetition count data.

FIG. 86 is a flowchart showing the flow of lottery processing such as the condition device number.
In step S1001, the main CPU 55 continues to determine whether or not the start switch 41 has been operated while a predetermined number of game media are bet (bet). Then, when it is determined that the start switch 41 has been operated, the process proceeds to the next step S1002.
In step S1002, the main CPU 55 acquires (latch) a random number value from the random number generating means (counter), and stores (stores) the acquired random number value in the random number value register. Then, the process proceeds to the next step S1003.
Proceeding to step S1003, the main CPU 55 controls the blocker 45 so that the insertion of medals is prohibited. Then, the process proceeds to the next step S1004.

In step S1004, the main CPU 55 executes the internal lottery 1 (FIG. 87). The internal lottery 1 is a process of determining a winning number from a random number value. Then, when the internal lottery 1 is executed, the process proceeds to the next step S1005.
In step S1005, the main CPU 55 executes the condition device number set 1 (FIG. 89). The condition device number set 1 is a process of determining the condition device number and the advantageous section number from the winning number. Then, when the condition device number set 1 is executed, the process proceeds to the next step S1006.
When the process proceeds to step S1006, the rotation of all the reels 31 is started, and the rotating reels 31 can be stopped by the operation of the stop switch 42 by the player. Then, when the rotation of all the reels 31 is stopped, the process according to this flowchart ends.

FIG. 87 is a flowchart showing the processing flow of the internal lottery 1.
Further, the internal lottery 1 is a process of determining a winning number from a random number value. The internal lottery 1 in FIG. 87 and the lottery determination process in FIG. 88, which will be described later, correspond to the winning number determining means.
Proceeding to the internal lottery 1 of step S1004, first, in step S1011, the main CPU 55 stores the random number value stored in the random number value register in the DE register. Then, the process proceeds to the next step S1012.

In step S1012, the main CPU 55 stores the start address of the lottery table according to the operating state of the accessory (when 1BBA is operating, when 1BBB is operating, or when the accessory is not operating) in the HL register.
Specifically, when 1BBA is activated, the start address of the 1BBA lottery table (TBL_LOTDAT_1BBA) shown in FIG. 84B is stored in the HL register. That is, the address indicating the data storage area of "DEFB @ LT_NUM OR @ NB_REP_D" in FIG. 84 (b) is stored in the HL register.

Further, when 1BBB is operated, the start address of the 1BBB lottery table (TBL_LOTDAT_1BBB) shown in FIG. 85 is stored in the HL register. That is, the address indicating the data storage area of "DEFB @ LT_NUM OR @ NB_REP_D" in FIG. 85 is stored in the HL register.
Furthermore, when the accessory is not activated, the start address of all RT common lottery tables (TBL_LOT_DAT1) shown in FIGS. 79 to 82 (a) is stored in the HL register. That is, the address indicating the data storage area of "DEFB @ LT_NUM OR @ BBA_WIN_E2" in FIG. 79 is stored in the HL register.

In the next step S1013, the main CPU 55 determines whether or not the accessory is operating.
Here, "_FL_ACTION" is a 1-byte storage area on the RWM 53 that stores a flag indicating the operating state of the accessory.
Further, when the value of the predetermined bit (for example, bit 2) of "_FL_ACTION" is "1", it indicates that the accessory is in operation, and when it is "0", it indicates that the accessory is not in operation.

Then, in step S1013, the main CPU 55 determines whether or not the accessory is operating by determining whether or not the value of the predetermined bit of the storage area "_FL_ACTION" of the RWM 53 is "0".
Here, when the value of the predetermined bit of "_FL_ACTION" is "0", the main CPU 55 determines that the accessory is not in operation (No), and proceeds to the next step S1014.
On the other hand, when the value of the predetermined bit of "_FL_ACTION" is "1", the main CPU 55 determines that the accessory is operating (Yes), skips steps S1014 to S1016, and proceeds to step S1017. move on.

In step S1014, the main CPU 55 executes the lottery determination (FIG. 88) using the lottery table set in step S1012. Further, the lottery determination is a process of determining whether or not a person has won by using the probability data. Then, when the lottery determination is executed, the process proceeds to the next step S1015.
Proceeding to step S1015, the main CPU 55 determines whether or not the lottery has been won.
Here, at the end of the lottery determination, a value indicating the winning number is stored in the C register. Further, when the value stored in the C register is "00 (H)", it indicates that the lottery determination has not been won, and the value stored in the C register is other than "00 (H)". If, it indicates that the player has won the lottery.

Then, in step S1015, the main CPU 55 determines whether or not the value stored in the C register is "00 (H)", thereby determining whether or not the lottery has been won.
Here, when the value stored in the C register is "00 (H)", the main CPU 55 determines that the lottery has not been won (No), and proceeds to the next step S1016.
On the other hand, when the value stored in the C register is other than "00 (H)", the main CPU 55 determines that the lottery has been won (Yes), skips steps S1016 and S1017, and skips steps S1016 and S1017. The process according to this flowchart ends.

Proceeding to step S1016, the main CPU 55 stores the start address of the lottery table according to the RT state (non-RT, RT1, RT2, RT3, or RT4) in the HL register.
Specifically, at the time of non-RT, the start address of the non-RT lottery table (TBL_LOTDAT_RT0) shown in FIG. 82 (b) is stored in the HL register. That is, the address indicating the data storage area of "DEFB @ LT_NUM OR @ NB_REP_A" in FIG. 82 (b) is stored in the HL register.

Further, at RT1, the start address of the RT1 o'clock lottery table (TBL_LOTDAT_RT1) shown in FIG. 82 (c) is stored in the HL register. That is, the address indicating the data storage area of "DEFB @ LT_NUM OR @ NB_REP_A" in FIG. 82 (c) is stored in the HL register.
The same applies to RT2, RT3, and RT4 as well as non-RT and RT1.
Then, when the start address of the lottery table corresponding to the RT state is stored in the HL register, the process proceeds to the next step S1017.

Proceeding to step S1017, the main CPU 55 executes the lottery determination (FIG. 88) using the lottery table set in step S1012 or S1016.
Specifically, when the accessory is activated, the lottery determination is executed using the lottery table set in step S1012, and when the accessory is not activated and the lottery determination in step S1014 is non-winning, the lottery determination is performed in step S1016. The lottery determination is executed using the set lottery table. Then, the process according to this flowchart is completed.

In this way, when the accessory is not operating (when "No" in step S1013), the lottery determination is performed at least once in step S1014, and the lottery determination is performed at most twice in steps S1014 and S1017. ..
On the other hand, when the accessory is activated (when "Yes" in step S1013), the lottery determination is performed only once in step S1017.

Further, when the accessory is not activated, the first lottery determination is made using the lottery table common to all RTs in step S1014, and if the lottery is not won at this time, then in step S1017, the lottery table according to the RT is performed. Is used to make a second lottery determination.
As described above, for the condition devices having the same winning probability in any of the non-RT, RT1, RT2, RT3, and RT4, the probability data is defined in the lottery table common to all RTs. As a result, the lottery table can be shared, so that the amount of ROM 54 used by the lottery table can be reduced.

FIG. 88 is a flowchart showing the flow of the lottery determination process.
Further, the lottery determination is a process of determining whether or not a person has won by using the probability data.
Proceeding to the lottery determination in step S1014 or S1017, first, in step S1021, the main CPU 55 determines whether or not the winning number identifier is on (data including the winning number identifier).
Here, at the start of the lottery determination process, the start address of the lottery table according to the operating state of the accessory is stored in the HL register (step S1012 in FIG. 87). For example, when the accessory is not activated, the HL register stores an address indicating the data storage area of "DEFB @ LT_NUM OR @ BBA_WIN_E2" in FIG. 79.

Further, when the bit 7 of the data corresponding to the address indicated by the HL register is "1", it indicates that the winning number identifier is on, and when the bit 7 is "0", the winning number identifier is off. Show that.
Then, in step S1021, the main CPU 55 determines whether or not the bit 7 of the data corresponding to the address indicated by the HL register is "1", so that the winning number identifier is turned on (including the winning number identifier). Judge whether it is data) or not.

Here, when the bit 7 of the data corresponding to the address indicated by the HL register is "1", the main CPU 55 determines that the winning number identifier is on (Yes), and proceeds to the next step S1022.
On the other hand, when the bit 7 of the data corresponding to the address indicated by the HL register is "0", the main CPU 55 determines that the winning number identifier is not on (No), skips step S1022, and steps. Proceed to S1023.
When "No" is set in step S1021, the main CPU 55 maintains the value of the C register. The value stored in the C register at this time is, for example, the value updated in step S1028 described later. Further, the value stored in the C register is determined as a winning number when it is determined in step S1027, which will be described later, that the winning (Yes) is won.

Proceeding to step S1022, the main CPU 55 acquires the winning number data from the lottery table.
Specifically, the main CPU 55 sets bit 7 of the data corresponding to the address indicated by the HL register to “0” and stores it in the C register.

For example, the data of "DEFB @ LT_NUM OR @ BBA_WIN_E2" in FIG. 79 is "10011111 (B)".
Further, in "10011111 (B)", bits 0 to 6 indicate winning number data, and bit 7 indicates a winning number identifier.
Then, the main CPU 55 sets bit 7 of "10011111 (B)" to "0" and stores "00011111 (B)" as winning number data in the C register.
After that, the main CPU 55 adds "1" to the value of the HL register to obtain a new HL register value. That is, the value of the HL register (address of data for lottery) is updated. Then, the process proceeds to the next step S1023.

Proceeding to step S1023, the main CPU 55 determines whether or not the repeat count identifier is on (data including the repeat count identifier).
Here, when the bit 6 of the data corresponding to the address indicated by the HL register is "1", it indicates that the repeat count identifier is on, and when the bit 6 is "0", the repeat count identifier is off. Indicates that there is.
Then, in step S1023, the main CPU 55 determines whether or not the bit 6 of the data corresponding to the address indicated by the HL register is "1", so that the repeat count identifier is turned on (including the repeat count identifier). Judge whether it is data) or not.

Here, when the bit 6 of the data corresponding to the address indicated by the HL register is "1", the main CPU 55 determines that the repeat count identifier is on (Yes), and proceeds to the next step S1024.
On the other hand, when the bit 6 of the data corresponding to the address indicated by the HL register is "0", the main CPU 55 determines that the repeat count identifier is not on (No), skips step S1024, and steps. Proceed to S1025.
Further, when "No" is set in step S1023, the main CPU 55 sets "1" in the B register. At this time, "1" set in the B register indicates that the number of times of hit / fail determination (number of repetitions) is one.

Proceeding to step S1024, the main CPU 55 acquires the repetition count data from the lottery table.
Specifically, the main CPU 55 sets bit 6 of the data corresponding to the address indicated by the HL register to “0” and stores it in the B register.

For example, the data of "DEFB @ LT_LOP OR 12" in FIG. 81 is "0100100 (B)".
Further, in "0100100 (B)", bits 0 to 3 indicate the repetition count data, and bit 6 indicates the repetition count identifier.
Then, the main CPU 55 sets the bit 6 of "00100110 (B)" to "0" and stores "00001100 (B)" in the B register as the repetition count data. In other words, the data indicating that it is repeated 12 times is stored in the B register.
Further, "0" is stored as an initial value in the A register.
After that, the main CPU 55 adds "1" to the value of the HL register to obtain a new HL register value. As a result, the value of the HL register is an identifier (1-byte data identifier or 2-byte data identifier) indicating how many bytes the probability data is, and an identifier (setting) indicating whether or not the probability data differs depending on the set value. It indicates the address of the storage area in which the data including the value-specific identifier) is stored. Then, the process proceeds to the next step S1025.

Proceeding to step S1025, the main CPU 55 acquires probability data from the lottery table.
Specifically, the main CPU 55 first saves the HL register value and the BC register value in the stack area of the RWM 53.
Next, the data corresponding to the address indicated by the HL register is stored in the B register. As a result, in the B register, an identifier (1-byte data identifier or 2-byte data identifier) indicating how many bytes the probability data is, and an identifier (setting value) indicating whether or not the probability data differs depending on the set value. Data including another identifier) is stored.

After that, "1" is added to the value of the HL register to obtain a new HL register value. As a result, the value of the HL register indicates the start address of the storage area in which the probability data is stored.
After that, the probability data is based on the data stored in the B register (data indicating whether the probability data is 1-byte data or 2-byte data, and whether the probability data differs depending on the set value). The address is calculated (designated), and the probability data corresponding to the calculated (designated) address is acquired from the lottery table and stored in the HL register or the A register. Then, the process proceeds to the next step S1026.

Here, the method of acquiring the probability data will be described in more detail.
As described above, in the predetermined storage area (set value data storage area "_NB_RANK") of the RWM 53, any value of "0" to "5" is stored as information regarding the set value.
Further, "0" is stored as an initial value in the A register.

Example 1) When the 1-byte data identifier is on and the set value-specific identifier is off, the value of the A register (“0”) is added to the value of the HL register to obtain the value of the new HL register. In this case, the value of the HL register is maintained (not changed). Then, the value of this HL register is used as the address of the probability data, and the probability data corresponding to this address is acquired from the lottery table.
When the probability data is 1-byte data, the acquired probability data is stored in the A register.

Example 2) When the 1-byte data identifier is on and the set value-specific identifier is on Since the set value-specific identifier is on, the value of the set value data storage area "_NB_RANK" is stored in the A register. As a result, "N" (N is a value corresponding to the set value; any value of "0" to "5") is stored in the A register.
After that, the value of the A register (“N”) is added to the value of the HL register to obtain a new HL register value.

Here, when "0" is stored in "_NB_RANK" (when the set value is "1"), the value of the HL register is maintained (not changed). As a result, the value of the HL register indicates the address of the storage area in which the first probability data is stored. For example, in the case of 1BBA + small winning combination E2 condition device lottery data in the all RT common lottery table (1) of FIG. 79, the address of "DEFB 10; probability data (setting 1)" is indicated.

Further, when "5" is stored in "_NB_RANK" (when the set value is "6"), "5" is added to the value of the HL register. As a result, the value of the HL register indicates the address of the storage area in which the sixth probability data is stored. For example, in the case of 1BBA + small winning combination E2 condition device lottery data in the all RT common lottery table (1) of FIG. 79, the address of "DEFB 20; probability data (setting 6)" is indicated.
Then, the value of this HL register is used as the address of the probability data, and the probability data corresponding to this address is acquired from the lottery table.
It should be noted that storing the acquired probability data in the A register is the same as in Example 1.

Example 3) When the 2-byte data identifier is on and the set value-specific identifier is off, the value of the A register ("0") is added to the value of the HL register to obtain the value of the new HL register. Further, the value of the A register (“0”) is added to obtain the value of the new HL register. That is, the value of the A register is added to the value of the HL register to obtain a new HL register value, which is repeated twice. In this case, the value of the HL register is maintained (not changed). Then, the value of this HL register is used as the address of the probability data, and the probability data corresponding to this address is acquired from the lottery table.
When the probability data is 2-byte data, the acquired probability data is stored in the HL register.

Example 4) When the 2-byte data identifier is on and the set value-specific identifier is on Since the set value-specific identifier is on, the value of the set value data storage area "_NB_RANK" is stored in the A register. As a result, "N" (N is a value corresponding to the set value; any value of "0" to "5") is stored in the A register.
Further, the value of the A register ("N") is added to the value of the HL register to obtain a new HL register value, and the value of the A register ("N") is further added to the new HL register value. The value of. That is, the value of the A register (“N”) is added to the value of the HL register to obtain a new HL register value, which is repeated twice.

Here, when "0" is stored in "_NB_RANK" (when the set value is "1"), the value of the HL register is maintained (not changed). As a result, the value of the HL register indicates the address of the storage area in which the first probability data is stored. For example, in the case of the small winning combination A condition device lottery data in the all RT common lottery table (3) of FIG. 81, the address of "DEFW 1000; probability data (setting 1)" is indicated.

Further, when "5" is stored in "_NB_RANK" (when the set value is "6"), "10" is added to the value of the HL register. As a result, the value of the HL register indicates the address of the storage area in which the sixth probability data is stored. For example, in the case of the small winning combination A condition device lottery data in the all RT common lottery table (3) of FIG. 81, the address of "DEFW 1250; probability data (setting 6)" is indicated.
Then, the value of this HL register is used as the address of the probability data, and the probability data corresponding to this address is acquired from the lottery table.
It should be noted that storing the acquired probability data in the HL register is the same as in Example 3.

In this way, the start address (address of the first probability data) of the storage area in which the probability data is stored is stored in the HL register, and the value stored in the A register is used as the offset value in the HL register. By adding to the value of, the probability data corresponding to the set value is acquired.

Here, when the set value-specific identifier is off, the initial value (“0”) stored in the A register is added to the value of the HL register as an offset value.
When the set value-specific identifier is on, the value of the set value data storage area "_NB_RANK" is stored in the A register, and the value of the A register is added to the value of the HL register as an offset value.
As a result, the processing can be standardized depending on whether the probability data is common to all the set values or different depending on the set values, so that the amount of ROM 54 used by the program can be reduced.

When the probability data is 1-byte data, the value of the A register is added to the HL register once, and when the probability data is 2-byte data, the value of the A register is added to the HL register twice.
As a result, the process of calculating (designating) the address of the probability data can be simplified, so that the amount of ROM 54 used by the program can be reduced.

Proceeding to step S1026, the main CPU 55 determines whether or not the result is correct.
Here, when the lottery determination is performed using the probability data of 2-byte data and the random number value, the main CPU 55 first subtracts the value of the HL register from the value of the DE register to obtain a new value of the DE register. ..
Further, when the lottery determination is performed using the probability data of 1-byte data and the random number value, the main CPU 55 first subtracts the value of the A register from the value of the DE register to obtain a new value of the DE register.
In this way, the value of the DE register is updated.
As described above, a random number value is stored in the DE register (step S1011 in FIG. 87). Then, in step S1026, the probability data is subtracted from the value of the DE register to obtain a new value of the DE register.

After that, the value of the HL register and the value of the BC register saved in the stack area of the RWM53 are restored.
As a result, the value of the HL register is an identifier (1-byte data identifier or 2-byte data identifier) indicating how many bytes the probability data is, and an identifier (setting) indicating whether or not the probability data differs depending on the set value. It indicates the address of the storage area in which the data including the value-specific identifier) is stored. Further, the value of the B register indicates the number of repetitions, and the value of the C register indicates the winning number.

In the next step S1027, the main CPU 55 determines whether or not it has won.
Here, by subtracting the probability data from the value of the DE register, when the value of the DE register becomes smaller than "0" (when a carry occurs), "1" is set in the carry flag of the flag register. That is, the carry flag is set. Further, "carry occurs" means that "1" is set in the carry flag.
Then, in step S1027, the main CPU 55 determines whether or not the carry flag has been won by determining whether or not the carry flag is set to "1".

Here, when the carry flag is not set to "1", the main CPU 55 determines that the carry flag has not been won (No), and proceeds to the next step S1028.
On the other hand, when the carry flag is set to "1", the main CPU 55 determines that the carry flag has been won (Yes), skips steps S1028 to S1033, and ends the process according to this flowchart.
Further, the value stored in the C register at the time of "Yes" in step S1027 indicates the winning number determined by the lottery determination.

In the next step S1028, the main CPU 55 updates the winning number data.
Specifically, the main CPU 55 adds "1" to the value of the C register to obtain a new value of the C register. That is, the value of the C register is updated. Then, the process proceeds to the next step S1029.
Proceeding to step S1029, the main CPU 55 updates the repetition count data.
Specifically, the main CPU 55 subtracts "1" from the value of the B register to obtain a new value of the B register. That is, the value of the B register is updated. Then, the process proceeds to the next step S1030.

Proceeding to step S1030, the main CPU 55 determines whether or not the number of repetitions has been completed.
Specifically, the main CPU 55 determines whether or not the value of the B register is "0".
Here, when the value of the B register is "0", it indicates that the number of repetitions has ended, and when the value of the B register is not "0" (greater than "0"), the number of repetitions has ended. Indicates that there is no such thing.
Then, in step S1030, the main CPU 55 determines whether or not the number of repetitions has ended by determining whether or not the value of the B register is "0".

Here, when the value of the B register is "0", the main CPU 55 determines that the number of repetitions has ended (Yes), and proceeds to the next step S1031.
On the other hand, when the value of the B register is not "0", the main CPU 55 determines that the number of repetitions has not ended (No), and returns to step S1025.

Further, when "No" is set in step S1030, in order to maintain the value of the HL register, the pass / fail judgment of step S1026 is performed again using the same probability data as the previous time.
In this way, since the same probability data as the previous time is set to be used repeatedly, it is not necessary to repeatedly set the same probability data in the lottery table, so that the amount of ROM 54 used by the lottery table can be reduced.

Proceeding to step S1031, the main CPU 55 sets the address of the next lottery data.
Specifically, the main CPU 55 updates the value of the HL register according to the following Examples 1) to 4).
Example 1) When the 1-byte data identifier is on and the set value-specific identifier is off, "1 + 1" (= "2") is added to the HL register value to obtain a new HL register value.

Example 2) When the 1-byte data identifier is on and the set value-specific identifier is on, "6 + 1" (= "7") is added to the HL register value to obtain a new HL register value.
Example 3) When the 2-byte data identifier is on and the set value-specific identifier is off, add "1 x 2 + 1" (= "3") to the HL register value to obtain the new HL register value. do.
Example 4) When the 2-byte data identifier is on and the identifier for each set value is on, add "6 x 2 + 1" (= "13") to the value of the HL register to obtain the value of the new HL register. do.

As described above, in step S1026, the value of the HL register saved in the stack area of the RWM 53 is restored.
Therefore, at the time of proceeding to step S1031, the value of the HL register differs depending on the identifier (1-byte data identifier or 2-byte data identifier) indicating how many bytes the probability data is, and whether the probability data is different depending on the set value. Indicates the address of the storage area in which data including an identifier (identifier for each set value) indicating whether or not is stored is stored.

Then, when the 1-byte data identifier is on and the set value-specific identifier is off, the lottery data (for example, the 1BBA condition device lottery data in the all RT common lottery table (1) of FIG. 79) The number of bytes of the probability data is 1 byte.
Therefore, by adding "2" to the value of the HL register, the value of the new HL register is the next lottery data (for example, 1BBA + small winning combination D condition device in the all RT common lottery table (1) of FIG. 79). The start address of the storage area of the lottery data) (for example, the address of the storage area in which the data of "DEFB @ LT_BYT; 1-byte data identifier" is stored) is indicated.

When the 1-byte data identifier is on and the set value-specific identifier is on, the lottery data (for example, 1BBA + small winning combination E2 condition device lottery in the lottery table (1) common to all RTs in FIG. 79). The number of bytes of the probability data in (data) is 6 bytes.
Therefore, by adding "7" to the value of the HL register, the value of the new HL register is the next lottery data (for example, 1BBB condition device lottery data in the all RT common lottery table (1) of FIG. 79). ) Is indicated (for example, the address of the storage area in which the data of "DEFB @LT_BYT OR @LT_RNK; 1-byte data identifier ;; + identifier for each set value" is stored).

Furthermore, when the 2-byte data identifier is on and the set value-specific identifier is off, the lottery data (for example, for the small winning combination D condition device lottery in the all RT common lottery table (1) of FIG. 79). The number of bytes of the probability data in (data) is 2 bytes.
Therefore, by adding "3" to the value of the HL register, the value of the new HL register is the next lottery data (for example, the small winning combination E1 condition device lottery in the all RT common lottery table (1) of FIG. 79). The start address of the storage area (for example, the address of the storage area in which the data of "DEFB @ LT_WRD; 2-byte data identifier" is stored) is indicated.

Further, when the 2-byte data identifier is on and the set value-specific identifier is on, the lottery data (for example, the small winning combination A condition device lottery data in the all RT common lottery table (3) of FIG. 81). The number of bytes of the probability data in) is 12 bytes.
Therefore, by adding "13" to the value of the HL register, the value of the new HL register can be changed to the next lottery data (for example, small winning combination B1 to small winning combination in the all RT common lottery table (3) of FIG. 81). The start address of the storage area of the B12 conditional device lottery data) (for example, the address of the storage area in which the data of "DEFB @ LT_LOP OR 12; repeat count identifier" is stored) is indicated.

In the next step S1032, the main CPU 55 determines whether or not the data corresponding to the address indicated by the HL register is the determination end identifier (“00 (H)”).
Here, when the data corresponding to the address indicated by the HL register is "00 (H)", the main CPU 55 determines that it is the determination end identifier (Yes), and proceeds to the next step S1033.
On the other hand, when the data corresponding to the address indicated by the HL register is not "00 (H)", the main CPU 55 determines that it is not the determination end identifier (No), and returns to step S1021.

In the next step S1033, the main CPU 55 sets the non-winning data.
Here, at the time of proceeding to step S1033, the data corresponding to the address indicated by the HL register is “00 (H)” (determination end identifier). Then, in step S1033, the main CPU 55 stores "00 (H)", which is the data corresponding to the address indicated by the HL register, in the C register as non-winning data. Then, the process according to this flowchart is completed.

Further, the value stored in the C register at the end of this flowchart (lottery determination) indicates the winning number determined by the lottery determination.
When the process proceeds to step S1033, the value stored in the C register at the end of this flowchart is “00 (H)”. In this case, it will not be won (it will not win any of the conditional devices).

In this way, by setting the data of the determination end identifier indicating the end of the lottery determination process to "00 (H)", if any of the condition devices is not won in the lottery determination process, no winner is won. The winning number "0" indicating (loss) is stored in the C register, and this flowchart ends. The winning number less than "31" matches the winning and replay condition device number.
In other words, it is possible to store the winning number indicating non-winning in the C register by acquiring the data of the determination end identifier without newly setting the winning number indicating non-winning.
On the other hand, when "Yes" is set in step S1027, the value stored in the C register at the end of this flowchart is other than "00 (H)". In this case, one of the conditional devices is won (a winning number other than "0" is determined).

Here, for example, a lottery result (also referred to as a push order small combination) in which the degree of advantage (payout number) differs depending on the operation mode (push order) of the stop switch 42, such as from the small combination B1 condition device to the small combination B12 condition device. As for the lottery result accompanied by RT transition depending on the operation mode of the stop switch 42, as in the case of the replay B1 condition device to the replay B3 condition device, the degree of advantage and the rate of RT transition are not biased depending on the operation mode of the stop switch 42. It is preferable to do so. That is, it is preferable that the frequency of appearance of correct answers is not biased depending on the pushing order.

Therefore, it is preferable to determine the same probability data so that the advantageous operation modes corresponding to the types of lottery results (conditional devices) are equal in each operation mode. That is, it is preferable to set the same probability data so that the frequency of appearance of correct answers is equal in each push order.
In such a case, the number of repetitions is determined, and the lottery determination is performed by repeatedly using the same probability data, thereby reducing the amount of ROM 54 used by the lottery table and equalizing the appearance frequency of correct answers in each push order. Therefore, it is possible to exert a greater effect.

Further, as described in step S1028, since the process of updating the winning number data is included in the lottery determination process, it is not necessary to store the winning number data in the lottery table.
Then, by determining the winning number using the number of repetitions and the same probability data, a related condition device (for example, from the small winning combination B1 conditional device to the small winning combination B12 conditional device, or from the replay B1 conditional device to the replay B3 condition). Regarding the device), the winning numbers of consecutive winning numbers (from the small winning combination B1 conditional device to the small winning combination B12 conditional device are from "12" to "22", and from the replay B1 conditional device to the replay B3 conditional device are "2". You can get "4") from the number.

As described above, in the present embodiment, the winning number less than "31" coincides with the winning and replay condition device number.
Further, at least in the normal section, the winning and replay condition device numbers are not transmitted to the sub control board 80 but are transmitted as the effect group number.
In such a case, consecutive winning numbers (for example, "12" to "22") can be obtained for the related conditional devices (for example, from the small winning combination B1 conditional device to the small winning combination B12 conditional device). By doing so, when the process of converting the winning number to the effect group number is executed, the effect group number can be determined by determining which range the acquired winning number belongs to.
Therefore, it is not necessary to have a table for determining which effect group number the acquired winning number is, so that the usage amount of the ROM 54 can be further reduced.

FIG. 89 is a flowchart showing a processing flow of the condition device number set 1.
Further, the conditional device number set 1 is a process of determining the conditional device number and the advantageous section number from the winning number. The process of the condition device number set 1 corresponds to the condition device number determination means.
Proceeding to the condition device number set 1 of step S1005, first, in step S1041, the main CPU 55 determines whether or not the winning number determined by the internal lottery 1 and the lottery determination is smaller than the conversion start number.

Here, at the start of the processing of the condition device number set 1, a value indicating the winning number determined by the internal lottery 1 and the lottery determination is stored in the C register.
Further, in step S1041, the main CPU 55 first stores the value of the C register (winning number) in the A register, and then subtracts "@NB_TRNS" from the value of the A register. As shown in FIG. 76 (a), “@NB_TRNS” indicates a conversion start number, and the value thereof is “@ BBA_WIN_E2”. Further, as shown in FIG. 75 (a), "@BBA_WIN_E2" indicates a duplicate winning of 1BBA and a small winning combination E2, and the value thereof is "31". Therefore, "@NB_TRNS" = "31".

Then, the main CPU 55 subtracts "31" from the value of the A register, and when a carry occurs due to the subtraction, determines that the winning number is smaller than the conversion start number (Yes), and skips steps S1042 to S1046. , Step S1047.
On the other hand, when the carry does not occur due to the subtraction, the main CPU 55 determines that the winning number is equal to or higher than the conversion start number (No), and proceeds to the next step S1042.
In step S1041, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

In step S1042, the main CPU 55 acquires the condition device number and the advantageous section number from the winning number.
Specifically, the main CPU 55 first stores the calculation result of "TBL_CNDNO_DAT"-"@NB_TRNS" x 3 in the HL register.
Here, "TBL_CNDNO_DAT" indicates the start address of the winning number conversion table (FIG. 77 (a)).
For example, "TBL_CNDNO_DAT" = "1600 (H)" address.
Further, as described above, "@NB_TRNS" = "31".
In this case, the value of the HL register is
"1600 (H)"-"31 (D)" x 3
= "1600 (H)"-"5D (H)"
= "15A3 (H)"
Will be.

Next, the main CPU 55 repeats adding the value of the A register to the value of the HL register to obtain a new HL register value three times.
For example, assume that the value of the A register (indicating the winning number) is "32".
Further, "32 (D)" = "20 (H)".
In this case, the value of the HL register is
"15A3 (H)" + "20 (H)" = "15C3 (H)" (1st time)
"15C3 (H)" + "20 (H)" = "15E3 (H)" (second time)
"15E3 (H)" + "20 (H)" = "1603 (H)" (3rd time)
Will be.
As a result, the "address of the conditional device number and the advantageous section number corresponding to the winning number" is set in the HL register.

Next, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the C register.
For example, when the value of the HL register is "1603 (H)", the data corresponding to this address is "@ NB_1BBB" (= "2"). In addition, this data indicates the "accessory condition device number" (FIGS. 77 (a) and 77 (d)).
In this case, the main CPU 55 stores "2" in the C register. As a result, "2" indicating the "accessory condition device number" is stored in the C register. After that, the value of the C register is maintained until the end of this flowchart (condition device number set 1).
After that, the main CPU 55 adds "1" to the value of the HL register to obtain a new HL register value. As a result, the value of the HL register becomes "1604 (H)".

Next, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the A register.
For example, when the value of the HL register is "1604 (H)", the data corresponding to this address is "0". In addition, this data shows "winning and replay condition device numbers" (FIGS. 77 (a) and 77 (d)).
In this case, the main CPU 55 stores "0" in the A register. As a result, "0" indicating "winning and replay condition device number" is stored in the A register. After that, the value of the A register is maintained until the end of this flowchart (condition device number set 1).

After that, the main CPU 55 adds "1" to the value of the HL register to obtain a new HL register value. As a result, the value of the HL register becomes "1605 (H)". After that, the value of the HL register is maintained until the end of this flowchart (condition device number set 1).
When the value of the HL register is "1605 (H)", the data corresponding to this address is "0". In addition, this data shows an "advantageous section number" (FIGS. 77 (a) and 77 (d)).

In step S1043, the main CPU 55 determines whether or not the accessory condition device number is “0”.
Here, "_NB_CND_BNS" is a 1-byte storage area on the RWM 53 that stores the accessory condition device number.
Further, when the value of "_NB_CND_BNS" is "0", it indicates that the character condition device has not been won, and when it is other than "0", it indicates that the character condition device has been won.

Furthermore, the previous game is a non-internal game, and when the character condition device is won in this game, the main CPU 55 stores the character condition device number in "_NB_CND_BNS" in step S1046 described later.
Further, when the combination of symbols corresponding to the special combination included in the winning accessory condition device stops at the effective line, the main CPU 55 clears the value of "_NB_CND_BNS" (sets it to "0").

Therefore, the previous game is a non-internal game, and when the character condition device is won in this game, the value of "_NB_CND_BNS" is "0" in step S1043.
Further, in step S1043, when the value of "_NB_CND_BNS" is other than "0", the combination of symbols corresponding to the special combination included in the winning character condition device was won before the previous game. Means that has not yet stopped at the valid line. That is, it means that the game is an internal game in which the winning information of the special role is carried over.

Then, in step S1043, the main CPU 55 determines whether or not the character condition device has been won by determining whether or not the value of the storage area "_NB_CND_BNS" of the RWM 53 is "0". That is, it is determined whether or not it is inside.
Here, when the value of "_NB_CND_BNS" is "0" (Yes), the main CPU 55 determines that the accessory condition device has not been won, and proceeds to the next step S1044.
On the other hand, when the value of "_NB_CND_BNS" is other than "0" (No), the main CPU 55 determines that the accessory condition device has been won, skips steps S1044 to S1046, and steps S1047. Proceed to.

In step S1044, the main CPU 55 determines whether or not the advantageous section number is “0”.
Here, "_NB_CND_AT" is a 1-byte storage area on the RWM 53 that stores the advantageous section number.
Further, when the value of "_NB_CND_AT" is "0", it indicates that the player has not won the advantageous section (decided to shift), and when the value is "1", it indicates that the player has won the advantageous section 1. When it is "2", it means that the advantageous section 2 has been won.

Furthermore, the previous game is a normal section game, and when the advantageous section 1 or the advantageous section 2 is won in this game, the main CPU 55 stores the advantageous section number in "_NB_CND_AT" in step S1045 described later.
Further, when the process shifts to the advantageous section 1 or the advantageous section 2 based on the winning of the advantageous section 1 or the advantageous section 2, and then the advantageous section 1 or the advantageous section 2 ends and returns to the normal section, the main CPU 55 receives the advantage section 1. Clear the value of "_NB_CND_AT" (set it to "0").

Therefore, the previous game is a normal section game, and when the advantageous section 1 or the advantageous section 2 is won in this game, the value of "_NB_CND_AT" is "0" in step S1044.
Further, in step S1044, when the value of "_NB_CND_AT" is other than "0", the advantageous section 1 or the advantageous section 2 was won before the previous game, and the advantageous section 1 or the advantageous section 2 shifted based on this winning. Means that is not finished yet. That is, it means that the game is a waiting section, an advantageous section 1, or an advantageous section 2.

Then, in step S1044, the main CPU 55 determines whether or not the advantageous section 1 or the advantageous section 2 has been won by determining whether or not the value of the storage area "_NB_CND_AT" of the RWM 53 is "0". do.
Here, when the value of "_NB_CND_AT" is "0" (Yes), the main CPU 55 determines that the advantageous section 1 or the advantageous section 2 has not been won, and proceeds to the next step S1045.
On the other hand, when the value of "_NB_CND_AT" is other than "0" (No), the main CPU 55 determines that the advantageous section 1 or the advantageous section 2 has been won, skips step S1045, and steps. Proceed to S1046.

In step S1045, the main CPU 55 stores the advantageous section number.
Specifically, at the time of proceeding to step S1045, a value indicating the address of the advantageous section number is stored in the HL register.
Then, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the storage area “_NB_CND_AT” of the RWM 53. As a result, the advantageous section number is saved.

In step S1046, the main CPU 55 stores the accessory condition device number.
Specifically, at the time of proceeding to step S1046, a value indicating the accessory condition device number is stored in the C register.
Then, the main CPU 55 stores the value of the C register in the storage area "_NB_CND_BNS" of the RWM53. As a result, the accessory condition device number is saved.

In step S1047, the main CPU 55 stores the winning and replay condition device numbers.
Here, when “Yes” is set in step S1041 and the process proceeds to step S1047, a value indicating a “winning number” is stored in the A register. When "Yes" is set in step S1041 (when the winning number is smaller than the conversion start number), "winning number" = "winning and replay condition device number" as shown in FIG. 74 (a). It is stipulated in. Therefore, when the result becomes “Yes” in step S1041 and the process proceeds to step S1047, the value of the A register indicates the “winning and replay condition device number”.

Further, in step S1042, a value indicating "winning and replay condition device number" is stored in the A register. Therefore, even when proceeding to step S1047 through step S1042, the value of the A register indicates the "winning and replay condition device number".
As described above, at the time of proceeding to step S1047, the value indicating the winning and replay condition device number is stored in the A register.

Further, "_NB_CND_NOR" is a 1-byte storage area on the RWM 53 that stores the winning and replay condition device numbers.
Then, the main CPU 55 stores the value of the A register in the storage area "_NB_CND_NOR" of the RWM53. As a result, the winning and replay condition device numbers are saved.
In this way, the winning and replay condition device numbers are set depending on whether the step S1041 is "Yes" and the process proceeds to step S1047, or the step S1041 is "No" and the step S1042 is followed by the step S1047. The process of storing in "_NB_CND_NOR" can be shared, and the amount of ROM 54 used by the program can be reduced.
The main CPU 55 clears the value of "_NB_CND_NOR" (sets to "0") at the end of the game or before the operation of the start switch 41 can be accepted in the next game.

As described above, in the condition device number set 1, it is determined whether or not the value of "_NB_CND_BNS" is "0" before the timing (step S1046) of storing the accessory condition device number in "_NB_CND_BNS". (Step S1043).
As a result, even if there is no flag indicating whether or not it is inside, whether or not it is inside (whether or not the character condition device was won in this game, or the character condition device was won before the previous game). Since it is possible to determine whether or not the RWM53 has been used, the amount of RWM53 used can be reduced accordingly.

Further, in the condition device number set 1, it is determined whether or not the value of "_NB_CND_BNS" is "0" (step S1043), and when it is determined to be "0", the advantageous section number is set to "_NB_CND_AT". The accessory condition device number is stored in "_NB_CND_BNS" (step S1046), and the winning and replay condition device numbers are stored in "_NB_CND_NOR" (step S1047).
As a result, it is possible to decide to shift to the advantageous section 1 or the advantageous section 2 in the game in which the accessory condition device is won, without requiring complicated processing.

Further, in the game, when the winning numbers are determined to be "31" to "36", "43" to "45", or "48" to "50", the accessory condition device. Will be elected.
In this case, when it is determined in step S1043 that "0" is stored in "_NB_CND_BNS", the process proceeds to step S1044, so that the value of "_NB_CND_BNS" and the value of "_NB_CND_AT" can be updated.
On the other hand, when it is determined in step S1043 that a value other than "0" is stored in "_NB_CND_BNS", steps S1044 to S1046 are skipped, so that the value of "_NB_CND_BNS" and the value of "_NB_CND_AT" are maintained. Will be done.

In this way, when "0" is stored in "_NB_CND_BNS", the value of "_NB_CND_BNS" and the value of "_NB_CND_AT" can be updated, and a value other than "0" is stored in "_NB_CND_BNS". At the time, the value of "_NB_CND_BNS" and the value of "_NB_CND_AT" are maintained.
As a result, it is possible to appropriately process the winning of the accessory condition device and the decision to shift to the advantageous section within a certain range of the usage amount of RWM55 without requiring complicated processing.

In addition, when the winning number is determined to be "43" to "47" in the game, the winning number is won (decided to shift) to the advantageous section 1 and the winning number is "48" to "52". When the turn is decided, the advantage section 2 is won (decided to shift).
In this case, when it is determined in step S1044 that "0" is stored in "_NB_CND_AT", the process proceeds to step S1045, so that the value of "_NB_CND_AT" can be updated.
On the other hand, when it is determined in step S1044 that a value other than "0" is stored in "_NB_CND_AT", step S1045 is skipped, so that the value of "_NB_CND_AT" is maintained.

In this way, when "0" is stored in "_NB_CND_AT", the value of "_NB_CND_AT" can be updated, and when "_NB_CND_AT" stores a value other than "0", "_NB_CND_AT" is stored. Maintain the value of.
Thereby, it is possible to appropriately process the determination to shift to the advantageous section within a certain range of the usage amount of RWM55 without requiring complicated processing.

In the present embodiment, the process of storing the advantageous section number in "_NB_CND_AT" (step S1044) is skipped, or the process of storing the accessory condition device number in "_NB_CND_BNS" (step S1046) is skipped. The value of "_NB_CND_BNS" and the value of "_NB_CND_AT" were maintained.
However, the present invention is not limited to this, for example, by storing (overwriting) the same advantageous section number in "_NB_CND_AT" or by storing (overwriting) the same accessory condition device number in "_NB_CND_BNS", the "_NB_CND_BNS" The value or the value of "_NB_CND_AT" may be maintained.

Further, in this game, when the winning number is determined to be less than "31", it becomes "Yes" in step S1041 and the process proceeds to step S1047. At this time, the winning number is stored in the A register. Then, in step S1047, the value of the A register is stored in "_NB_CND_NOR" as the winning and replay condition device number.
That is, when the winning number is less than "31", it is stipulated that "winning number" = "winning and replay condition device number".

Then, only when the winning number is "31" or more, the conditional device number is determined from the winning number by using the winning number conversion table that defines the correspondence between the winning number and the conditional device number.
Therefore, for numbers less than "31", it is not necessary to determine the correspondence between the winning number and the conditional device number in the winning number conversion table, so that the amount of ROM 54 used by the winning number conversion table can be reduced.

In the present embodiment, the lottery regarding the transition from the normal section to the advantageous section has been described. For example, at the start of the game this time, a value other than "0" is stored in "_NB_CND_AT" (storage area of the advantageous section number). Even if it is, it is related to the addition of the advantageous section (including changing the performance so that the gaming state in the advantageous section is advantageous to the player and adding the number of AT games in the advantageous section). The lottery may be executed and the value of "_NB_CND_AT" may be changed according to the result.

For example, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" (storage area of the accessory condition device number) is "0", the winning number is determined to be "37". A control process for storing "2" in "_NB_CND_AT" may be executed based on the above.
Further, in the situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" is "0", the lottery regarding the addition of the advantageous section is based on the fact that the winning number is determined to be "37". May be executed.

Furthermore, the winning numbers "43" to "52" were treated as a lottery regarding the transition from the normal section to the advantageous section, but it is also advantageous when these winning numbers are determined in the advantageous section. A lottery regarding the addition of sections may be executed.
As described above, when the value of "_NB_CND_BNS" is "1" (so-called internal), for example, even if the winning number is determined to be "37", the lottery regarding the addition of the advantageous section is not executed.

<Modified example of the 16th embodiment>
Subsequently, a modified example of the 16th embodiment of the present invention will be described.
In the modified example of the 16th embodiment, the processing of the condition device number set is different from that of the 16th embodiment.
In the process of the condition device number set 1 of the 16th embodiment, the advantageous section number is stored in "_NB_CND_AT", and then the accessory condition device number is stored in "_NB_CND_BNS".
On the other hand, in the condition device number set 2 of the modified example of the 16th embodiment, the accessory condition device number is stored in "_NB_CND_BNS", and then the advantageous section number is stored in "_NB_CND_AT".

FIG. 90 is a flowchart showing a flow of lottery processing such as a condition device number in a modified example of the 16th embodiment.
Steps S1001 to S1004 and step S1006 are the same as those in the 16th embodiment.
Further, in the present embodiment, when the internal lottery 1 is executed in step S1004, the process proceeds to step S1051.

Further, when the process proceeds to step S1051, the condition device number set 2 (FIG. 92) is executed, and the process proceeds to step S1006.
Further, in step S1006, the rotation of all the reels 31 is started, and the rotating reels 31 can be stopped by the operation of the stop switch 42 by the player. Then, when the rotation of all the reels 31 is stopped, the process proceeds to step S1052, and the processing at the time of stopping all reels (FIG. 91) is executed.
Then, when the processing at the time of stopping all reels is executed in step S1052, the processing according to this flowchart ends.

FIG. 91 is a flowchart showing a flow of processing when all reels are stopped in a modified example of the 16th embodiment.
Further, the processing at the time of stopping all reels is a processing for controlling on / off of the internal middle flag indicating that the winning information of the special combination is carried over after the rotation of all the reels 31 is stopped.
Proceeding to the process when all reels are stopped in step S1052, first, in step S1061, the main CPU 55 determines whether or not the combination of symbols corresponding to the special combination has stopped at the effective line.

Here, when it is determined that the combination of symbols corresponding to the special combination has stopped at the effective line (Yes), steps S1062 and S1063 are skipped, and the process proceeds to step S1064.
On the other hand, when it is determined that the combination of symbols corresponding to the special combination is not stopped at the effective line (No), the process proceeds to the next step S1062.

In step S1062, the main CPU 55 determines whether or not the accessory condition device number is “0”.
Specifically, the main CPU 55 determines whether or not the accessory condition device has been won by determining whether or not the value of the storage area "_NB_CND_BNS" of the RWM 53 is "0".
Here, when the value of "_NB_CND_BNS" is other than "0" (No), the main CPU 55 determines that the accessory condition device has been won, and proceeds to the next step S1063.
On the other hand, when the value of "_NB_CND_BNS" is "0" (Yes), the main CPU 55 determines that the accessory condition device has not been won, and ends the process according to this flowchart.

In step S1063, the main CPU 55 turns on the internal medium flag.
Here, "_FL_PRD_LOT" is a 1-byte storage area on the RWM53 that stores the internal flag.
In addition, the "internal middle flag" is a flag indicating that the game is an internal game in which the winning information of the special role is carried over.
Furthermore, when the value of "_FL_PRD_LOT" is "FF (H)", it indicates that the internal internal flag is on, and when it is "0", it indicates that the internal internal flag is off.

Then, in step S1063, the main CPU 55 stores "FF (H)" in the storage area "_FL_PRD_LOT" of the RWM 53. Then, the process according to this flowchart is completed.
In step S1064, the main CPU 55 clears the internal middle flag.
Specifically, the main CPU 55 sets the value of the storage area "_FL_PRD_LOT" of the RWM 53 to "0". Then, the process proceeds to the next step S1065.
In step S1065, the main CPU 55 clears the accessory condition device number.
Specifically, the main CPU 55 sets the value of the storage area "_NB_CND_BNS" of the RWM 53 to "0". Then, the process according to this flowchart is completed.

FIG. 92 is a flowchart showing a processing flow of the condition device number set 2.
Further, the conditional device number set 2 is a process of determining the conditional device number and the advantageous section number from the winning number.
Proceeding to the condition device number set 2 in step S1051, first, in step S1071, the main CPU 55 determines whether or not the winning number is smaller than the conversion start number.
The specific processing content in step S1071 is the same as that in step S1041 of FIG. 89.

Then, when it is determined in step S1071 that the winning number is smaller than the conversion start number (Yes), steps S1072 to S1074 are skipped and the process proceeds to step S1075.
On the other hand, when it is determined in step S1071 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1072.
In step S1071, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

In step S1072, the main CPU 55 acquires the condition device number and the advantageous section number from the winning number.
Here, in step S1042 of FIG. 89, a value indicating the “accessory condition device number” is stored in the C register.
On the other hand, in step S1072, a value indicating the “accessory condition device number” is stored in the E register.
In the condition device number set 2, the value of the C register (winning number) is used in steps S1071 and S1076, so that the value of the C register (winning number) is not destroyed in step S1072.
Other than that, the specific contents of the process in step S1072 are the same as those in step S1042 of FIG. 89.

In step S1073, the main CPU 55 determines whether or not the accessory condition device number is “0”.
The specific content of the process in step S1073 is the same as that in step S1043 of FIG. 89.
Then, when it is determined in step S1073 that the accessory condition device number is "0" (Yes), the process proceeds to the next step S1074.
On the other hand, when it is determined in step S1073 that the accessory condition device number is other than "0" (No), step S1074 is skipped and the process proceeds to step S1075.

In step S1074, the main CPU 55 stores the accessory condition device number.
Specifically, at the time of proceeding to step S1074, a value indicating the accessory condition device number is stored in the E register.
Then, the main CPU 55 stores the value of the E register in the storage area "_NB_CND_BNS" of the RWM53. As a result, the accessory condition device number is saved.

In step S1075, the main CPU 55 stores the winning and replay condition device numbers.
Here, when “Yes” is set in step S1071 and the process proceeds to step S1075, a value indicating a “winning number” is stored in the A register. When "Yes" is set in step S1071 (when the winning number is smaller than the conversion start number), "winning number" = "winning and replay condition device number" as shown in FIG. 74 (a). It is stipulated in. Therefore, when the result becomes “Yes” in step S1071 and the process proceeds to step S1075, the value of the A register indicates the “winning and replay condition device number”.

Further, in step S1072, a value indicating "winning and replay condition device number" is stored in the A register. Therefore, even when proceeding to step S1075 through step S1072, the value of the A register indicates the “winning and replay condition device number”.
As described above, at the time of proceeding to step S1075, a value indicating the winning and replay condition device number is stored in the A register.
Then, the main CPU 55 stores the value of the A register in the storage area "_NB_CND_NOR" of the RWM53. As a result, the winning and replay condition device numbers are saved.

In this way, the winning and replay condition device numbers are set when the step S1071 becomes "Yes" and the process proceeds to step S1075, and when the step S1071 becomes "No" and the process proceeds to step S1072 through step S1072. The process of storing in "_NB_CND_NOR" can be shared, and the amount of ROM 54 used by the program can be reduced.

In step S1076, the main CPU 55 determines whether or not the winning number is smaller than the advantageous section conversion start number.
Specifically, at the time of proceeding to step S1076, a value indicating a winning number is stored in the C register.
Further, in step S1076, the main CPU 55 first stores the value of the C register (winning number) in the A register, and then subtracts "@NB_TRNS_AT" from the value of the A register. As shown in FIG. 76 (a), “@NB_TRNS_AT” indicates an advantageous section conversion start number, and the value thereof is “@ AT1_BBA”. Further, as shown in FIG. 75A, “@ AT1_BBA” indicates a single winning of 1BBA and a winning of the advantageous section 1, and the value thereof is “38”. Therefore, "@NB_TRNS_AT" = "38".

Then, the main CPU 55 subtracts "38" from the value of the A register, and when a carry occurs due to the subtraction, determines that the winning number is smaller than the advantageous section conversion start number (Yes), and skips steps S1077 to S1079. Then, the process according to this flowchart is completed.
On the other hand, when the carry does not occur due to the subtraction, the main CPU 55 determines that the winning number is equal to or higher than the advantageous section conversion start number (No), and proceeds to the next step S1077.

In step S1077, the main CPU 55 determines whether or not the advantageous section number is “0”.
The specific processing content in step S1077 is the same as in step S1044 of FIG. 89.
Then, when it is determined in step S1077 that the advantageous section number is "0" (Yes), the process proceeds to the next step S1078.
On the other hand, when it is determined in step S1077 that the advantageous section number is other than "0" (No), steps S1078 and S1079 are skipped, and the process according to this flowchart is terminated.

In step S1078, the main CPU 55 determines whether or not the internal middle flag is on.
Specifically, in step S1078, the main CPU 55 determines whether or not the value of the storage area "_FL_PRD_LOT" of the RWM53 is "FF (H)", thereby determining whether or not the internal internal flag is on. To judge.
Here, when the value of "_FL_PRD_LOT" is "FF (H)" (Yes), the main CPU 55 determines that the internal flag is on, skips step S1079, and performs the process according to this flowchart. finish.
On the other hand, when the value of "_FL_PRD_LOT" is "0" (No), the main CPU 55 determines that the internal flag is off, and proceeds to the next step S1079.

In step S1079, the main CPU 55 stores the advantageous section number.
Specifically, at the time of proceeding to step S1079, a value indicating the address of the advantageous section number is stored in the HL register.
Then, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the storage area “_NB_CND_AT” of the RWM 53. As a result, the advantageous section number is saved. Then, the process according to this flowchart is completed.

As described above, in the condition device number set 2, it is determined whether or not the value of "_NB_CND_BNS" is "0" (step S1073), and when it is determined as "0" (Yes), the accessory condition device number. Is stored in "_NB_CND_BNS" (step S1074), and then the advantageous section number is stored in "_NB_CND_AT" (step S1079).
Therefore, in the condition device number set 2, even if it is determined whether or not the value of "_NB_CND_BNS" is "0" in the step before storing the advantageous section number in "_NB_CND_AT", the accessory condition device is used in this game. It is not possible to determine whether the player has won the game or has won the character condition device before the previous game.

Therefore, in the condition device number set 2, in step S1078 before storing the advantageous section number in "_NB_CND_AT", whether or not the internal medium flag is on (whether or not the value of "_FL_PRD_LOT" is "FF (H)"). By determining, it is determined whether the character condition device was won in this game or whether the character condition device was won before the previous game.
Then, when the internal middle flag is off (the value of "_FL_PRD_LOT" is "0"), it is determined that the character condition device has been won in this game, and the advantageous section number is stored in "_NB_CND_AT" (step S1079). ).

Here, in the condition device number set 2, in step S1072, the value indicating the “accessory condition device number” is stored in the E register, and the value indicating the “winning and replay condition device number” is stored in the A register. After that, in step S1074, the value of the E register (accessory condition device number) is stored in "_NB_CND_BNS", and in step S1075, the value of the A register (winning and replay condition device number) is stored in "_NB_CND_NOR".
Therefore, even if the value of the E register is destroyed after step S1074, the accessory condition device number is not lost, and even if the value of the A register is destroyed after step S1075, the prize is won and the replay is performed. The condition device number is not lost.

Further, in step S1076, the winning number is smaller than the advantageous section conversion start number by storing the value of the C register in the A register and then subtracting "@NB_TRNS_AT" (= "43") from the value of the A register. Judge whether or not.
Therefore, even if the value of the C register is destroyed after step S1076, there is no problem in the process of storing the advantageous section number.

From the above, in the condition device number set 2, the E register can be used for other processing after step S1074. Similarly, after step S1075, the A register can be used for other processing, and after step S1076, the C register can be used for other processing.
As another process, for example, an additional lottery for an AT (instructed game section) in an advantageous section can be mentioned.

Further, in the condition device number set 2, in step S1078, by determining whether or not the internal middle flag is on (whether or not the value of "_FL_PRD_LOT" is "FF (H)"), the character condition in this game is determined. It was determined whether the device was won or the character condition device was won before the previous game.
However, it is not limited to this. In the present embodiment, the inside shifts to RT4. Therefore, for example, in step S1078, by determining whether or not the RT4 corresponds to the inside, whether or not the character condition device was won in this game, or the character condition device was won before the previous game. You may judge whether it is.

<17th Embodiment>
Subsequently, the 17th embodiment of the present invention will be described.
FIG. 93 (a) is a diagram showing the winning number definition (3) in the present embodiment.
Here, the winning number definition (3) in FIG. 93A shows the winning number definitions for the winning numbers "31" to "42".
The winning number definitions for the winning numbers "1" to "30" are the same as the winning number definition (1) of the 16th embodiment shown in FIG. 74 (a).

As shown in FIG. 93 (b), in "@BBA EQU 38; 1BBA single winning + transition lottery", "@BBA" indicates "1BBA single winning" and "execution of transition lottery", "@BBA It means that the winning number corresponding to "" is "38".
Then, when the winning number is determined to be "38", the "1BBA condition device" is independently won, and whether or not to shift from the normal section to the advantageous section, and which type of advantageous section is shifted from the normal section. A transition lottery to decide whether to let it be done becomes feasible.
The types of advantageous sections include an advantageous section 1 and an advantageous section 2. Then, if the player wins the advantageous section 1 (decides to move), the game state shifts to the game state of Gase, which does not have the right to move to the ART, and if the player wins the advantageous section 2, the game state allows the player to move to the ART (ART). It shifts to ART through the precursor).

As shown in FIG. 93 (c), in "@BBA_WD EQU 39; 1BBA + small winning combination D duplicate winning + transition lottery", "@BBA_WD" is "1BBA and small winning combination D duplicate winning" and "execution of transition lottery". Means that the winning number corresponding to "@BBA_WD" is "39".
Then, when the winning number is determined to be "39", the "1BBA condition device" and the "small winning combination D condition device" are duplicated, and whether or not to shift from the normal section to the advantageous section is determined, and from the normal section. A transition lottery that determines which type of advantageous section to shift to can be executed.

As shown in FIGS. 74 (a) and 93 (a), in the present embodiment, the winning numbers are defined from "1" to "42". Then, the winning number determining means determines any one of the numerical values of "0" to "42" as the winning number.
Further, as shown in FIG. 93 (a), in the present embodiment, the winning numbers "31" to "33" are the single winning of the character condition device, or the character condition device and the winning and replay condition device. The winning numbers "34" to "37" correspond to the addition of the advantageous section, and the winning numbers "38" to "42" correspond to the execution of the transition lottery. ..

The winning numbers "38" to "42" may also be added to the advantageous section. Then, when the winning numbers are determined to be "38" to "42", the transition lottery may be made feasible and the addition of the advantageous section may be made feasible.
Further, "when the winning number is determined to be" 38 "to" 42 "" means when the winning number is determined to be any of "38" to "42".
Further, the number of games to be added to the number of games in the advantageous section and the content of the change in the game state (performance of the advantageous section) in the advantageous section can be appropriately set according to the type of the determined winning number.

FIG. 93D is a diagram showing a winning number conversion data definition in the present embodiment.
As shown in FIG. 93 (d), in "@NB_TRNS EQU @ BBA_WIN_E2; conversion start number", "@NB_TRNS" indicates "conversion start number", and the value corresponding to "@NB_TRNS" is "@ BBA_WIN_E2". Means that As shown in FIG. 93 (a), “@ BBA_WIN_E2” = “31”. Therefore, "@NB_TRNS" = "@BBA_WIN_E2" = "31".
Then, when the winning number determined by the winning number determining means is equal to or higher than the "conversion start number", the winning number conversion table is used to obtain the winning number, the winning number, and the winning and replaying condition device number. Is acquired (remembered).

Further, as shown in FIG. 93 (d), in the "@NB_TRNS_UP EQU @RE; additional conversion start number", "@NB_TRNS_UP" indicates the "additional conversion start number", and the value corresponding to "@NB_TRNS_UP" is It means that it is "@RE". As shown in FIG. 93 (a), “@RE” = “34”. Therefore, "@NB_TRNS_UP" = "@RE" = "34".
Then, when the winning number determined by the winning number determining means is equal to or higher than the "additional conversion start number", there is a case where an advantageous section is added.

Further, as shown in FIG. 93 (d), "@NB_TRNS_AT EQU @BBA; advantageous section conversion start number" corresponds to "@NB_TRNS_AT" indicating "advantageous section conversion start number" and "@NB_TRNS_AT". It means that the value is "@BBA". As shown in FIG. 93 (a), “@BBA” = “38”. Therefore, "@NB_TRNS_AT" = "@BBA" = "38".
Then, when the winning number determined by the winning number determining means is equal to or higher than the "advantageous section conversion start number", there is a case where a transition lottery for determining whether or not to shift to the advantageous section is executed.

FIG. 94 (a) is a diagram showing a winning number conversion table in this embodiment.
As shown in FIG. 94 (a), when the winning numbers determined by the winning number determining means are "31" to "42", the winning number conversion table corresponds to the determined winning numbers. It is used when determining the "feature condition device number" and the "winning and replay condition device number".

As shown in FIG. 94 (b), "DEFB @ NB_1BBA, @ NB_WIN_E2; winning number 31" stores "@ NB_1BBA" in the address ### 0 (for example, address 1600 (H)), and the address ### It means that "@ NB_WIN_E2" is stored in 1 (for example, address 1601 (H)). As shown in FIG. 93 (d), “@ NB_1BBA” = “1”, and as shown in FIG. 74 (a), “@ NB_WIN_E2” = “28”. Therefore, "1" is stored in the address ### 0, and "28" is stored in the address ### 1.

That is,
Address ## # 0 (1600 (H) address) 1: Character condition device number Address ## # 1 (1601 (H) address) 28: Winning and replay condition device number.
Then, each data stored in the address ## 0 and the address ## 1 is used when the winning number is determined to be "31".

As shown in FIG. 94 (c), "DEFB @ NB_1BBB, 0; winning number 32" stores "@ NB_1BBB" in the address ### 2 (for example, address 1602 (H)), and the address ### 3 It means that "0" is stored in (for example, address 1603 (H)). As shown in FIG. 93 (d), "@ NB_1BBB" = "2". Therefore, "2" is stored in the address ### 2.

That is,
Address ### 2 (address 1602 (H)) 2: Accessory condition device number Address ### 3 (address 1603 (H)) 0: Winning and replay condition device number.
Then, each data stored in the address ## # 2 and the address ## # 3 is used when the winning number is determined to be "32".
The winning number lottery data definition is the same as the winning number lottery data definition of the 16th embodiment shown in FIG. 78 (a).

94 (d), 95, and 96 are diagrams showing a lottery table common to all RTs in this embodiment.
FIG. 94 (d) is a diagram showing a lottery table (5) common to all RTs. Further, FIG. 95 is a diagram showing a lottery table (6) common to all RTs, and is a diagram following FIG. 94 (d). Furthermore, FIG. 96 is a diagram showing a lottery table (7) common to all RTs, and is a diagram following FIG. 95.
The non-RT lottery table, RT1 o'clock lottery table, RT2 o'clock lottery table, RT3 o'clock lottery table, RT4 o'clock lottery table, 1BBA time lottery table, and 1BBB time lottery table are the same as those in the 16th embodiment.

Further, at the time of non-RT, RT1, RT2, RT3, or RT4, the lottery determination is first performed using the lottery table common to all RTs, and at this time, when the winning number is determined to be "00 (H)", Next, a lottery judgment is made using the lottery table according to RT, and when the winning number is determined to be a value other than "00 (H)", the internal lottery is completed without using the lottery table according to RT. Is the same as in the 16th embodiment.
Furthermore, at the time of 1BBA, the lottery determination is performed using the 1BBA time lottery table, and at the time of 1BBB, the lottery determination is performed using the 1BBB time lottery table, as in the 16th embodiment.

FIG. 97A is a diagram showing a two-stage lottery address table. Further, FIG. 97 (b) is a diagram showing the two-stage lottery table 1, FIG. 97 (c) is a diagram showing the two-stage lottery table 2, and FIG. 97 (d) is a diagram showing the two-stage lottery table 3. 97 (e) is a diagram showing a two-stage lottery table 4, and FIG. 97 (f) is a diagram showing a two-stage lottery table 5.
Here, the two-stage lottery address table and the two-stage lottery tables 1 to 5 are used in the two-stage lottery of FIG. 100 and the lottery without setting difference of FIG. 101, which will be described later, and are stored in the ROM 54 of the main control board 50. ing. Further, in the two-stage lottery and the lottery with no setting difference, it is decided whether or not to shift from the normal section to the advantageous section. That is, the transition lottery for determining whether or not to shift from the normal section to the advantageous section corresponds to a two-stage lottery and a lottery with no setting difference.

Further, the two-stage lottery address table defines which of the two-stage lottery tables 1 to 5 is used.
As shown in FIG. 97 (a), when the winning number is determined to be "38", "TBL_2NDAT_LOT1" (two-stage lottery table 1) is used.
Similarly, when the winning number is determined to be "39", "TBL_2NDAT_LOT2" (two-stage lottery table 2) is used, and when the winning number is determined to be "40", "TBL_2NDAT_LOT3" (two-stage). The lottery table 3) is used.
When the winning number is determined to be "41", "TBL_2NDAT_LOT4" (two-stage lottery table 4) is used, and when the winning number is determined to be "42", "TBL_2NDAT_LOT5" (two-stage lottery) is used. Table 5) is used.

Further, the two-stage lottery table 1 is used when the winning number is determined to be "38", and defines the winning data and the probability data.
The "DEFB 2; winning data" on the first line indicates that the winning data is "2".
The second line "DEFB 85; probability data (winning data 2)" indicates that "85" is defined as the probability data, and when winning using this probability data, the winning data is "2". It shows that it is decided to.

The third line "DEFB 85; probability data (winning data 1)" indicates that "85" is defined as the probability data, and when winning using this probability data, the winning data is "1". It shows that it is decided to.
The fourth line "; // DEFB 86; probability data (winning data 0)" is a comment indicating that the probability that the winning data is determined to be "0" is "86/256", and the data is stored in the ROM 54. Not remembered as.
The two-stage lottery tables 2 to 5 are the same as those of the two-stage lottery table 1.

FIG. 98 is a flowchart showing the flow of the lottery process for the condition device number and the like in the 17th embodiment.
Steps S1001 to S1004 and step S1006 are the same as those in the 16th embodiment.
Further, in the present embodiment, when the internal lottery 1 is executed in step S1004, the process proceeds to step S1101.
Further, when the process proceeds to step S1101, the condition device number set 3 (FIG. 99) is executed, and the process proceeds to step S1006.
Then, in step S1006, the rotation of all the reels 31 is started, and the rotating reels 31 can be stopped by the operation of the stop switch 42 by the player. Then, when the rotation of all the reels 31 is stopped, the process according to this flowchart ends.

FIG. 99 is a flowchart showing a processing flow of the condition device number set 3.
Further, the conditional device number set 3 is a process of determining (acquiring, storing, determining) the conditional device number and the advantageous section number from the winning number.
Proceeding to the condition device number set 3 in step S1101, first, in step S1111, the main CPU 55 determines whether or not the winning number is smaller than the conversion start number.
The specific processing content in step S1111 is the same as in step S1041 of FIG. 89.

Then, when it is determined in step S1111 that the winning number is smaller than the conversion start number (Yes), steps S1112 to S1118 are skipped and the process proceeds to step S1119.
On the other hand, when it is determined in step S1111 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1112.
In step S1111, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

In step S1112, the main CPU 55 acquires the condition device number corresponding to the winning number from the winning number conversion table of FIG. 94 (a).
Specifically, the main CPU 55 first stores the calculation result of "TBL_CNDNO_DAT"-"@NB_TRNS" x 2 in the HL register.
For example, "TBL_CNDNO_DAT" = "1600 (H)" address.
Further, as shown in FIGS. 93 (a) and 93 (d), “@NB_TRNS” = “@ BBA_WIN_E2” = “31”.
In this case, the value of the HL register is
"1600 (H)"-"31 (D)" x 2
= "1600 (H)"-"3E (H)"
= "15C2 (H)"
Will be.

Next, the main CPU 55 repeats twice by adding the value of the A register to the value of the HL register to obtain a new HL register value.
For example, assume that the value of the A register (indicating the winning number) is "32".
Further, "32 (D)" = "20 (H)".
In this case, the value of the HL register is
"15C2 (H)" + "20 (H)" = "15E2 (H)" (1st time)
"15E2 (H)" + "20 (H)" = "1602 (H)" (second time)
Will be.
As a result, the "address of the conditional device number corresponding to the winning number" is set in the HL register.

In other words, the address stored in the HL register (“15C2 (H)” in this embodiment) is used as the reference address, and the winning number stored in the A register is used as the offset value (in this embodiment, it is stored in the A register). By (the offset value is a value obtained by doubling the winning number obtained), it is possible to calculate (designate) the address in which the condition device number corresponding to the determined winning number is stored.
Here, the value of the A register is added twice (the value obtained by doubling the winning number is used as the offset value) of two data (data indicating the accessory condition device number) for one winning number. This is because the winning number and the replay condition device number (two of the data indicating the device number) are stored in the winning number conversion table.

As in the 16th embodiment, three data (data indicating the accessory condition device number, data indicating the winning and replay condition device number, and data indicating the advantageous section number) are provided for one winning number. When stored in the winning number conversion table, the condition device number corresponding to the winning number is stored by adding the value of the A register three times (the value obtained by multiplying the winning number by 3 is used as the offset value). It is possible to calculate (specify) the address.

Next, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the E register.
For example, when the value of the HL register is "1602 (H)", the data corresponding to this address is "@ NB_1BBB" (= "2"). In addition, this data indicates the "accessory condition device number" (FIGS. 94 (a) and 94 (c)).
In this case, the main CPU 55 stores "2" in the E register. As a result, "2" indicating the "accessory condition device number" is stored in the E register. After that, the value of the E register is maintained until the end of this flowchart (condition device number set 3).
After that, the main CPU 55 adds "1" to the value of the HL register to obtain a new HL register value. As a result, the value of the HL register becomes "1603 (H)".

In step S1042 of FIG. 89, a value indicating the “accessory condition device number” is stored in the C register.
On the other hand, in step S1112, a value indicating the "accessory condition device number" is stored in the E register.
In the condition device number set 3, the value of the C register (winning number) is used in steps S1111 and S1115, so that the value of the C register (winning number) is not destroyed in step S1112.

Next, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the D register.
For example, when the value of the HL register is "1603 (H)", the data corresponding to this address is "0". In addition, this data shows "winning and replay condition device numbers" (FIGS. 94 (a) and 94 (c)).
In this case, the main CPU 55 stores "0" in the D register. As a result, "0" indicating "winning and replay condition device number" is stored in the D register. After that, the value of the D register is maintained until the end of this flowchart (condition device number set 3).

In step S1042 of FIG. 89, a value indicating the “winning and replay condition device number” is stored in the A register.
On the other hand, in step S1112, a value indicating "winning and replay condition device number" is stored in the D register.
In the condition device number set 3, the A register is used in step S1115 described later. Therefore, before saving the winning and replay condition device number in step S1119 described later, the value indicating the winning and replay condition device number is not lost.

In step S1113, the main CPU 55 determines whether or not "0" is stored in the "_NB_CND_BNS" (storage area of the accessory condition device number) of the RWM 53.
In other words, it is determined whether or not the game is a game inside the bonus this time.
If "0" is stored in "_NB_CND_BNS" of RWM53, it is determined that the game is a game that is not inside the bonus, and if a value other than "0" is stored, this game is played. Is determined to be a game inside the bonus.
Of course, other information such as the RT number may be referred to in order to determine whether or not the game is a game within the bonus this time.

The specific content of the process in step S1113 is the same as that in step S1043 of FIG. 89.
Then, when it is determined in step S1113 that the accessory condition device number is "0" (Yes), the process proceeds to the next step S1114.
On the other hand, when it is determined in step S1113 that the accessory condition device number is other than "0" (No), steps S1114 to S1117 are skipped and the process proceeds to step S1118.

In step S1114, the main CPU 55 determines whether or not the advantageous section number is “0”.
The specific processing content in step S1114 is the same as in step S1044 of FIG. 89.
Then, when it is determined in step S1114 that the advantageous section number is "0" (Yes), the process proceeds to the next step S1115.
On the other hand, when it is determined in step S1114 that the advantageous section number is other than "0" (No), steps S1115 and S1116 are skipped and the process proceeds to step S1117.

In step S1115, the main CPU 55 determines whether or not the winning number is smaller than the advantageous section conversion start number.
Specifically, at the time of proceeding to step S1115, a value indicating a winning number is stored in the C register.
Further, in step S1115, the main CPU 55 first stores the value of the C register (winning number) in the A register, and then subtracts "@NB_TRNS_AT" from the value of the A register. As shown in FIGS. 93 (a) and 93 (d), “@NB_TRNS_AT” = “@BBA” = “38”.

Then, the main CPU 55 subtracts "38" from the value of the A register, and when a carry occurs due to the subtraction, determines that the winning number is smaller than the advantageous section conversion start number (Yes), and skips step S1116. , Step S1117.
On the other hand, when the carry does not occur due to the subtraction, the main CPU 55 determines that the winning number is equal to or higher than the advantageous section conversion start number (No), and proceeds to the next step S1116.
In step S1115, "38" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

Proceeding to step S1116, the main CPU 55 executes a two-stage lottery (FIG. 100). Then, when the two-stage lottery is completed, the process proceeds to the next step S1117.
In step S1117, the main CPU 55 stores the accessory condition device number.
Specifically, at the time of proceeding to step S1117, a value indicating the accessory condition device number is stored in the E register.
Then, the main CPU 55 stores the value of the E register in the storage area "_NB_CND_BNS" of the RWM53. As a result, the accessory condition device number is saved.

In the next step S1118, the main CPU 55 moves the winning and replay condition device numbers.
Here, in step S1112, a value indicating a "winning and replay condition device number" is stored in the D register. Therefore, when proceeding to step S1118 through step S1112, the value of the D register indicates "winning and replay condition device number".
As described above, at the time of proceeding to step S1118, the value indicating the winning and replay condition device number is stored in the D register.
Then, in step S1118, the main CPU 55 stores the value of the D register in the A register.

In the next step S1119, the main CPU 55 stores the winning and replay condition device numbers.
Here, when “Yes” is set in step S1111 and the process proceeds to step S1119, a value indicating a “winning number” is stored in the A register. When "Yes" is set in step S1111 (when the winning number is smaller than the conversion start number), "winning number" = "winning and replay condition device number" as shown in FIG. 74 (a). It is stipulated in. Therefore, when the result becomes “Yes” in step S1111 and the process proceeds to step S1119, the value of the A register indicates the “winning and replay condition device number”.

Also, when proceeding from step S1118 to step S1119, the value of the A register indicates the "winning and replay condition device number".
Then, in step S1119, the main CPU 55 stores the value of the A register in the storage area “_NB_CND_NOR” of the RWM53. As a result, the winning and replay condition device numbers are saved.
Then, the process according to this flowchart is completed.

As described above, in the condition device number set 3, in step S1118, the value of the D register (indicating the winning and replay condition device numbers) is stored in the A register.
In this way, the winning and replay conditions are obtained when the step S1111 becomes "Yes" and the process proceeds to step S1119, and when the step S1111 becomes "No" and the process proceeds from step S1118 to step S1119. The process of storing the device number in "_NB_CND_NOR" can be shared, and the amount of ROM 54 used by the program can be reduced.

FIG. 100 is a flowchart showing the flow of processing of the two-stage lottery.
Further, the two-stage lottery is a process of acquiring an advantageous section number from the winning number.
Proceeding to the two-stage lottery in step S1116, first, in step S1121, the main CPU 55 sets the two-stage lottery table.
Specifically, the main CPU 55 first stores the calculation result of "TBL_2NDDAT_ADR"-"@NB_TRNS_AT" in the HL register.

Here, "TBL_2NDDAT_ADR" indicates the start address of the two-stage lottery address table (FIG. 97 (a)).
For example, it is assumed that "TBL_2NDDAT_ADR" = "1700 (H)" address.
Further, as shown in FIGS. 93 (a) and 93 (d), “@NB_TRNS_AT” = “@BBA” = “38”.
In this case, the value of the HL register is
"1700 (H)"-"38 (D)"
= "1700 (H)"-"26 (H)"
= "16DA (H)"
Will be.

Next, the main CPU 55 adds the value of the A register (winning number) to the value of the HL register to obtain a new HL register value.
As described above, in step S1115 of FIG. 99, "38" is subtracted from the value (winning number) of the A register to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is updated. Keep without. That is, even after the subtraction, the value of the A register indicates the "winning number". Therefore, even at the time of proceeding to step S1121, the value of the A register indicates the “winning number”.

For example, assume that the value (winning number) of the A register is "39".
Further, "39 (D)" = "27 (H)".
In this case, the value of the HL register is
"16DA (H)" + "27 (H)" = "1701 (H)"
Will be.

In other words, the address indicated by the HL register (“16DA (H)” in this embodiment) is used as the reference address, and the winning number stored in the A register is used as the offset value. It is possible to calculate (specify) the address of "address designation data".
Further, the "address designation data" is data stored in the two-step lottery address table, and is data for calculating (designating) the start address of the two-step lottery tables 1 to 5.

“DEFB TBL_2NDAT_LOT1 − $; winning number 38” on the two-stage lottery address table of FIG. 97 (a) is address designation data for calculating (designating) the start address of the two-stage lottery table 1.
Similarly, "DEFB TBL_2NDAT_LOT2- $; winning number 39" is address designation data for calculating (designating) the start address of the two-stage lottery table 2, and "DEFB TBL_2NDAT_LOT3- $; winning number 40" is 2 This is address designation data for calculating (designating) the start address of the stage lottery table 3.
Further, "DEFB TBL_2NDAT_LOT4- $; winning number 41" is address designation data for calculating (designating) the start address of the two-stage lottery table 4, and "DEFB TBL_2NDAT_LOT5-$; winning number 42" is two-stage. This is address designation data for calculating (designating) the start address of the lottery table 5.

Next, the main CPU 55 stores the data (address designation data) corresponding to the address indicated by the HL register in the A register.
For example, when the value of the HL register is "1701 (H)", the data corresponding to this address (address designation data) is "DEFB TBL_2NDAT_LOT2- $; winning number 39" as shown in FIG. 97 (a). Is.

Here, "TBL_2NDAT_LOT2" indicates the start address of the two-stage lottery table 2 (FIG. 97 (c)).
For example, it is assumed that "TBL_2NDAT_LOT2" = "1708 (H)" address.
In addition, "$" indicates the current address. As mentioned above, the current address is "1701 (H)".
In this case, the value of the A register is
"TBL_2NDAT_LOT2"-"$"
= "1708 (H)"-"1701 (H)"
= "7 (H)"
Will be.

Next, the main CPU 55 adds the value of the A register to the value of the HL register to obtain a new HL register value.
When the value of the HL register is "1701 (H)" and the value of the A register is "7 (H)", the value of the new HL register is
"1701 (H)" + "7 (H)"
= "1708 (H)"
Will be.

Then, the value of the HL register "1708 (H)" indicates the start address of the two-stage lottery table used in the lottery without setting difference in the next step S1122.
The address "1708 (H)" indicates the start address of the two-stage lottery table 2 in FIG. 97 (c).
In this way, in step S1121, a two-stage lottery table is set. Then, the process proceeds to the next step S1122.

Proceeding to step S1122, the main CPU 55 executes a lottery without setting difference (FIG. 101). Then, when the lottery without setting difference is completed, the process proceeds to the next step S1123.
In step S1123, the main CPU 55 stores the winning value in the lottery without setting difference as an advantageous section number.
Specifically, at the time of proceeding to step S1123, the winning value in the lottery without setting difference is stored in the A register.
Then, in step S1123, the main CPU 55 stores the value of the A register as an advantageous section number in the storage area “_NB_CND_AT” of the RWM 53. As a result, the advantageous section number is saved.
Then, the process according to this flowchart is completed.

Here, the following points can be mentioned as merits of calculating (designating) the start address of the two-stage lottery table using the two-stage lottery address table.
In the present embodiment, as shown in FIGS. 97 (b) to 97 (f), 3 bytes of data are stored (stored) in each of the two-stage lottery tables 1 to 5.
Therefore, the start address of the two-stage lottery table 1 (“1705 (H)”) and the start address of the two-stage lottery table 2 (“1708 (H)”) are separated by 3 bytes.

Similarly, the start address of the two-stage lottery table 2 (“1708 (H)”) and the start address of the two-stage lottery table 3 (“170B (H)”) are separated by 3 bytes.
Further, the start address of the two-stage lottery table 3 (“170B (H)”) and the start address of the two-stage lottery table 4 (“170E (H)”) are separated by 3 bytes.
Further, the start address of the two-stage lottery table 4 (“170E (H)”) and the start address of the two-stage lottery table 5 (“1711 (H)”) are separated by 3 bytes.

In such a case, for example, "72 (H)" which is a value obtained by triple "@NB_TRNS_AT"("26(H)") from the start address ("1705 (H)") of the two-stage lottery table 1. ) ”Is subtracted to calculate“ 1693 (H) ”and store it in the HL register as a reference address. The reason why "@NB_TRNS_AT" is tripled is that the data stored in each two-stage lottery table is 3 bytes. When N bytes of data are stored in each of the two-stage lottery tables, "@NB_TRNS_AT" is multiplied by N.
Then, the address of the two-stage lottery table corresponding to the winning number is calculated (designated) by adding the value obtained by triple the data of the winning number stored in the A register to the reference address. You can also. When N-byte data is stored in each of the two-stage lottery tables, the value obtained by multiplying the winning number data by N is added.

That is, the calculation result of "1705 (H)"-"@NB_TRNS_AT" x 3 is stored in the HL register as a reference address.
In this case, the value of the HL register is
"1705 (H)"-"@NB_TRNS_AT" x 3
= "1705 (H)"-"26 (H)" x 3
= "1693 (H)"
Will be.

Next, the main CPU 55 repeats adding the value of the A register to the value of the HL register to obtain a new HL register value three times.
For example, assume that the value of the A register (indicating the winning number) is "39".
Further, "39 (D)" = "27 (H)".
In this case, the value of the HL register is
"1693 (H)" + "27 (H)" = "16BA (H)" (1st time)
"16BA (H)" + "27 (H)" = "16E1 (H)" (second time)
"16E1 (H)" + "27 (H)" = "1708 (H)" (3rd time)
Will be.
As a result, the "address of the conditional device number and the advantageous section number corresponding to the winning number" is set in the HL register.

However, the contents of the two-stage lottery tables 1 to 5 may be changed at the development stage of the slot machine 10.
For example, in the two-stage lottery table 1, the winning probability of the advantageous section number "1" may be set to 0%, and the winning probability of the advantageous section number "2" may be set to 100%.
In this case, in the two-stage lottery table 1, since there is only one type of advantageous section number to be won, the interval between the head addresses of the two-stage lottery tables 1 to 5 is not 3 bytes each.

Therefore, as shown in FIG. 97A, by providing a two-stage lottery address table for designating the start address of the two-stage lottery table corresponding to the winning number, the two-stage lottery is provided at the development stage of the slot machine 10. Even if the intervals between the start addresses of the tables 1 to 5 are no longer equal, it is possible to specify the start addresses of the two-stage lottery table, so that it is possible to flexibly respond to changes in specifications.

It is also possible to specify the start address of the corresponding two-stage lottery table from the determined winning number without using the two-stage lottery address table.
However, in this case, in step S1121 of FIG. 100, first, it is determined whether or not the winning number is "38", and when it is determined that the winning number is "38", the start address of the two-stage lottery table 1 is determined. When "1705 (H)" is specified and it is determined that the number is not "38", then it is determined whether or not the winning number is "39".

If it is determined that the winning number is "39", "1708 (H)", which is the start address of the two-stage lottery table 2, is specified, and if it is determined that the winning number is not "39", then , It is determined whether or not the winning number is "40".
Such processing is repeated until the start address of the two-stage lottery table corresponding to the winning number is specified.

Therefore, the process until the start address of the two-stage lottery table is specified becomes long.
A program for designating the start address of the two-stage lottery table is also required.
On the other hand, if the start address of the two-stage lottery table is specified using the two-stage lottery address table, the process until the start address of the two-stage lottery table is specified can be shortened, and the start of the two-stage lottery table can be shortened. Since it is not necessary to define a program for designating the address, the amount of ROM 54 used by the program can be reduced.

FIG. 101 is a flowchart showing a flow of processing of a lottery without a setting difference.
Further, the lottery without setting difference is a process of determining an advantageous section number based on the two-stage lottery table set in step S1121 of FIG. 100.
Proceeding to the lottery without setting difference in step S1122, first, in step S1131, the main CPU 55 acquires a random number value.
In the present embodiment, a counter that counts in the range of "0" to "255" as one cycle is provided. Then, the main CPU 55 acquires a 1-byte random value from this counter for lottery without setting difference and stores it in the A register.
The lower 1 byte of the 2-byte counter may be acquired as a random number value.

Proceeding to the next step S1132, the main CPU 55 acquires winning data from the two-stage lottery table.
Specifically, the main CPU 55 stores the data in which the bit 7 of the data corresponding to the address indicated by the HL register is set to “0” in the B register. At this time, the data itself corresponding to the address indicated by the HL register is the data before the bit 7 is set to “0”.
Here, in the two-stage lottery tables 1 to 5 of FIGS. 97 (b) to 97 (f), "2 (D)" is defined as the winning data.

However, when the winning data is determined by "2", "10000010 (B)" can be defined as the winning data.
Similarly, when the winning data is determined by "1", "10000001 (B)" can be defined as the winning data.
In this case, of the 8-bit data, bits 0 to 6 indicate winning data, and bit 7 indicates "winning confirmation data".
Further, the "winning confirmation data" is data indicating that the winning data is confirmed as the winning value.

Proceeding to the next step S1133, the main CPU 55 determines whether or not the winning confirmation data is included.
Specifically, the main CPU 55 determines whether or not the bit 7 of the data corresponding to the address indicated by the HL register is "1".
Then, when the bit 7 is "1", it is determined that the winning confirmation data is included (Yes), steps S1134 to S1138 are skipped, and the process proceeds to step S1139. As a result, of the 8-bit data corresponding to the address indicated by the HL register, bits 0 to bit 6 (winning data) are determined as winning values.
On the other hand, when the bit 7 is "0", it is determined that the winning confirmation data is not included (No), and the process proceeds to the next step S1134.

In step S1134, the main CPU 55 acquires probability data from the two-stage lottery table.
Specifically, the main CPU 55 adds "1" to the value of the HL register. As a result, the value of the HL register indicates the address of the probability data.
Proceeding to the next step S1135, the main CPU 55 determines whether or not the result is correct.
Specifically, the main CPU 55 subtracts the data corresponding to the address indicated by the HL register from the value of the A register, and stores the subtraction result in the HL register.

Proceeding to the next step S1136, the main CPU 55 determines whether or not the player has won.
Specifically, the main CPU 55 determines whether or not carry has occurred due to the subtraction in step S1135.
Here, when a carry occurs due to the subtraction, it is determined that the player has won (Yes), steps S1137 and S1138 are skipped, and the process proceeds to step S1139.
On the other hand, when the carry does not occur due to the subtraction, it is determined that the player has not won (No), and the process proceeds to the next step S1137.

In step S1137, the main CPU 55 subtracts “1” from the winning data.
Specifically, the main CPU 55 subtracts "1" from the value of the B register to obtain a new value of the B register.
Proceeding to the next step S1138, the main CPU 55 determines whether or not the winning data is “0”.
Specifically, the main CPU 55 determines whether or not the value of the B register is "0".

Here, when it is determined that the value of the B register is not "0" (No), the process returns to step S1134.
On the other hand, when it is determined that the value of the B register is "0" (Yes), the process proceeds to the next step S1139.
In step S1139, the main CPU 55 acquires the winning data as the winning value.
Specifically, the main CPU 55 stores the value of the B register in the A register. In this way, the winning data is stored in the A register as the winning value. Then, the process according to this flowchart is completed.

As described above, in the condition device number set 3, when the winning numbers determined by the internal lottery 1 and the lottery determination are "38" to "42", "No" is displayed in step S1111 of FIG. Therefore, it is possible to execute a two-stage lottery and a lottery with no setting difference (transition lottery).
In this case, when a value other than "0" is stored in "_NB_CND_AT" (when "No" in step S1114 of FIG. 99; when the advantageous section number is stored), steps S1115 and S1116 are performed. Since the process is skipped and the process proceeds to step S1117, the two-stage lottery and the lottery without setting difference are not executed.
As a result, it is possible to appropriately perform the processing related to the transition to the advantageous section within a certain range of the usage amount of RWM55 without requiring complicated processing.

When "No" is set in step S1114 of FIG. 99 (when a value other than "0" is stored in "_NB_CND_AT"), steps S1115 and S1116 are skipped to change from the normal section to the advantageous section. It only does not execute the lottery related to the transition (two-stage lottery and lottery with no setting difference).
Then, even when "No" is set in step S1114 of FIG. 99 (when a value other than "0" is stored in "_NB_CND_AT"), the advantageous section is added (the gaming state in the advantageous section is the player). It is possible to perform a lottery regarding (including changing the performance to be advantageous to the player and adding the number of AT games played in the advantageous section).

When the winning numbers determined by the internal lottery 1 and the lottery determination are "38" to "42" and a value other than "0" is stored in "_NB_CND_AT" (advantageous section number is (When stored), the process proceeds to step S1116 of FIG. 99, and a two-step lottery and a lottery with no setting difference may be executed. In this case, step S1123 of FIG. 100 is skipped. As a result, the value stored in "_NB_CND_AT" is maintained.
Even in this way, it is possible to appropriately perform the process related to the transition to the advantageous section within a certain range of the amount of RWM55 used without requiring a complicated process.

Further, as described above, when the winning numbers determined by the internal lottery 1 and the lottery determination are "38" to "42", the two-stage lottery and the lottery without setting difference can be executed. In this case, when a value other than "0" is stored in "_NB_CND_BNS" (when "No" in step S1113 of FIG. 99; when the accessory condition device number is stored), steps S1114 to Since S1117 is skipped and the process proceeds to step S1118, the two-stage lottery and the lottery without setting difference are not executed.
As a result, it is possible to appropriately perform the processing related to the transition to the advantageous section within a certain range of the usage amount of RWM55 without requiring complicated processing.

When the winning numbers determined by the internal lottery 1 and the lottery determination are "38" to "42", and a value other than "0" is stored in "_NB_CND_BNS" (character condition device). When the number is stored), the process proceeds to step S1116 of FIG. 99, and a two-step lottery and a lottery with no setting difference may be executed. In this case, step S1123 of FIG. 100 is skipped. As a result, the value stored in "_NB_CND_AT" is maintained.
Even in this way, it is possible to appropriately perform the process related to the transition to the advantageous section within a certain range of the amount of RWM55 used without requiring a complicated process.

In addition, when the winning numbers determined by the internal lottery 1 and the lottery judgment are "38" to "40", the accessory condition device is won, and the two-stage lottery and the lottery without setting difference can be executed. Become. In this case, a two-step lottery and a lottery with no setting difference are executed (step S1116), and then the accessory condition device number is stored in "_NB_CND_BNS" (step S1117).

Furthermore, when the winning number determined by the internal lottery 1 and the lottery judgment is "39" or "40", the winning condition device and the winning condition device are duplicated, and there is no difference between the two-stage lottery and the setting. The lottery can be executed. In this case, a two-step lottery and a lottery with no setting difference are executed (step S1116), after that, the accessory condition device number is stored in "_NB_CND_BNS" (step S1117), and the winning condition device number is stored in "_NB_CND_NOR" (step S1117). Step S1118).
As a result, in the game in which the accessory condition device is won, it is possible to execute the process related to the transition to the advantageous section without requiring a complicated process.

<Modified example of the 17th embodiment>
Subsequently, a modified example of the 17th embodiment of the present invention will be described.
In the modified example of the 17th embodiment, the processing of the condition device number set is different from that of the 17th embodiment.
In the process of the condition device number set 3 of the 17th embodiment, a two-stage lottery is performed to store the advantageous section number in "_NB_CND_AT", and then the accessory condition device number is stored in "_NB_CND_BNS", and the winning and winning are performed. The replay condition device number was stored in "_NB_CND_NOR".

On the other hand, in the condition device number set 4 of the modified example of the 17th embodiment, the accessory condition device number is stored in "_NB_CND_BNS", and the winning and replay condition device numbers are stored in "_NB_CND_NOR". A two-stage lottery is performed and the advantageous section number is stored in "_NB_CND_AT".

FIG. 102 is a flowchart showing a flow of lottery processing such as a condition device number in a modified example of the 17th embodiment.
Steps S1001 to S1004 and step S1006 are the same as those in the 16th embodiment.
Further, step S1052 is the same as the modified example of the 16th embodiment.
Further, in the present embodiment, when the internal lottery 1 is executed in step S1004, the process proceeds to step S1141.
Then, when the process proceeds to step S1141, the condition device number set 4 (FIG. 103) is executed, and the process proceeds to step S1006.

FIG. 103 is a flowchart showing a processing flow of the condition device number set 4.
Further, the conditional device number set 4 is a process of determining the conditional device number and the advantageous section number from the winning number.
Proceeding to the condition device number set 4 in step S1141, first, in step S1151, the main CPU 55 determines whether or not the winning number is smaller than the conversion start number.
The specific processing content in step S1151 is the same as in step S1041 of FIG. 89.

Then, when it is determined in step S1151 that the winning number is smaller than the conversion start number (Yes), steps S1152 to S1154 are skipped and the process proceeds to step S1155.
On the other hand, when it is determined in step S1151 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1152.
In step S1151, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

Proceeding to step S1152, the main CPU 55 acquires the condition device number from the winning number.
Here, in step S1112 of FIG. 99, a value indicating the “winning and replay condition device number” is stored in the D register.
On the other hand, in step S1152, a value indicating "winning and replay condition device number" is stored in the A register.
Other than that, the specific contents of the process in step S1152 are the same as those in step S1112 in FIG. 99.

In the condition device number set 3 of FIG. 99, a value indicating the winning number is stored in the A register in step S1115 before the winning and replay condition device numbers are saved in step S1119. Therefore, in order not to lose the value indicating the winning and replay condition device number, in step S1112, the value indicating the winning and replay condition device number is stored in the D register instead of the A register.

In step S1153, the main CPU 55 determines whether or not the accessory condition device number is “0”.
The specific processing content in step S1153 is the same as in step S1043 of FIG. 89.
Then, when it is determined in step S1153 that the accessory condition device number is "0" (Yes), the process proceeds to the next step S1154.
On the other hand, when it is determined in step S1153 that the accessory condition device number is other than "0" (No), step S1154 is skipped and the process proceeds to step S1155.

In step S1154, the main CPU 55 stores the accessory condition device number, and in the next step S1155, the main CPU 55 stores the winning and replay condition device numbers.
The specific processing content in step S1154 is the same as in step S1074 in FIG. 92, and the specific processing content in step S1155 is the same as in step S1075 in FIG. 92.

It should be noted that the winning and replay condition device number is set to "_NB_CND_NOR" when the step S1151 becomes "Yes" and the process proceeds to step S1155, and when the step S1151 becomes "No" and the process proceeds to step S1152 through step S1152. The processing to be stored in "" can be standardized, and the amount of ROM 54 used by the program can be reduced.

Proceeding to step S1156, the main CPU 55 determines whether or not the winning number is smaller than the advantageous section conversion start number.
The specific content of the process in step S1156 is the same as that in step S1115 of FIG. 99.
Then, in step S1156, when it is determined that the winning number is smaller than the conversion start number (Yes), steps S1157 to S1116 are skipped, and the process according to this flowchart ends.
On the other hand, when it is determined in step S1156 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1157.

Proceeding to step S1157, the main CPU 55 determines whether or not the advantageous section number is “0”.
The specific content of the process in step S1157 is the same as that in step S1044 of FIG. 89.
Then, when it is determined in step S1157 that the advantageous section number is other than "0" (No), steps S1158 and S1116 are skipped, and the process according to this flowchart ends.
On the other hand, when it is determined in step S1157 that the advantageous section number is "0" (Yes), the process proceeds to the next step S1158.

Proceeding to step S1158, the main CPU 55 determines whether or not the internal middle flag is on.
The specific content of the process in step S1158 is the same as that in step S1078 of FIG.
Then, in step S1158, when it is determined that the internal middle flag is on, step S1116 is skipped and the process according to this flowchart ends.
On the other hand, when it is determined in step S1158 that the internal middle flag is off, the process proceeds to the next step S1116.

Proceeding to step S1116, the main CPU 55 executes a two-stage lottery (FIG. 100). Then, when the two-stage lottery is completed, the process according to this flowchart is completed.
The content of the two-stage lottery process in step S1116 is the same as that of the 17th embodiment.

As described above, in the condition device number set 4, when the winning numbers determined by the internal lottery 1 and the lottery determination are "38" to "40", the accessory condition device is won and 2 It becomes possible to execute a stage lottery and a lottery with no setting difference.
In this case, when the value of "_NB_CND_BNS" is "0" (when "Yes" in step S1153), the accessory condition device number is stored in "_NB_CND_BNS" (step S1154), and the value of "_NB_CND_BNS" is ". When it is other than "0" (when "No" in step S1153), the value of "_NB_CND_BNS" is maintained (step S1154 is skipped).

In addition, when the winning number determined by the internal lottery 1 and the lottery judgment is "39" or "40", the winning condition device and the winning condition device are duplicated, and there is no difference between the two-stage lottery and the setting. The lottery can be executed.
In this case, depending on the value of "_NB_CND_BNS", the accessory condition device number is stored in "_NB_CND_BNS", or the value of "_NB_CND_BNS" is maintained, and then the winning condition device number is stored in "_NB_CND_NOR" ( Step S1155).

After that, when the value of "_FL_PRD_LOT" is "0" (when "No" in step S1158), a two-step lottery and a lottery with no setting difference (transition lottery) are executed (step S1116), and the value of "_FL_PRD_LOT" is executed. When is "FF (H)" (when "Yes" in step S1158), the two-step lottery and the lottery without setting difference are not executed (step S1116 is skipped).
As a result, in the game in which the accessory condition device is won, it is possible to execute the process related to the transition to the advantageous section without requiring a complicated process.

Further, in the condition device number set 4, when the value of "_NB_CND_BNS" is "0" (when "Yes" in step S1153), the accessory condition device number is stored in "_NB_CND_BNS" (step S1154). After that, a two-stage lottery and a lottery with no setting difference are executed (step S1116).
Therefore, in the condition device number set 4, even if it is determined whether or not the value of "_NB_CND_BNS" is "0" in the step before executing the two-stage lottery and the lottery without setting difference, the character condition is used in this game. It is not possible to determine whether the device was won or whether the character condition device was won before the previous game.

Therefore, in the condition device number set 4, in step S1158 before executing the two-stage lottery and the lottery without setting difference, the character condition device was won in this game by determining whether or not the internal middle flag is on. Or, it is determined whether the player has won the character condition device before the previous game.
Then, when the internal middle flag is off, it is determined that the character condition device has been won in this game, and a two-stage lottery and a lottery with no setting difference are executed (step S1116).

Further, in the condition device number set 4, in step S1152, the value indicating the “accessory condition device number” is stored in the E register, and the value indicating the “winning and replay condition device number” is stored in the A register. After that, in step S1154, the value of the E register (accessory condition device number) is stored in "_NB_CND_BNS", and in step S1155, the value of the A register (winning and replay condition device number) is stored in "_NB_CND_NOR".
Therefore, even if the value of the E register is destroyed after step S1154, the accessory condition device number is not lost, and even if the value of the A register is destroyed after step S1155, the prize is won and the replay is performed. The condition device number is not lost.

Further, in step S1156, the winning number is smaller than the advantageous section conversion start number by storing the value of the C register in the A register and then subtracting "@NB_TRNS_AT" (= "38") from the value of the A register. Judge whether or not.
From the above, in the condition device number set 4, the E register can be used for other processing after step S1154. Similarly, after step S1155, the A register can be used for other processing, and after step S1156, the C register can be used for other processing.
As another process, for example, an additional lottery for an AT (instructed game section) in an advantageous section can be mentioned.

Further, in the condition device number set 4, in step S1158, by determining whether or not the internal middle flag is on, whether or not the character condition device was won in this game, or the character condition device was won before the previous game. It was judged whether or not it was done, but it is not limited to this, for example, by judging whether it is RT4 corresponding to the inside, whether or not the character condition device was won in this game, or the character condition device before the previous game. You may judge whether you have won.

In the present embodiment, the two-stage lottery and the lottery with no setting difference have been described as the transition lottery from the normal section to the advantageous section. For example, at the start of this game, "_NB_CND_AT" (storage area of the advantageous section number) is set. Even when a value other than "0" is stored, the addition of the advantageous section (the performance is changed so that the gaming state in the advantageous section is advantageous to the player, or the AT game in the advantageous section is played. A lottery regarding (including adding the number of times) may be executed, and the value of "_NB_CND_AT" may be changed according to the result.

For example, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" (storage area of the accessory condition device number) is "0", the winning number is determined to be "37". A control process for storing "2" in "_NB_CND_AT" may be executed based on the above.
Further, in the situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" is "0", the lottery regarding the addition of the advantageous section is based on the fact that the winning number is determined to be "37". May be executed.

Furthermore, the winning numbers "38" to "42" were treated as performing a transition lottery from the normal section to the advantageous section, but even when these winning numbers are determined in the advantageous section, the advantageous section A lottery regarding the addition may be executed.
As described above, when the value of "_NB_CND_BNS" is "1" (so-called internal), for example, even if the winning number is determined to be "37", the lottery regarding the addition of the advantageous section is not executed.

<18th Embodiment>
Subsequently, the eighteenth embodiment of the present invention will be described.
The winning number definitions for the winning numbers "1" to "30" are the same as the winning number definitions (1) of the 16th embodiment shown in FIG. 74 (a).
Further, the winning number definitions for the winning numbers "31" to "42" are the same as the winning number definition (3) of the 17th embodiment shown in FIG. 93 (a).
Furthermore, the winning number conversion data definition is the same as the winning number conversion data definition of the 17th embodiment shown in FIG. 93 (d).
Further, the winning number conversion table is the same as the winning number conversion table of the 17th embodiment shown in FIG. 94 (a).

FIG. 104A is a diagram showing a winning number lottery data definition in the present embodiment.
The winning number identifier, the repetition count identifier, the set value-specific identifier, the 2-byte data identifier, the 1-byte data identifier, and the determination end identifier are the same as those in the 16th embodiment.
The "advantageous section number 1 identifier" is an identifier indicating that the player has won (decided to shift) to the advantageous section 1.

The "advantageous section number 2 identifier" is an identifier indicating that the player has won (decided to shift) to the advantageous section 2.
The advantageous section number 1 identifier and the advantageous section number 2 identifier are collectively referred to as an “advantageous section number identifier”.
The “advantageous section number mask data” is data for masking (setting to “0”) bit data (bits 3 to 7) corresponding to an identifier other than the advantageous section number identifier.

Then, in "@ LT_AT1 EQU 000000001B; advantageous section number 1 identifier", "@ LT_AT1" indicates "advantageous section number 1 identifier", and the data corresponding to "@ LT_AT1" is "00000001 (B)". Means.
Further, in "@ LT_AT2 EQU 0000000010B; advantageous section number 2 identifier", "@ LT_AT2" indicates "advantageous section number 2 identifier", and the data corresponding to "@ LT_AT2" is "00000010 (B)". Means.
Furthermore, in "@MSK_AT EQU 00000111B; advantageous section number mask data", "@MSK_AT" indicates "advantageous section number mask data", and the data corresponding to "@MSK_AT" is "000000111 (B)". Means that.

FIGS. 105 to 108 are diagrams showing a lottery table common to all RTs in this embodiment.
FIG. 105 is a diagram showing a lottery table (8) common to all RTs. Further, FIG. 106 is a diagram showing a lottery table (9) common to all RTs, and is a diagram following FIG. 105. Furthermore, FIG. 107 is a diagram showing a lottery table (10) common to all RTs, and is a diagram following FIG. 106. Further, FIG. 108 is a diagram showing a lottery table (11) common to all RTs, and is a diagram following FIG. 107.
The non-RT lottery table, RT1 o'clock lottery table, RT2 o'clock lottery table, RT3 o'clock lottery table, RT4 o'clock lottery table, 1BBA time lottery table, and 1BBB time lottery table are the same as those in the 16th embodiment.

Further, at the time of non-RT, RT1, RT2, RT3, or RT4, the lottery determination is first performed using the lottery table common to all RTs, and at this time, when the winning number is determined to be "00 (H)", Next, a lottery judgment is made using the lottery table according to RT, and when the winning number is determined to be a value other than "00 (H)", the internal lottery is completed without using the lottery table according to RT. Is the same as in the 16th embodiment.
Furthermore, at the time of 1BBA, the lottery determination is performed using the 1BBA time lottery table, and at the time of 1BBB, the lottery determination is performed using the 1BBB time lottery table, as in the 16th embodiment.

Here, in FIG. 106, “DEFB @LT_BYT OR @ LT_AT1; 1-byte data identifier ;; + advantageous section number 1 identifier” is the data obtained by ORing “@LT_BYT” and “@ LT_AT1”. It is shown that it is stored in the second line of "1 BBA condition device lottery data".
Here, as shown in FIG. 104 (a), "@LT_BYT" indicates a 1-byte data identifier, and its value is "00001000 (B)".
Further, as shown in FIG. 104 (a), “@ LT_AT1” indicates an advantageous section number 1 identifier, and the value thereof is “00000001 (B)”.

Further, when "@LT_BYT" and "@ LT_AT1" are OR-operated,
00001000 (B): @LT_BYT
00000001 (B): @ LT_AT1
00001001 (B): Data after OR calculation.

In other words, "DEFB @ LT_BYT OR @ LT_AT1" indicates that "000001001 (B)" is stored in a predetermined 1-byte storage area on the ROM 54.
Thereby, the 1-byte data identifier and the advantageous section number 1 identifier can be represented by one 8-bit data.
Further, the comment "; 1-byte data identifier ;; + advantageous section number 1 identifier" indicates that the data includes the 1-byte data identifier and the advantageous section number 1 identifier.

Further, when "000001001 (B)" and "@MSK_AT" are ANDed,
00001001 (B): @ LT_BYT OR @ LT_AT1
00000111 (B): @MSK_AT
000000001 (B): Data after AND operation.
As a result, "00000001 (B)" = "@ LT_AT1" (advantageous section number 1 identifier) can be acquired.

When the probability data is 1 byte and the advantageous section 1 is won, the data including the 1-byte data identifier and the advantageous section number 1 identifier is stored in the lottery table.
Further, when the probability data is 1 byte and the advantageous section 2 is won, the data including the 1-byte data identifier and the advantageous section number 2 identifier is stored in the lottery table.

Furthermore, when the probability data is 2 bytes and the advantageous section 1 is won, the data including the 2-byte data identifier and the advantageous section number 1 identifier is stored in the lottery table.
Further, when the probability data is 2 bytes and the advantageous section 2 is won, the data including the 1-byte data identifier and the advantageous section number 1 identifier is stored in the lottery table.

Further, the decision to shift to the advantageous section 1 or the advantageous section 2 must be linked to the condition device having no setting difference. That is, the probability of shifting to the advantageous section 1 or the advantageous section 2 must not differ depending on the set value.
Therefore, one 8-bit data including the set value-specific identifier and the advantageous section number 1 identifier is not stored in the lottery table.
Similarly, one 8-bit data including the set value-specific identifier and the advantageous section number 2 identifier is not stored in the lottery table.

"1BBA condition device lottery data" is defined in the all RT common lottery table (8) of FIG. 105, and "1BBA condition device lottery data" is also defined in the all RT common lottery table (9) of FIG. 106. Therefore, "1BBA condition device lottery data" is also defined in the lottery table (10) common to all RTs in FIG. 107.
Here, when the "1BBA condition device lottery data" of FIG. 105 is used, "@BBA" = "38" is set as the winning number data, and "10" is set as the probability data. At this time, if it is determined that the player has won or not, the winning number is determined to be "38", but since the advantageous section number identifier is not defined, the advantageous section is not won.

Also, when the "1BBA condition device lottery data" of FIG. 106 is used, "@BBA" = "38" is set as the winning number data, and "10" is set as the probability data. Then, if it is determined that the winning or not is won at this time, the winning number is determined to be "38" and the advantageous section number 1 identifier is determined, so that the advantageous section 1 is won.
Further, when the "1BBA condition device lottery data" of FIG. 107 is used, "@BBA" = "38" is set as the winning number data, and "10" is set as the probability data. Then, if it is determined that the winning or not is won at this time, the winning number is determined to be "38" and the advantageous section number 2 identifier is determined, so that the advantageous section 2 is won.

As described above, in the present embodiment, the lottery table common to all RTs is the 1BBA condition device lottery data (1BBA condition device lottery data) in which the winning number data "38" and the probability data "10" are associated and the advantageous section number identifier is not associated. FIG. 105), 1BBA condition device lottery data (FIG. 106) in which the winning number data “38”, the probability data “10”, and the advantageous section number 1 identifier are associated, and the winning number data “38” and the probability data “10”. 1BBA condition device lottery data (FIG. 107) in which "" and the advantageous section number 2 identifier are associated with each other are defined.
That is, a plurality of probability data are defined corresponding to one winning number data. Then, of the plurality of probability data corresponding to one winning number data, one probability data is associated with the data indicating the transition from the normal section to the advantageous section 1 or the advantageous section 2, and the other one. The probabilistic data is not associated with the data indicating the transition from the normal interval to the advantageous interval.

Therefore, as described above, even when the winning number is determined to be the same "38" (it becomes a single winning of the 1BBA condition device), when the winning section is not won and the advantageous section 1 is set. It has a time when it wins and a time when it wins in the advantageous section 2.
"1BBA + small win D condition device lottery data", "1BBA + small win E1 condition device lottery data", "small win D condition device lottery data", and "small win E1 condition device lottery data" are also "data for small win E1 condition device lottery". 1BBA condition device lottery data ”is the same.

Further, in FIG. 105, "1BBA condition device lottery data", "1BBA + small winning combination D condition device lottery data", "1BBA + small winning combination E1 condition device lottery data", "small winning combination D condition device lottery data", And, regarding "small winning combination E1 condition device lottery data", those that are not won in the advantageous section are defined as a group.
Furthermore, in FIG. 106, "1BBA condition device lottery data", "1BBA + small winning combination D condition device lottery data", "1BBA + small winning combination E1 condition device lottery data", "small winning combination D condition device lottery data". , And "small winning combination E1 condition device lottery data", the ones that win the advantageous section 1 are defined as a group.

Further, in FIG. 107, "1BBA condition device lottery data", "1BBA + small winning combination D condition device lottery data", "1BBA + small winning combination E1 condition device lottery data", "small winning combination D condition device lottery data", And, regarding "small winning combination E1 condition device lottery data", the ones that win in the advantageous section 2 are defined as a group.
In this way, in the order of "a group of lottery data that is not won in the advantageous section" → "a group of lottery data that is won in the advantageous section 1" → "a group of lottery data that is won in the advantageous section 2" By defining the data in the lottery table, it is sufficient to determine the winning number data only in the "1BBA condition device lottery data", so that the amount of ROM 54 used by the lottery table can be reduced.

Specifically, the winning number definitions for the winning numbers "31" to "42" in the present embodiment are the same as the winning number definitions (3) in the 17th embodiment shown in FIG. 93 (a).
That is, the winning number corresponding to "1BBA single winning" is "38", and the winning number corresponding to "1BBA + small winning combination D duplicate winning" is "39", which corresponds to "1BBA + small winning combination E1 duplicate winning". The winning number is "40", the winning number corresponding to "small role D single winning" is "41", and the winning number corresponding to "small winning combination E1 single winning" is "42".

In this way, from "1BBA single winning" to "small role E1 single winning", the corresponding winning numbers are consecutive.
Therefore, as shown in FIG. 105, if "@BBA" (= "38") is defined as the winning number data for the "1BBA condition device lottery data", "1BBA + small winning combination D condition device lottery data" is used. As for the "data", the winning number data ("39") obtained by adding "1" to the winning number data ("38") of the "1BBA condition device lottery data" can be used as the winning number data.

Similarly, for "1BBA + small winning combination E1 conditional device lottery data", a value obtained by adding "1" to the winning number data ("39") of "1BBA + small winning combination D conditional device lottery data"("" 40 ") can be used as the winning number data.
Further, regarding the "small winning combination D condition device lottery data", the value ("41") obtained by adding "1" to the winning number data ("40") of "1BBA + small winning combination E1 condition device lottery data". ) Can be the winning number data.
Further, regarding the "small winning combination E1 condition device lottery data", the value ("42") obtained by adding "1" to the winning number data ("41") of the "small winning combination D condition device lottery data". Can be used as the winning number data.

Therefore, as shown in FIG. 105, if the winning number data is determined only for "1BBA condition device lottery data", "1BBA + small winning combination D condition device lottery data" and "1BBA + small winning combination E1 condition device lottery data" For "data", "small win D condition device lottery data", and "small win E1 condition device lottery data", it is not necessary to determine the winning number data, so the amount of ROM 54 used by the lottery table should be reduced. Can be done.
The "1BBA condition device lottery data" to "small combination E1 condition device lottery data" in FIG. 106 and the "small combination E1 condition device lottery data" to "1BBA condition device lottery data" in FIG. 107 are also shown in FIG. It is the same as the "small winning combination E1 condition device lottery data" from "1BBA condition device lottery data" of 105.

For example, "1BBA condition device lottery data that is not won in the advantageous section" → "1BBA condition device lottery data that is won in the advantageous section 1" → "1BBA condition device lottery data that is won in the advantageous section 2" The data can be set in the lottery table in the order of "."
However, in this case, since it is necessary to determine the winning number data for each lottery data, the amount of ROM 54 used by the lottery table increases accordingly.

Specifically, for example
1BBA condition device lottery data DEFB @LT_NUM OR @BBA; Winning number data identifier
;; + Winning number data DEFB @LT_BYT; 1-byte data identifier DEFB 10; Probability data (common to all settings)

1BBA condition device lottery data DEFB @LT_NUM OR @BBA; Winning number data identifier
;; + Winning number data DEFB @ LT_BYT OR @ LT_AT1; 1-byte data identifier
;; + Advantageous interval number 1 Identifier DEFB 10; Probability data (common to all settings)

1BBA condition device lottery data DEFB @LT_NUM OR @BBA; Winning number data identifier
;; + Winning number data DEFB @ LT_BYT OR @ LT_AT2; 1-byte data identifier
;; + Advantageous interval number 2 identifier DEFB 10; Probability data (common to all settings)
As described above, three types of "1BBA condition device lottery data" can be continuously determined.

Then, for example,
1BBA + small winning combination D condition device lottery data DEFB @LT_NUM OR @BBA_WD; winning number data identifier
;; + Winning number data DEFB @LT_BYT; 1-byte data identifier DEFB 5; Probability data (common to all settings)

1BBA + small winning combination D condition device lottery data DEFB @LT_NUM OR @BBA_WD; winning number data identifier
;; + Winning number data DEFB @ LT_BYT OR @ LT_AT1; 1-byte data identifier
;; + Advantageous section number 1 Identifier DEFB 2; Probability data (common to all settings)

1BBA + small winning combination D condition device lottery data DEFB @LT_NUM OR @BBA_WD; winning number data identifier
;; + Winning number data DEFB @ LT_BYT OR @ LT_AT2; 1-byte data identifier
;; + Advantageous section number 2 Identifier DEFB 3; Probability data (common to all settings)
As described above, three types of "1BBA + small winning combination D condition device lottery data" can be continuously determined.
However, in this case, since it is necessary to determine the winning number data for each lottery data, the amount of ROM 54 used by the lottery table increases accordingly.

FIG. 109 is a flowchart showing the flow of the lottery process for the condition device number and the like in the 18th embodiment.
Steps S1001 to S1004 and step S1006 are the same as those in the 16th embodiment.
Further, in the present embodiment, when the internal lottery 1 is executed in step S1004, the process proceeds to step S1201.

Further, when the process proceeds to step S1201, the advantageous section number acquisition (FIG. 110) is executed, and the process proceeds to step S1202.
Further, when the process proceeds to step S1202, the condition device number set 5 (FIG. 111) is executed, and the process proceeds to step S1006.
When the process proceeds to step S1006, the rotation of all the reels 31 is started, and the rotating reels 31 can be stopped by the operation of the stop switch 42 by the player. Then, when the rotation of all the reels 31 is stopped, the process according to this flowchart ends.

FIG. 110 is a flowchart showing the flow of processing for acquiring the advantageous section number.
Further, the advantageous section number acquisition is a process of acquiring the advantageous section number from the data defined in the lottery table.
Proceeding to the acquisition of the advantageous section number in step S1201, first, in step S1211, the main CPU 55 acquires the data corresponding to the winning number.
Specifically, at the time of proceeding to step S1211, a value indicating the address of the data on the lottery table used in the internal lottery 1 (FIG. 87) and the lottery determination (FIG. 88) is stored in the HL register.

For example, it is assumed that when the "1 BBA condition device lottery data" of FIG. 105 is used, it is determined that the winner is a winner. In this case, at the time of proceeding to step S1211, a value indicating the address of "DEFB @ LT_BYT" is stored in the HL register.
Further, it is assumed that when the "1 BBA condition device lottery data" shown in FIG. 106 is used, it is determined that the winner is a winner. In this case, at the time of proceeding to step S1211, a value indicating the address of "DEFB @ LT_BYT OR @ LT_AT1" is stored in the HL register.

Furthermore, it is assumed that when the "1 BBA condition device lottery data" of FIG. 107 is used, it is determined that the winner is a winner. In this case, at the time of proceeding to step S1211, a value indicating the address of "DEFB @ LT_BYT OR @ LT_AT2" is stored in the HL register.
Further, it is assumed that the process proceeds to the "judgment end" in FIG. In this case, at the time of proceeding to step S1211, a value indicating the address of "DEFB @ LT_END" is stored in the HL register.

Then, in step S1211, the main CPU 55 stores the data corresponding to the address indicated by the HL register in the B register.
For example, when the value indicating the address of "DEFB @ LT_BYT" in FIG. 105 is stored in the HL register, "DEFB @ LT_BYT" = "00001000 (B)" is stored in the B register.
Further, when the value indicating the address of "DEFB @ LT_BYT OR @ LT_AT1" in FIG. 106 is stored in the HL register, "DEFB @ LT_BYT OR @ LT_AT1" = "000001001 (B)" is stored in the B register. ..

Furthermore, when the value indicating the address of "DEFB @ LT_BYT OR @ LT_AT2" in FIG. 107 is stored in the HL register, "DEFB @ LT_BYT OR @ LT_AT2" = "000001010 (B)" is stored in the B register. do.
Further, when the value indicating the address of "DEFB @ LT_END" in FIG. 108 is stored in the HL register, "DEFB @ LT_END" = "00 (H)" is stored in the B register.
Then, the process proceeds to the next step S1212.

Proceeding to step S1212, the main CPU 55 generates an advantageous section number from the acquired data.
Specifically, the main CPU 55 performs an AND operation on the B register data and "@MSK_AT" (advantageous section number mask data = "000000111 (B)"), and the data obtained by this is used as a new B register. Data.

For example, when the data in the B register is "00001000 (B)", "0000000000 (B)" can be obtained by performing an AND operation on "00001000 (B)" and "000000111 (B)". Then, the obtained "00000000000 (B)" is stored in the B register. In this case, the advantageous section will not be won.
When the data in the B register is "000001001 (B)", "00000001 (B)" can be obtained by performing an AND operation on "000001001 (B)" and "000000111 (B)". Then, the obtained "00000001 (B)" (= "@ LT_AT1": advantageous section number 1) is stored in the B register. In this case, the advantage section 1 is won (decided to shift).

Furthermore, when the data in the B register is "000001010 (B)", "00000010 (B)" can be obtained by ANDing "000001010 (B)" and "000000111 (B)". Then, the obtained "00000010 (B)" (= "@ LT_AT2": advantageous section number 2) is stored in the B register. In this case, it will be elected (decided to shift) to the advantageous section 2.

Further, when the data in the B register is "00 (H)", "0000000000 (B)" can be obtained by performing an AND operation on "00 (H)" and "000000111 (B)". Then, the obtained "00000000000 (B)" is stored in the B register. In this case, the advantageous section will not be won.
Then, the process according to this flowchart is completed.
In the present embodiment, when the winning number is determined by the internal lottery 1 and the lottery determination, the advantageous section number acquisition of FIG. 110 is executed, the process proceeds to step S1212, and the advantageous section number is generated. , This is stored in the B register.

FIG. 111 is a flowchart showing a processing flow of the condition device number set 5.
Proceeding to the condition device number set 5 in step S1202, first, in step S1221, the main CPU 55 determines whether or not the winning number is smaller than the conversion start number.
The specific processing content in step S1221 is the same as in step S1041 of FIG. 89.

Then, when it is determined in step S1221 that the winning number is smaller than the conversion start number (Yes), steps S1222 to S1226 are skipped and the process proceeds to step S1227.
On the other hand, when it is determined in step S1221 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1222.
In step S1221, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

Proceeding to step S1222, the main CPU 55 acquires the condition device number from the winning number.
Here, in step S1112 of FIG. 99, the value indicating the “accessory condition device number” is stored in the E register, and the value indicating the “winning and replay condition device number” is stored in the D register.
On the other hand, in step S1222, the value indicating the "accessory condition device number" is stored in the C register, and the value indicating the "winning and replay condition device number" is stored in the A register.
Other than that, the specific contents of the process in step S1222 are the same as those in step S1112 in FIG. 99.

Proceeding to step S1223, the main CPU 55 determines whether or not the value stored in the “_NB_CND_BNS” (storage area of the accessory condition device number) of the RWM 53 is “0”.
In other words, it is determined whether or not the game is a game inside the bonus this time.
If "0" is stored in "_NB_CND_BNS" of RWM53, it is determined that the game is a game that is not inside the bonus, and if a value other than "0" is stored, this game is played. Is determined to be a game inside the bonus.

The specific processing content in step S1223 is the same as in step S1043 of FIG. 89.
Then, when it is determined in step S1223 that the accessory condition device number is "0" (Yes), the process proceeds to the next step S1224.
On the other hand, when it is determined in step S1223 that the accessory condition device number is other than "0" (No), steps S1224 to S1226 are skipped and the process proceeds to step S1227.

Proceeding to step S1224, the main CPU 55 determines whether or not the value stored in the “_NB_CND_AT” (storage area of the advantageous section number) of the RWM 53 is “0”.
In other words, it is determined whether or not the game is a normal section game this time.
When "0" is stored in "_NB_CND_AT" of RWM53, it is determined that the game is a normal section game, and when "1" is stored, the game is advantageous section 1 this time. When it is determined that the game is a game and "2" is stored, it is determined that the game is a game in the advantageous section 2 this time.

The specific processing content in step S1224 is the same as in step S1044 of FIG. 89.
Then, when it is determined in step S1224 that the advantageous section number is "0" (Yes), the process proceeds to the next step S1225.
On the other hand, when it is determined in step S1224 that the advantageous section number is other than "0" (No), step S1225 is skipped and the process proceeds to step S1226.

Proceeding to step S1225, the main CPU 55 stores the advantageous section number.
Specifically, at the time of proceeding to step S125, a value indicating an advantageous section number is stored in the B register.
Then, the main CPU 55 stores the value of the B register in the storage area "_NB_CND_AT" of the RWM53. As a result, the advantageous section number is saved.

Proceeding to step S1226, the main CPU 55 saves the accessory condition device number.
Specifically, at the time of proceeding to step S1046, a value indicating the accessory condition device number is stored in the C register.
Then, the main CPU 55 stores the value of the C register in the storage area "_NB_CND_BNS" of the RWM53. As a result, the accessory condition device number is saved.

Proceeding to step S1227, the main CPU 55 saves the winning and replay condition device numbers.
Here, when “Yes” is set in step S1221 and the process proceeds to step S1227, a value indicating a “winning number” is stored in the A register. When "Yes" is set in step S1221 (when the winning number is smaller than the conversion start number), "winning number" = "winning and replay condition device number" as shown in FIG. 74 (a). It is stipulated in. Therefore, when the result becomes “Yes” in step S1221 and the process proceeds to step S1227, the value of the A register indicates the “winning and replay condition device number”.

Further, in step S1222, a value indicating "winning and replay condition device number" is stored in the A register. Therefore, even when proceeding to step S1227 through step S1222, the value of the A register indicates the “winning and replay condition device number”.
As described above, at the time of proceeding to step S1227, a value indicating the winning and replay condition device number is stored in the A register.
Then, the main CPU 55 stores the value of the A register in the storage area "_NB_CND_NOR" of the RWM53. As a result, the winning and replay condition device numbers are saved.

In this way, the winning and replay condition device numbers are set depending on whether the step S1221 is "Yes" and the process proceeds to step S1227, or the step S1221 is "No" and the step S1222 is followed by the step S1227. The process of storing in "_NB_CND_NOR" can be shared, and the amount of ROM 54 used by the program can be reduced.
Then, the process according to this flowchart is completed.

In the present embodiment, the lottery regarding the transition from the normal section to the advantageous section has been described. For example, at the start of the game this time, a value other than "0" is stored in "_NB_CND_AT" (storage area of the advantageous section number). Even if it is, it is related to the addition of the advantageous section (including changing the performance so that the gaming state in the advantageous section is advantageous to the player and adding the number of AT games in the advantageous section). The lottery may be executed and the value of "_NB_CND_AT" may be changed according to the result.

For example, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" (storage area of the accessory condition device number) is "0", a lottery for adding an advantageous section may be executed. ..
Further, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" is "0", a lottery for adding an advantageous section is executed, and "2" is set in "_NB_CND_AT" according to the result. You may execute the control process which memorizes.
When the value of "_NB_CND_BNS" is "1" (so-called internal), the lottery for adding the advantageous section is not executed.

<19th Embodiment>
Subsequently, the 19th embodiment of the present invention will be described.
FIG. 112 (a) is a diagram showing the winning number definition (4) in the present embodiment.
Here, the winning number definition (4) in FIG. 112A shows the winning number definitions for the winning numbers "31" to "36".
The winning number definitions for the winning numbers "1" to "30" are the same as the winning number definition (1) of the 16th embodiment shown in FIG. 74 (a).

As shown in FIGS. 74 (a) and 112 (a), in the present embodiment, the winning numbers are defined from "1" to "36".
Further, as shown in FIG. 112 (a), in the present embodiment, the winning numbers "31" and "35" correspond to the single winning of the accessory condition device, and the winning numbers "32" to "34". The numbers "" and "36" correspond to the duplicate winning of the character condition device and the winning and replay condition device.

FIG. 112B is a diagram showing data definitions for winning number conversion and advantageous section transition determination in the present embodiment.
As shown in FIG. 112 (c), "@ LOT_TRNS_AT1 EQU 167 + @ LOT_TRNS_AT2; advantageous section 1 transition determination random number" corresponds to "@ LOT_TRNS_AT1" indicating "advantageous section 1 transition determination random number" and "@ LOT_TRNS_AT1". It means that the value to be used is "167 + @ LOT_TRNS_AT2".
Further, "@ LOT_TRNS_AT2" = "178".
Therefore, "@ LOT_TRNS_AT1" = "167 + 178" = "345".

As shown in FIG. 112 (d), “@ LOT_TRNS_AT2 EQU 178; advantageous section 2 transition determination random number” means that “@ LOT_TRNS_AT2” indicates “advantageous section 2 transition determination random number”, and a value corresponding to “@ LOT_TRNS_AT2”. Means that is "178". That is, "@ LOT_TRNS_AT2" = "178".
The advantageous section 1 transition determination random number and the advantageous section 2 transition determination random number are collectively referred to as an “advantageous section transition determination random number”.

FIG. 113A is a diagram showing a winning number conversion table in this embodiment.
As shown in FIG. 113 (a), when the winning numbers determined by the winning number determining means are "31" to "36", the winning number conversion table corresponds to the determined winning numbers. It is used when determining the "feature condition device number" and the "winning and replay condition device number".

As shown in FIG. 113 (b), "DEFB @ NB_1BBA, 0; winning number 31" stores "@ NB_1BBA" in the address ### 0 (for example, address 1600 (H)), and the address ### 1 It means that "0" is stored in (for example, address 1601 (H)). As shown in FIG. 112 (b), "@ NB_1BBA" = "1". Therefore, "1" is stored in the address ### 0, and "0" is stored in the address ### 1.

That is,
Address ## # 0 (address 1600 (H)) 1: Character condition device number Address ## # 1 (address 1601 (H)) 0: Winning and replay condition device number.
Then, each data stored in the address ## 0 and the address ## 1 is used when the winning number is determined to be "31".

As shown in FIG. 113 (c), "DEFB @ NB_1BBB, @ NB_WIN_D; winning number 32" stores "@ NB_1BBB" in the address ### 2 (for example, address 1602 (H)), and the address ### It means that "@NB_WIN_D" is stored in 3 (for example, address 1603 (H)). As shown in FIG. 112 (b), "@ NB_1BBB" = "2". Further, as shown in FIG. 74, “@NB_WIN_D” = “26”. Therefore, "2" is stored in the address ### 2, and "26" is stored in the address ### 3.

That is,
Address ### 2 (address 1602 (H)) 2: Accessory condition device number Address ### 3 (address 1603 (H)) 26: Winning and replay condition device number.
Then, each data stored in the address ## # 2 and the address ## # 3 is used when the winning number is determined to be "32".

The winning number lottery data definition is the same as the winning number lottery data definition of the 16th embodiment shown in FIG. 78 (a).
114, 115, and 116 are diagrams showing a lottery table common to all RTs in this embodiment.
FIG. 114 is a diagram showing a lottery table (12) common to all RTs. Further, FIG. 115 is a diagram showing a lottery table (13) common to all RTs, and is a diagram following FIG. 114. Furthermore, FIG. 116 is a diagram showing a lottery table (14) common to all RTs, and is a diagram following FIG. 115.
The non-RT lottery table, RT1 o'clock lottery table, RT2 o'clock lottery table, RT3 o'clock lottery table, RT4 o'clock lottery table, 1BBA time lottery table, and 1BBB time lottery table are the same as those in the 16th embodiment.

Further, at the time of non-RT, RT1, RT2, RT3, or RT4, the lottery determination is first performed using the lottery table common to all RTs, and at this time, when the winning number is determined to be "00 (H)", Next, a lottery judgment is made using the lottery table according to RT, and when the winning number is determined to be a value other than "00 (H)", the internal lottery is completed without using the lottery table according to RT. Is the same as in the 16th embodiment.
Furthermore, at the time of 1BBA, the lottery determination is performed using the 1BBA time lottery table, and at the time of 1BBB, the lottery determination is performed using the 1BBB time lottery table, as in the 16th embodiment.

FIG. 117A is a diagram showing an advantageous section transition determination random number table.
The advantageous section transition determination random number table is used in the advantageous section transition lottery shown in FIG. 121, which will be described later, and "@LOT_TRNS_AT2" is defined as a criterion for determining that the advantageous section 2 is won (decided to shift). At the same time, "@LOT_TRNS_AT1" is set as a criterion for determining that the advantageous section 1 is won.
Then, when the random number value acquired from the random number generating means (counter) is smaller than "@ LOT_TRNS_AT2" (= "178"), it is determined that the advantageous section 2 has been won, and from "@ LOT_TRNS_AT1" (= "345"). When it is small, it is determined that the advantageous section 1 is won.

Here, "DEFW" is an assembly language that "allocates two 1-byte (8-bit) areas in the memory in the order of addresses, stores the lower 1 byte of 2-byte data in the previous address, and stores the lower 1 byte of the data in the later address. It is a pseudo-instruction that "stores the upper 1 byte of 2-byte data".
As shown in FIG. 117 (c), "DEFW @ LOT_TRNS_AT2; advantageous section number 2" is assigned to the address ### 0 (for example, address 1700 (H)) as "@ LOT_TRNS_AT2" (= "178 (D)" = " The lower 1 byte of "00B2 (H)") is stored in "B2 (H)", and the upper 1 byte of "@LOT_TRNS_AT2" is stored in the address ### 1 (for example, address 1701 (H)) "00 (H)". ) ”Is memorized.

As shown in FIG. 117 (d), "DEFW @ LOT_TRNS_AT1; advantageous section number 1" is assigned to the address ### 2 (for example, address 1702 (H)) as "@ LOT_TRNS_AT1" (= "345 (D)" = " "59 (H)" which is the lower 1 byte of "0159 (H)") is stored, and "01 (H)" which is the upper 1 byte of "@LOT_TRNS_AT1" is stored in the address ### 3 (for example, address 1703 (H)). ) ”Is memorized.

That is,
Address ### 0 (Address 1700 (H)) B2 (H): Lower 1-byte address ### 1 (Address 1701 (H)) 00 (H): Upper 1-byte address ### 2 (1702 (H)) Address) 59 (H): Lower 1 byte address ### 3 (1703 (H) address) 01 (H): Upper 1 byte.

FIG. 118 is a flowchart showing the flow of the lottery process for the condition device number and the like in the 19th embodiment.
Steps S1001 to S1003 and step S1006 are the same as those in the 16th embodiment.
Further, in the present embodiment, if the blocker 45 is controlled so that the insertion of medals is prohibited in step S1003, the process proceeds to step S1301.

Further, when the process proceeds to step S1301, the internal lottery 2 (FIG. 119) is executed, and the process proceeds to step S1302.
Further, when the process proceeds to step S1302, the condition device number set 6 (FIG. 120) is executed, and the process proceeds to step S1006.
When the process proceeds to step S1006, the rotation of all the reels 31 is started, and the rotating reels 31 can be stopped by the operation of the stop switch 42 by the player. Then, when the rotation of all the reels 31 is stopped, the process according to this flowchart ends.

FIG. 119 is a flowchart showing the processing flow of the internal lottery 2.
Proceeding to the internal lottery 2 in step S1301, first, in step S1311, the main CPU 55 stores the random number value in "_BF_RAND" (random number buffer).
Here, "_BF_RAND" is a 2-byte storage area on the RWM53 that stores a random number value.
Then, when the main CPU 55 proceeds to step S1301, first, the random number value stored in the random number value register is stored in the HL register, and then the random number value stored in the HL register is stored in the storage area "_BF_RAND" of the RWM53. Remember. As a result, the random number value is saved in the random number buffer. Then, the process proceeds to the next step S1312.

Proceeding to step S1312, the main CPU 55 stores a random number value.
Specifically, the main CPU 55 stores the random number value stored in the HL register in the DE register. Then, the process proceeds to the next step S1313.
Proceeding to step S1313, the main CPU 55 sets a lottery table according to the operating state of the accessory (when 1BBA is operating, when 1BBB is operating, or when the accessory is not operating).
The specific processing content in step S1313 is the same as in step S1012 of FIG. 87. Then, the process proceeds to the next step S1314.

Proceeding to step S1314, the main CPU 55 determines whether or not the accessory is operating.
The specific processing content in step S1314 is the same as in step S1013 of FIG. 87.
Then, when it is determined that the accessory is operating (Yes), steps S1315 to S1317 are skipped and the process proceeds to step S1318.
On the other hand, when it is determined that the accessory is not in operation (No), the process proceeds to the next step S1315.

Proceeding to step S1315, the main CPU 55 executes the lottery determination (FIG. 88) using the lottery table set in step S1313. Then, the process proceeds to the next step S1316.
Proceeding to step S1316, the main CPU 55 determines whether or not the lottery has been won.

The specific processing content in step S1316 is the same as in step S1015 of FIG.
Then, when it is determined that the lottery has been won (Yes), steps S1317 and S1318 are skipped, and the process according to this flowchart is terminated.
On the other hand, when it is determined that the lottery has not been won (No), the process proceeds to the next step S1317.

In step S1317, the main CPU 55 sets a lottery table according to the RT state (non-RT, RT1, RT2, RT3 or RT4).
The specific processing content in step S1317 is the same as in step S1016 of FIG. 87. Then, the process proceeds to the next step S1318.
Proceeding to step S1318, the main CPU 55 executes the lottery determination (FIG. 88) using the lottery table set in step S1313 or S1317. Specifically, when the accessory is activated, the lottery determination is executed using the lottery table set in step S1313, and when the accessory is not activated, the lottery determination is executed using the lottery table set in step S1317. Then, the process according to this flowchart is completed.

FIG. 120 is a flowchart showing a processing flow of the condition device number set 6.
Proceeding to the condition device number set 6 in step S1302, first, in step S1321, the main CPU 55 determines whether or not the winning number is smaller than the conversion start number.
The specific processing content in step S1321 is the same as in step S1041 of FIG. 89.

Then, when it is determined in step S1321 that the winning number is smaller than the conversion start number (Yes), step S1322 is skipped and the process proceeds to step S1323.
On the other hand, when it is determined in step S1321 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1322.
In step S1321, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

In step S1322, the main CPU 55 acquires the condition device number corresponding to the winning number from the winning number conversion table of FIG. 113 (a).
The specific processing content in step S1322 is the same as that in step S1222 of FIG. 111. Then, the process proceeds to the next step S1323.

Proceeding to step S1323, the main CPU 55 determines whether or not the accessory is operating.
The specific processing content in step S1323 is the same as in step S1013 of FIG. 87.
Then, when it is determined that the accessory is operating (Yes), steps S1324 to S1327 are skipped, and the process proceeds to step S1328.
On the other hand, when it is determined that the accessory is not in operation (No), the process proceeds to the next step S1324.

In step S1324, the main CPU 55 determines whether or not the value stored in the “_NB_CND_BNS” (storage area of the accessory condition device number) of the RWM 53 is “0”.
In other words, it is determined whether or not the game is a game inside the bonus this time.
The specific content of the process in step S1324 is the same as that in step S1043 of FIG. 89.

Then, in step S1324, when it is determined that "0" is stored in "_NB_CND_BNS" of RWM53 (Yes), it is determined that this game is a game in which the bonus is not inside, and the process proceeds to the next step S1325. ..
On the other hand, in step S1324, when it is determined that a value other than "0" is stored in "_NB_CND_BNS" of RWM53 (No), it is determined that this game is a game inside the bonus, and step S1325. -S1327 is skipped, and the process proceeds to step S1328.

In step S1325, the main CPU 55 determines whether or not the value stored in the “_NB_CND_AT” (storage area of the advantageous section number) of the RWM 53 is “0”.
In other words, it is determined whether or not the game is a normal section game this time.
The specific processing content in step S1325 is the same as in step S1044 of FIG. 89.

Then, in step S1325, when it is determined that "0" is stored in "_NB_CND_AT" of RWM53 (Yes), it is determined that this game is a normal section game, and the process proceeds to the next step S1326.
On the other hand, in step S1325, when it is determined that a value other than "0" is stored in "_NB_CND_AT" of RWM53 (No), it is determined that the game is an advantageous section game this time, and step S1326 is performed. Skip to step S1327.

Proceeding to step S1326, the main CPU 55 executes an advantageous section transition lottery (FIG. 121). Then, when the advantageous section transition lottery is executed, the process proceeds to the next step S1327.
In step S1327, the main CPU 55 stores the accessory condition device number.
Specifically, at the time of proceeding to step S1327, a value indicating the accessory condition device number is stored in the C register.
Then, the main CPU 55 stores the value of the C register in the storage area "_NB_CND_BNS" of the RWM53. As a result, the accessory condition device number is saved. Then, the process proceeds to the next step S1328.

Proceeding to step S1328, the main CPU 55 saves the winning and replay condition device numbers.
Here, when “Yes” is set in step S1321 and step S1322 is skipped and the process proceeds to step S1328, a value indicating a “winning number” is stored in the A register. When "Yes" is set in step S1321 (when the winning number is smaller than the conversion start number), "winning number" = "winning and replay condition device number" as shown in FIG. 74 (a). It is stipulated in. Therefore, when it becomes "Yes" in step S1321 and skips step S1322 and proceeds to step S1328, the value of the A register indicates "winning and replay condition device number".

Further, when the result is "No" in step S1321 and the process proceeds to step S1322, a value indicating "winning and replay condition device number" is stored in the A register. Therefore, when the result is "No" in step S1321 and the process proceeds to step S1328 through step S1322, the value of the A register indicates the "winning and replay condition device number".
As described above, at the time of proceeding to step S1328, the value indicating the winning and replay condition device number is stored in the A register.

Then, in step S1328, the main CPU 55 stores the value of the A register in the storage area “_NB_CND_NOR” of the RWM53. As a result, the winning and replay condition device numbers are saved.
In this way, a prize is won when the result is "Yes" in step S1321 and the step S1322 is skipped to proceed to step S1328, and when the result is "No" in step S1321 and the process proceeds to step S1328 through step S1322. And the process of storing the replay condition device number in "_NB_CND_NOR" can be shared, and the amount of ROM 54 used by the program can be reduced.
Then, the process according to this flowchart is completed.

FIG. 121 is a flowchart showing the flow of processing of the advantageous section transition lottery.
Further, in the advantageous section transition lottery, the random number value acquired from the random number generating means (counter) and "@ LOT_TRNS_AT1" (advantageous section 1 transition determination random number) and "@LOT_TRNS_AT2" (advantageous section) defined in the advantageous section transition determination random number table are used. 2 This is a process of determining whether to shift to the advantageous section 1, shift to the advantageous section 2, or not shift to the advantageous section based on the transition determination random number).

Proceeding to the advantageous section transition lottery in step S1326, first, in step S1331, the main CPU 55 sets the initial value of the number of determinations.
Specifically, the main CPU 55 stores "2" in the B register as the initial value of the number of determinations. Then, the process proceeds to the next step S1332.
Proceeding to step S1332, the main CPU 55 sets the address of the advantageous section transition determination random number.

Specifically, the main CPU 55 stores the start address of "TBL_AT_RAND" (advantageous section transition determination random number table) in the HL register. Then, the process proceeds to the next step S1333.
In step S1333, the main CPU 55 acquires a random number value.
Specifically, at the time of proceeding to step S1333, the random number value acquired from the random number generating means (counter) is stored in the storage area “_BF_RAND” (random number buffer) of the RWM53. Then, the main CPU 55 stores the random number value stored in "_BF_RAND" in the DE register. Then, the process proceeds to the next step S1334.

Proceeding to step S1334, the main CPU 55 determines whether or not the acquired random number value is smaller than the advantageous section transition determination random number.
Specifically, the main CPU 55 subtracts the data corresponding to the address indicated by the HL register (advantageous section transition determination random number) from the data (random number value) of the DE register, and determines whether or not carry has occurred by the subtraction. do.

Here, when it is determined that the carry has occurred due to the subtraction, it is determined that the random number value is smaller than the advantageous section transition determination random number (Yes), steps S135 to S1337 are skipped, and the process proceeds to step S1338.
On the other hand, when it is determined that the carry has not occurred due to the subtraction, it is determined that the random number value is equal to or greater than the advantageous section transition determination random number (No), and the process proceeds to the next step S1335.
In step S1334, the data corresponding to the address indicated by the HL register (advantageous section transition determination random number) is subtracted from the DE register data (random value) to determine whether or not carry has occurred, but the data is subtracted. However, the data in the DE register is maintained without being updated. That is, even after the subtraction, the data in the DE register shows a "random value".

Proceeding to step S1335, the main CPU 55 updates the address of the advantageous section transition determination random number.
Specifically, the main CPU 55 repeats twice by adding "1" to the value of the HL register to obtain a new HL register value. That is, "2" is added to the value of the HL register. Then, the process proceeds to the next step S1336.
Proceeding to step S1336, the main CPU 55 updates the number of determinations.
Specifically, the main CPU 55 subtracts "1" from the value of the B register to obtain a new value of the B register. Then, the process proceeds to the next step S1337.

In step S1137, the main CPU 55 determines whether or not to end the determination.
Specifically, the main CPU 55 determines whether or not the value of the B register is "0".
Then, when it is determined that the value of the B register is "0" (Yes), the process proceeds to the next step S1338.
On the other hand, when it is determined that the value of the B register is not "0" (No), the process returns to step S1334.
As a result, the first time, the advantageous section 2 transition judgment random number is subtracted from the random number value to determine whether or not a carry has occurred, and the second time, the advantageous section 1 transition judgment random number is subtracted from the random number value to carry. It will be judged whether or not it has occurred.

Proceeding to step S1338, the main CPU 55 stores the number of determinations as an advantageous section number.
Specifically, the main CPU 55 stores the value of the B register in the storage area "_NB_CND_AT" of the RWM53. As a result, the advantageous section number is saved.
Then, the process according to this flowchart is completed.

As described above, in the present embodiment, when a predetermined condition is satisfied (not when the accessory is activated (“No” in step S1323 of FIG. 120), and not inside (“Yes” in step S1324). ), And when it is not an advantageous section (“Yes” in step S1325)), the advantageous section transition lottery is executed (progresses to step S1326).

Further, in the advantageous section transition lottery, when the random number value acquired from the random number generating means is smaller than "@LOT_TRNS_AT2" (advantageous section 2 transition determination random number = "178"), it is decided to win (transfer) to the advantageous section 2. ).
That is, when the random number value acquired from the random number generating means belongs to the range of "0" to "177", the advantageous section 2 is won.

Further, as shown in FIG. 114, "probability data" is totaled from "small winning combination D condition device and advantageous section number 2 lottery data" to "1BBA + small winning combination E1 condition device and advantageous section number 2 lottery data". Then, "30" + "125" + "10" + "3" + "10" = "178".
Therefore, in the lottery of the conditional device, when the random number value acquired from the random number generating means belongs to the range of "0" to "177", as shown in FIG. 114, the small winning combination D conditional device is independently won or small. The winning combination E1 condition device is independently won, the 1BBA condition device is independently won, the 1BBA condition device and the small combination D condition device are duplicately won, or the 1BBA condition device and the small combination E1 condition device are duplicately won.

Further, in the advantageous section transition lottery, when the random number value acquired from the random number generating means is smaller than "@LOT_TRNS_AT1" (advantageous section 1 transition determination random number = "345"), it is decided to win (transfer) to the advantageous section 1. ).
However, as described above, when the random number value acquired from the random number generating means belongs to the range of "0" to "177", the advantageous section 2 is won.
Therefore, when the random number value acquired from the random number generating means belongs to the range of "178" to "344", the advantageous section 1 is won.

Further, as shown in FIG. 114, "probability data" is totaled from "small winning combination D condition device and advantageous section number 1 lottery data" to "1BBA + small winning combination E1 condition device and advantageous section number 1 lottery data". Then, "20" + "125" + "10" + "2" + "10" = "167".
Further, for "small winning combination D condition device and advantageous section number 2 lottery data" to "1BBA + small winning combination E1 condition device and advantageous section number 2 lottery data", the total "probability data" is "178". When "167" is added to, it becomes "345".

Therefore, in the lottery of the conditional device, when the random number value acquired from the random number generating means belongs to the range of "178" to "344", as shown in FIG. 114, the small winning combination D conditional device is independently won or small. The winning combination E1 condition device is independently won, the 1BBA condition device is independently won, the 1BBA condition device and the small combination D condition device are duplicately won, or the 1BBA condition device and the small combination E1 condition device are duplicately won.

Further, the lottery table common to all RTs is commonly used in non-RT, RT1, RT2, RT3, and RT4, and when this lottery table common to all RTs is used, the small winning combination D condition device Single winning, single winning of the small winning combination E1 condition device, single winning of the 1BBA condition device, overlapping winning of the 1BBA condition device and the small winning combination D condition device, or overlapping winning of the 1BBA condition device and the small winning combination E1 condition device.
Therefore, in the present embodiment, although the replay condition device has non-RT, RT1, RT2, RT3, and RT4 having different winning probabilities, the random number value acquired from the random number generating means is in the range of "0" to "344". The condition device that wins when belonging is the same regardless of whether it is non-RT, RT1, RT2, RT3, or RT4.

In the present embodiment, the lottery regarding the transition from the normal section to the advantageous section has been described. For example, at the start of the game this time, a value other than "0" is stored in "_NB_CND_AT" (storage area of the advantageous section number). Even if it is, it is related to the addition of the advantageous section (including changing the performance so that the gaming state in the advantageous section is advantageous to the player and adding the number of AT games in the advantageous section). The lottery may be executed and the value of "_NB_CND_AT" may be changed according to the result.

For example, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" (storage area of the accessory condition device number) is "0", a lottery for adding an advantageous section may be executed. ..
Further, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" is "0", a lottery for adding an advantageous section is executed, and "2" is set in "_NB_CND_AT" according to the result. You may execute the control process which memorizes.
When the value of "_NB_CND_BNS" is "1" (so-called internal), the lottery for adding the advantageous section is not executed.

<Modified example of the 19th embodiment>
Subsequently, a modified example of the 19th embodiment of the present invention will be described.
In the modified example of the 19th embodiment, the processing of the condition device number set is different from that of the 19th embodiment.
In the processing of the condition device number set 6 of the 19th embodiment, the advantageous section transition lottery is performed to store the advantageous section number in "_NB_CND_AT", and then the accessory condition device number is stored in "_NB_CND_BNS" and a prize is won. And the replay condition device number was stored in "_NB_CND_NOR".

On the other hand, in the condition device number set 7 of the modified example of the 19th embodiment, the accessory condition device number is stored in "_NB_CND_BNS", and the winning and replay condition device numbers are stored in "_NB_CND_NOR". The advantageous section transition lottery is performed and the advantageous section number is stored in "_NB_CND_AT".

FIG. 122 is a flowchart showing a flow of lottery processing such as a condition device number in a modified example of the 19th embodiment.
Steps S1001 to S1003 and step S1006 are the same as those in the 16th embodiment.
Further, step S1301 is the same as that of the 19th embodiment, and step S1052 is the same as the modified example of the 16th embodiment.
Further, in the present embodiment, when the internal lottery 2 is executed in step S1301, the process proceeds to step S1341.
Then, when the process proceeds to step S1341, the condition device number set 7 (FIG. 123) is executed, and the process proceeds to step S1006.

FIG. 123 is a flowchart showing a processing flow of the condition device number set 7.
Proceeding to the condition device number set 7 in step S1341, first, in step S1351, the main CPU 55 determines whether or not the winning number is smaller than the conversion start number.
The specific processing content in step S1351 is the same as in step S1041 of FIG. 89.

Then, when it is determined in step S1351 that the winning number is smaller than the conversion start number (Yes), steps S1352 to S1354 are skipped and the process proceeds to step S1355.
On the other hand, when it is determined in step S1351 that the winning number is equal to or greater than the conversion start number (No), the process proceeds to the next step S1352.
In step S1351, "31" is subtracted from the value of the A register (winning number) to determine whether or not a carry has occurred, but even if the subtraction is performed, the value of the A register is maintained without being updated. That is, even after the subtraction, the value of the A register indicates the "winning number".

Proceeding to step S1352, the main CPU 55 acquires the condition device number corresponding to the winning number from the winning number conversion table shown in FIG. 113 (a).
The specific processing content in step S1352 is the same as in step S1222 of FIG. 111. Then, the process proceeds to the next step S1323.

In step S1353, the main CPU 55 determines whether or not the accessory condition device number is “0”.
The specific processing content in step S1353 is the same as in step S1043 of FIG. 89.
Then, when it is determined in step S1353 that the accessory condition device number is "0" (Yes), the process proceeds to the next step S1354.
On the other hand, when it is determined in step S1353 that the accessory condition device number is other than "0" (No), step S1354 is skipped and the process proceeds to step S1355.

In step S1354, the main CPU 55 stores the accessory condition device number.
Specifically, at the time of proceeding to step S1354, a value indicating the accessory condition device number is stored in the C register.
Then, the main CPU 55 stores the value of the C register in the storage area "_NB_CND_BNS" of the RWM53. As a result, the accessory condition device number is saved. Then, the process proceeds to the next step S1355.

Proceeding to step S1355, the main CPU 55 saves the winning and replay condition device numbers.
Here, when “Yes” is set in step S1351 and step S1352 is skipped to proceed to step S1355, a value indicating a “winning number” is stored in the A register. When "Yes" is set in step S1351 (when the winning number is smaller than the conversion start number), "winning number" = "winning and replay condition device number" as shown in FIG. 74 (a). It is stipulated in. Therefore, when it becomes "Yes" in step S1351 and skips step S1352 and proceeds to step S1355, the value of the A register indicates "winning and replay condition device number".

Further, when the result is "No" in step S1351 and the process proceeds to step S1352, a value indicating "winning and replay condition device number" is stored in the A register. Therefore, when the result is "No" in step S1351 and the process proceeds to step S1355 through step S1352, the value of the A register indicates the "winning and replay condition device number".
As described above, at the time of proceeding to step S1355, a value indicating the winning and replay condition device number is stored in the A register.

Then, in step S1355, the main CPU 55 stores the value of the A register in the storage area “_NB_CND_NOR” of the RWM53. As a result, the winning and replay condition device numbers are saved.
In this way, when the step S1351 becomes "Yes" and the process proceeds to step S1355, and when the step S1351 becomes "No" and the process proceeds to step S1352, the winning and replay condition device numbers are set. The process of storing in "_NB_CND_NOR" can be shared, and the amount of ROM 54 used by the program can be reduced.

Proceeding to step S1356, the main CPU 55 determines whether or not the accessory is operating.
The specific processing content in step S1356 is the same as in step S1013 of FIG. 87.
Then, when it is determined that the accessory is not in operation (No), the process proceeds to the next step S1357.
On the other hand, when it is determined that the accessory is operating (Yes), steps S1357 to S1326 are skipped, and the process according to this flowchart is terminated.

Proceeding to step S1357, the main CPU 55 determines whether or not the internal middle flag is on.
The specific content of the process in step S1357 is the same as that in step S1078 of FIG.
Then, in step S1357, when it is determined that the internal middle flag is off (No), the process proceeds to the next step S1358.
On the other hand, when it is determined in step S1357 that the internal middle flag is on (Yes), steps S1358 and S1326 are skipped, and the process according to this flowchart ends.

Proceeding to step S1358, the main CPU 55 determines whether or not the advantageous section number is “0”.
The specific content of the process in step S1358 is the same as that in step S1044 of FIG. 89.
Then, when it is determined in step S1358 that the advantageous section number is "0" (Yes), the process proceeds to the advantageous section transition lottery (FIG. 121) in step S1326.
On the other hand, when it is determined in step S1358 that the advantageous section number is other than "0" (No), the advantageous section transition lottery (FIG. 121) in step S1326 is skipped, and the process according to this flowchart is terminated. ..

Proceeding to step S1326, the main CPU 55 executes an advantageous section transition lottery (FIG. 121). Then, when the advantageous section transition lottery is completed, the processing according to this flowchart is completed.
The content of the advantageous section transition lottery process in step S1326 is the same as that of the 19th embodiment.

Here, in the condition device number set 7, when the winning numbers determined by the internal lottery 2 and the lottery determination are "31" to "36", the accessory condition device is won.
In this case, when the value of "_NB_CND_BNS" is "0" (when "Yes" in step S1353), the accessory condition device number is stored in "_NB_CND_BNS" (step S1354), and the value of "_NB_CND_BNS" is ". When it is other than "0" (when "No" in step S1353), the value of "_NB_CND_BNS" is maintained (step S1354 is skipped).

Further, in the condition device number set 7, when the accessory is operating (the value of "_FL_ACTION" is not "0"), the internal flag is on (the value of "_FL_PRD_LOT" is "FF (H)"). When there is), and when the advantageous section number is not "0" (the value of "_NB_CND_AT" is not "0"), the advantageous section transition lottery is not executed (step S1326 is skipped).
Then, when the accessory is not operating (the value of "_FL_ACTION" is "0"), the internal flag is off (the value of "_FL_PRD_LOT" is "0"), and the advantageous section number is When it is "0" (the value of "_NB_CND_AT" is "0"), the advantageous section transition lottery is executed (progresses to step S1326).
As a result, it is possible to execute the process related to the advantageous section transition lottery without requiring a complicated process.

Further, in the condition device number set 7, the value of "_NB_CND_BNS" is the value of "_NB_CND_BNS" when the winning numbers determined by the internal lottery 2 and the lottery determination are the numbers "31" to "36" for winning the accessory condition device. Is "0" (when "Yes" in step S1353), the accessory condition device number is stored in "_NB_CND_BNS" (step S1354), and then the advantageous section transition lottery is executed (step S1326).
Therefore, in the condition device number set 7, even if it is determined whether or not the value of "_NB_CND_BNS" is "0" in the step before executing the advantageous section transition lottery, the character condition device is won in this game. It is not possible to determine whether or not the player has won the character condition device before the previous game.

Therefore, in the condition device number set 7, in step S1357 before executing the advantageous section transition lottery, by determining whether or not the internal middle flag is on, whether or not the character condition device was won in the game this time, or the previous time. It is determined whether or not the character condition device was won before the game.
Then, when the internal middle flag is off, it is determined that the character condition device has been won in this game, and the advantageous section transition lottery is executed (step S1326).

Further, in the condition device number set 7, in step S1352, the value indicating the “accessory condition device number” is stored in the C register, and the value indicating the “winning and replay condition device number” is stored in the A register. After that, in step S1354, the value of the C register (accessory condition device number) is stored in "_NB_CND_BNS", and in step S1355, the value of the A register (winning and replay condition device number) is stored in "_NB_CND_NOR".

Therefore, even if the value of the C register is destroyed after step S1354, the accessory condition device number is not lost, and even if the value of the A register is destroyed after step S1355, the prize is won and the replay is performed. The condition device number is not lost.
Therefore, in the condition device number set 7, the C register can be used for other processing after step S1354, and the A register can be used for other processing after step S1355. can.
As another process, for example, an additional lottery for an AT (instructed game section) in an advantageous section can be mentioned.

Further, in the condition device number set 7, in step S1357, by determining whether or not the internal middle flag is on, whether or not the character condition device was won in this game, or the character condition device was won before the previous game. I decided if I did.
However, not limited to this, for example, in step S1357, by determining whether or not the RT4 corresponds to the inside, whether or not the character condition device was won in this game, or the character condition device was used before the previous game. You may decide whether you have won.

Furthermore, in the condition device number set 7, the accessory is not operating (“No” in step S1356), the internal middle flag is off (“No” in step S1357), and the advantageous section number is “0”. (“Yes” in step S1358), the advantageous section transition lottery was executed (step S1326).
However, the present invention is not limited to this, and the advantageous section transition lottery may be executed, for example, when the accessory is operating, when the internal middle flag is on, and when the advantageous section number is not "0". In this case, even if the advantageous section transition lottery is executed, the advantageous section number is maintained by skipping step S1338 in FIG. 121 (the value of "_NB_CND_AT" is maintained).

Although the 16th to 19th embodiments of the present invention have been described above, the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the 16th to 19th embodiments, two types of advantageous sections 1 and 2 are provided as advantageous sections. Further, in the normal section, it was decided whether to shift to the advantageous section 1 or the advantageous section 2. Then, if the player wins the advantageous section 1 (decides to move), the game state shifts to the game state of Gase, which does not have the right to move to the ART, and if the player wins the advantageous section 2, the game state allows the player to move to the ART (ART). After the precursor), it was transferred to ART. However, it is not limited to this.

For example, there may be only one type of advantageous section, and in the normal section, it may be determined whether or not to shift to the advantageous section.
Then, when the player is elected (decided to shift) to the advantageous section, the section may be uniformly shifted to the advantageous section of 1500 games, which is the upper limit.
In this case, the value of "_NB_CND_AT" is, for example, "00000000000 (B)" in the normal section and "00000001 (B)" in the advantageous section. Thereby, it is possible to manage whether it is a normal section or an advantageous section with 1-bit data.

Further, in the game of the advantageous section, the conditions for falling to the normal section (for example, the number of executed games of ART has reached a specific value, the fall lottery has been won, the predetermined number of games have been executed, etc.) are satisfied. At that time, it may be possible to shift to the normal section.
Further, for example, three types of advantageous sections 1 to 3 may be provided as advantageous sections, and it may be determined which of the advantageous sections 1 to 3 is shifted to in the normal section. Then, if the advantageous section 1 is won, it shifts to the advantageous section of 500 games, if it wins the advantageous section 2, it shifts to the advantageous section of 1000 games, and if it wins the advantageous section 3, it shifts to the advantageous section of 1500 games. May be good.

(2) In the 16th to 19th embodiments, it is determined whether or not to add the number of games in the advantageous section. However, it is not limited to this.
For example, in the case where ART is executed during the advantageous section, when the winning number corresponding to the addition of the advantageous section is determined, the number of games that can execute ART during the advantageous section is increased uniformly or by lottery. You may let me.

In addition, for example, in the case of executing a Gase game (a game state in which the advantageous section display LED 77 is lit, although there is no right to shift to ART) during the advantageous section, the winning corresponding to the addition of the advantageous section is performed. When the number is decided, the right to move to ART may be granted uniformly or by lottery.
In this way, instead of adding the number of games in the advantageous section, the gaming state (performance of the advantageous section) in the advantageous section may be changed so as to be advantageous to the player.

(3) In the normal section, when the player wins (decides to shift) to the advantageous section, he / she may shift from the next game to the advantageous section, or shifts from the next game to the standby section, and then shifts to the standby section. May shift to an advantageous section.
That is, in the 16th to 19th embodiments, "winning in the advantageous section" is not limited to shifting from the next game to the advantageous section, but shifting from the next game to the waiting section, and then from the waiting section. It is a concept that includes shifting to an advantageous section.
Further, when shifting from the normal section to the standby section, information indicating that the standby section is stored is stored in a predetermined storage area of the RWM53, and when shifting from the standby section to the advantageous section, information indicating that the section is advantageous is stored. May be stored in a predetermined storage area of the RWM 53.

(4) In the 16th to 19th embodiments, when the value of bit 2 of "_FL_ACTION" is "1", it means that the accessory is operating, and when it is "0", it means that the accessory is not operating. I showed that.
Further, when the value of "_NB_CND_BNS" is "0", it indicates that the character condition device has not been won, and when it is other than "0", it indicates that the character condition device has been won.
Furthermore, when the value of "_NB_CND_AT" is "0", it indicates that the player has not won the advantageous section (decided to shift), and when the value is "1", it indicates that the player has won the advantageous section 1. , "2" indicates that the player has won the advantageous section 2.

Further, when the value of "_FL_PRD_LOT" is "FF (H)", it indicates that the internal internal flag is on, and when it is "0", it indicates that the internal internal flag is off.
However, when the accessory is activated / not activated, the value of bit 2 of "_FL_ACTION" is not limited to "1" / "0", and can be set as appropriate.
Similarly, the winning / non-winning of the accessory condition device, the winning / non-winning of the advantageous section, and the on / off of the internal middle flag can be appropriately set without being limited to the above mode.

(5) In the 16th to 19th embodiments, a 1-byte storage area on the RWM53 was secured as "_NB_CND_AT". However, the storage area for storing the advantageous section number is not limited to the 1-byte storage area.
As described above, for example, there is only one type of advantageous section, and in the normal section, it is possible to determine whether or not to shift to the advantageous section. In this case, a specific bit (for example, bit 0) of the 1-byte storage area on the RWM 53 can be used as the storage area for storing the advantageous section number. That is, the 1-bit storage area may be used as a storage area for storing advantageous section numbers or information indicating that the current game section is an advantageous section.

Similarly, "_NB_CND_BNS" is not limited to the 1-byte storage area.
For example, in the 1-byte storage area on the RWM53, a specific bit (for example, bit 0) is used as a storage area for storing an advantageous section number, and a predetermined bit (for example, bit 1) is stored for storing a bonus condition device number. It can be an area.
As a result, the amount of RWM53 used by the program can be reduced.

(6) In the 16th embodiment, when it is determined in step S1043 of FIG. 89 that a value other than "0" is stored in "_NB_CND_BNS", steps S1044 to S1046 are skipped to obtain "_NB_CND_BNS". The value and the value of "_NB_CND_AT" were maintained. However, it is not limited to this.

For example, when "00000001 (B)" is stored in "_NB_CND_BNS" and "00000001 (B)" is stored in "_NB_CND_AT", "00000001 (B)" is overwritten in "_NB_CND_BNS" and "00000001 (B)" is overwritten. By overwriting "00000001 (B)" in "_NB_CND_AT", the value of "_NB_CND_BNS" and the value of "_NB_CND_AT" may be maintained.
As described above, in the 16th to 19th embodiments, when the value of "_NB_CND_BNS" or the value of "_NB_CND_AT" is maintained, the same value is overwritten, not limited to the case of maintaining by skipping (not updating). It may be maintained by doing so.

(7) In the 16th embodiment, the winning numbers are determined as shown in FIGS. 74 (a) and 75 (a). Further, in the 17th embodiment, the winning numbers are determined as shown in FIGS. 74 (a) and 93 (a). Further, in the eighteenth embodiment, the winning numbers are determined as shown in FIGS. 74 (a) and 112 (a). These have the regularity as shown below, and thereby exert the effects as shown below.

A. As shown in FIG. 74 (a), for the winning numbers less than "31", the "winning number" and the "winning and replay condition device number" are defined to match, and "1" to "1" to " The number 30 "is set to be continuous.

In this way, for winning numbers less than a specific value (for example, "31"), the winning number determined by the lottery judgment is determined by setting the "winning number" and the "winning and replay condition device number" to match. When it is determined that the number is less than a specific value, the "winning number" determined by the lottery determination can be used as the "winning and replay condition device number" in a predetermined storage area ("_NB_CND_NOR") of the RWM53. ..
Therefore, since the process of storing the "winning and replay condition device number" in "_NB_CND_NOR" can be simplified, the amount of ROM 54 used by the program can be reduced.

B. As shown in FIG. 74 (a), for the winning numbers less than "31", the "winning number" and the "winning and replay condition device number" are defined to match, and FIG. 112 (a) shows. As shown, for the winning numbers of "31" and above, the lottery result including the character condition device is obtained (single winning of the character condition device, or duplicate winning of the prize condition device and the winning and replay condition device). (To be).
In this way, for winning numbers less than a specific value (for example, "31"), the "winning number" and the "winning and replay condition device number" are set to match, and for winning numbers above the specific value, It can be set so that the result of the lottery includes the accessory condition device.

In this case, it is determined whether or not the winning number determined by the lottery determination is less than a specific value.
Then, when it is determined that the value is less than the specific value, the "winning number" determined by the lottery determination is stored in the predetermined storage area ("_NB_CND_NOR") of the RWM53 as the "winning and replay condition device number".
On the other hand, when it is determined that the value is equal to or higher than a specific value, for example, using the "winning number conversion table" shown in FIG. Acquire the "device number" and the "winning and replay condition device number", respectively. Then, the acquired "feature condition device number" is stored in a specific storage area ("_NB_CND_BNS") of the RWM53, and the acquired "winning and replay condition device number" is stored in a predetermined storage area ("_NB_CND_NOR") of the RWM53. ).

In this way, by separately determining the winning number that matches the winning and replay condition device number and the winning number that is the result of the lottery including the accessory condition device based on the specific value, the winning number that is equal to or higher than the specific value Only the winning number conversion table needs to be determined, so that the amount of ROM 54 used by the winning number conversion table can be reduced.
Further, by determining whether or not the winning number determined by the lottery determination is less than a specific value, it is possible to determine whether or not the winning number requires a winning number conversion table. Therefore, the program Therefore, the amount of ROM 54 used by the program can be reduced.

Further, by determining one winning number based on one random value by the lottery determination, the lottery result that the winning and replay condition device is independently won, the lottery result that the character condition device is independently won, and the lottery result. It is possible to obtain a lottery result that is a duplicate winning of the character condition device and the winning and replay condition device. Therefore, since the lottery determination process (the process of determining the winning number from the random number value) can be simplified, the amount of ROM 54 used by the program can be reduced.

C. As shown in FIG. 75 (a), the winning numbers "34" to "42" are defined so that the processing related to the addition of the advantageous section can be executed.
Further, in FIG. 75A, it is defined that the winning numbers "43" to "52" can be processed for the transition from the normal section to the advantageous section (advantageous section 1 or advantageous section 2). However, when the winning number is determined to be "43" to "52" in the advantageous section, it can be determined so that the process related to the addition of the advantageous section can be executed.

In addition, the addition of the advantageous section means adding (adding, increasing) the number of games of the advantageous section, and adding (adding, increasing) the number of games of ART in the advantageous section when ART is executed during the advantageous section. (Increase), shift to ART during the advantageous section when performing a Gase game (a game state in which the advantageous section display LED 77 is lit, although there is no right to shift to ART). It is a concept that includes making.

In this way, by defining the winning numbers having a predetermined value (for example, "34") or more so that the processing related to the addition of the advantageous section can be executed, the winning numbers determined by the lottery determination are the predetermined values or more. When it is determined that there is, the process related to the addition of the advantageous section can be executed.
Therefore, by determining whether or not the winning number determined by the lottery determination is equal to or greater than a predetermined value, it is possible to determine whether or not to execute the process related to the addition of the advantageous section, which simplifies the program. Therefore, the amount of ROM 54 used by the program can be reduced.

D. As shown in FIG. 75 (a), it is determined that the winning numbers "43" to "52" can be processed for the transition from the normal section to the advantageous section (advantageous section 1 or advantageous section 2). ing.
In addition, if the player wins the advantageous section 1 (decides to shift), he / she shifts to the gaming state of Gase who does not have the right to shift to ART, and if he wins the advantageous section 2, he / she shifts to the gaming state that can shift to ART (ART). It shifts to ART through the precursor).

In this way, for the winning numbers that are equal to or higher than the specified value (for example, "43"), the winning numbers determined by the lottery determination can be determined by stipulating that the processing related to the transition from the normal section to the advantageous section can be executed. When it is determined that the value is equal to or higher than the specified value, the process related to the transition from the normal section to the advantageous section can be executed.
Therefore, by determining whether or not the winning number determined by the lottery determination is equal to or higher than the specified value, it is possible to determine whether or not to execute the process related to the transition from the normal section to the advantageous section. Since the program can be simplified, the amount of ROM 54 used by the program can be reduced.

(8) In the 16th to 19th embodiments, the lottery table common to all RTs (for example, FIGS. 79 to 79) is first used regardless of the RT state (non-RT, RT1, RT2, RT3, or RT4) except when 1BB is operating. The lottery determination was made using FIG. 82 (a)). Then, when the winning number was determined to be "00 (H)" in the lottery determination using the lottery table common to all RTs, the lottery determination was then performed using the lottery table according to the RT state.

Specifically, at the time of non-RT, the lottery determination is performed using the non-RT lottery table (FIG. 82 (b)), and at the time of RT1, the lottery determination is performed using the RT 1:00 lottery table (FIG. 82 (c)). rice field.
Further, at RT2, a lottery determination is made using the RT2 o'clock lottery table (FIG. 83 (a)), at RT3, a lottery determination is made using the RT3 o'clock lottery table (FIG. 83 (b)), and at RT4, RT4 The lottery determination was made using the hour lottery table (FIG. 84 (a)).

Regarding this point, for example, the lottery address table for each RT state (TBL_LOT_RTTBL) as shown below is provided, and the start address of the lottery table according to the RT state is calculated (designated) using this lottery address table for each RT state. be able to.
TBL_LOT_RTTBL:
DEFB TBL_LOTDAT_RT0- $; Non-RT lottery table DEFB TBL_LOTDAT_RT1-$; RT1 o'clock lottery table DEFB TBL_LOTDAT_RT2- $; RT2 o'clock lottery table DEFB TBL_LOTDAT_RT3-

Here, the lottery address table for each RT state can be stored in the ROM 54 of the main control board 50, for example.
Further, "TBL_LOTDAT_RT0" indicates the start address of the non-RT lottery table, and "TBL_LOTDAT_RT1" indicates the start address of the RT1 time lottery table.
Similarly, "TBL_LOTDAT_RT2" indicates the start address of the lottery table at RT2, "TBL_LOTDAT_RT3" indicates the start address of the lottery table at RT3, and "TBL_LOTDAT_RT4" indicates the start address of the lottery table at RT4.

In addition, "$" indicates the current address.
Therefore, "TBL_LOTDAT_RT0- $" indicates the difference (number of data, number of bytes) from the current address to the start address of the non-RT lottery table.
Similarly, "TBL_LOTDAT_RT1-$" indicates the difference from the current address to the start address of the RT1 o'clock lottery table, and "TBL_LOTDAT_RT2-$" indicates the difference from the current address to the start address of the RT1 o'clock lottery table. ..
Further, "TBL_LOTDAT_RT3-$" indicates the difference from the current address to the start address of the RT3 o'clock lottery table, and "TBL_LOTDAT_RT4-$" indicates the difference from the current address to the start address of the RT4 o'clock lottery table.

Further, the information regarding the RT state can be stored in a predetermined storage area (RT state data storage area “_NB_RT”) of the RWM 53, for example.
Further, as information regarding the RT state, any one of "0" to "4" is stored in "_NB_RT".
Specifically, at the time of non-RT, "0" is stored in "_NB_RT", and at the time of RT1, "1" is stored in "_NB_RT".
Further, at RT2, "2" is stored in "_NB_RT", at RT3, "3" is stored in "_NB_RT", and at RT4, "4" is stored in "_NB_RT".

Then, the start address of the lottery table according to the RT state can be calculated (designated) as shown below.
First, "TBL_LOT_RTTBL" is stored in the HL register. As a result, the start address of the lottery address table for each RT state is stored in the HL register.
Next, the value of "_NB_RT" is stored in the A register. As a result, a value indicating the RT state is stored in the A register.

Next, the value of the A register (the value indicating the RT state) is added to the value of the HL register (the start address of the lottery address table for each RT state) to obtain a new HL register value. As a result, the address of the "address designation data" corresponding to the RT state is stored in the HL register.
Here, the "address designation data" is data stored in the lottery address table for each RT state, and is data for calculating (designating) the start address of the non-RT lottery table to the RT4 o'clock lottery table. ..
Specifically, "TBL_LOTDAT_RT0- $" is address designation data for calculating (designating) the start address of the non-RT lottery table.

Similarly, "TBL_LOTDAT_RT1-$" is the address designation data for calculating (designating) the start address of the lottery table at RT1 o'clock, and "TBL_LOTDAT_RT2-$" calculates (designates) the start address of the lottery table at RT2 o'clock. It is the address specification data to do.
Further, "TBL_LOTDAT_RT3-$" is address designation data for calculating (designating) the start address of the lottery table at RT3, and "TBL_LOTDAT_RT4-$" calculates (designates) the start address of the lottery table at RT4. Address specification data for.

Next, the data (address designation data) corresponding to the address indicated by the HL register is stored in the A register. As a result, "address designation data" corresponding to the RT state is stored in the A register.
Next, the value of the A register is added to the value of the HL register to obtain a new HL register value. As a result, the start address of the lottery table according to the RT state is stored in the HL register.

Here, the start address of the lottery address table (TBL_LOT_RTTBL) for each RT state is set to "1500 (H)". In this case, the address of the "DEFB TBL_LOTDAT_RT0- $; non-RT lottery table" is also "1500 (H)".
Further, the address of the "DEFB TBL_LOTDAT_RT1-$; RT1 o'clock lottery table" is set to "1501 (H)", and the address of the "DEFB TBL_LOTDAT_RT2-$; RT2 o'clock lottery table" is set to "1502 (H)".
Further, the address of the "DEFB TBL_LOTDAT_RT3- $; RT3 o'clock lottery table" is set to "1503 (H)", and the address of the "DEFB TBL_LOTDAT_RT4-$; RT4 o'clock lottery table" is set to "1504 (H)".

Further, the start address of the non-RT lottery table (TBL_LOTDAT_RT0) is set to "1505 (H)".
In this case, as shown in FIG. 82 (b), since 5 bytes of data are stored in the non-RT lottery table, the start address of the RT1 lottery table (TBL_LOTDAT_RT1) is "1505 (H)". + "5 (H)" = "150A (H)".
Further, as shown in FIG. 82 (c), 9 bytes of data are stored in the RT1 o'clock lottery table. Therefore, the start address of the RT2 o'clock lottery table (TBL_LOTDAT_RT2) is "150A (H)" + "9 (H)" = "1513 (H)".

Furthermore, as shown in FIG. 83A, 9 bytes of data are stored in the RT2 o'clock lottery table. Therefore, the start address of the RT3 o'clock lottery table (TBL_LOTDAT_RT3) is "1513 (H)" + "9 (H)" = "151C (H)".
Further, as shown in FIG. 83 (b), 10 bytes of data are stored in the RT3 o'clock lottery table. Therefore, the start address of the RT4 o'clock lottery table (TBL_LOTDAT_RT4) is "151C (H)" + "A (H)" = "1526 (H)".

Hereinafter, the calculation (designation) of the start address of the lottery table according to the RT state will be described in more detail, taking RT3 o'clock as an example.
First, the start address = "1500 (H)" of "TBL_LOT_RTTBL" is stored in the HL register.
Next, the value of "_NB_RT" = "3 (H)" is stored in the A register.
Next, the value "3 (H)" of the A register is added to the value "1500 (H)" of the HL register to obtain a new value "1503 (H)" of the HL register.

Next, "TBL_LOTDAT_RT3-$" corresponding to the value "1503 (H)" of the HL register is stored in the A register.
Here, "TBL_LOTDAT_RT3" = "151C (H)".
When the value of the HL register is "1503 (H)", "$" = "1503 (H)".
Therefore, the value stored in the address corresponding to the value "1503 (H)" of the HL register is "19 (H)" (= "151C (H)"-"1503 (H)"). “19 (H)” is the value of the A register.

Next, the value "19 (H)" of the A register is added to the value "1503 (H)" of the HL register to obtain a new HL register value.
Here, "1503 (H)" + "19 (H)" = "151C (H)".
Therefore, the value of the new HL register becomes "151C (H)".
Then, the value "151C (H)" of the HL register indicates the start address of the RT3 o'clock lottery table (TBL_LOTDAT_RT3).
In this way, the start address of the lottery table according to the RT state can be calculated (designated) based on the values of the lottery address table for each RT state (TBL_LOT_RTTBL) and the RT state data storage area "_NB_RT".

The lottery address table for each RT state defines which of the lottery tables (non-RT lottery table to RT4 o'clock lottery table) is used according to the RT state, and the non-RT lottery table to RT4 o'clock. "Address designation data" for calculating (designating) the start address of the lottery table is defined.
Therefore, the lottery address table for each RT state may also be referred to as an "address designation data selection table", an "address designation data table", or the like.

Further, the two-stage lottery address table of the seventeenth embodiment determines which of the two-stage lottery tables 1 to 5 is used, and calculates (designates) the start address of the two-stage lottery tables 1 to 5. "Addressing data" for this is defined.
Therefore, the two-stage lottery address table may also be referred to as an "address designation data selection table", an "address designation data table", or the like, similarly to the lottery address table for each RT state.

It is also possible to specify the start address of the lottery table according to the RT state from the value indicating the RT state without using the lottery address table for each RT state.
However, in this case, first, it is determined whether or not the value indicating the RT state is "0", and when it is determined that it is "0", it is "1505 (H)" which is the start address of the non-RT lottery table. When is specified and it is determined that it is not "0", then it is determined whether or not the value indicating the RT state is "1".

When it is determined that the value indicating the RT state is "1", "150A (H)" which is the start address of the lottery table at RT1 is specified, and when it is determined that it is not "1", the next , It is determined whether or not the value indicating the RT state is "2".
Furthermore, when it is determined that the value indicating the RT state is "2", "1513 (H)" which is the start address of the lottery table at RT2 is specified, and when it is determined that it is not "2", the next In addition, it is determined whether or not the value indicating the RT state is "3".

Furthermore, when it is determined that the value indicating the RT state is "3", "151C (H)" which is the start address of the lottery table at RT3 is specified, and when it is determined that it is not "3", it is RT4 o'clock. The start address of the lottery table, "1526 (H)", is specified.
Since such processing is performed, it takes a long time to specify the start address of the lottery table according to the RT state.
In addition, a program for designating the start address of the lottery table according to the RT state is also required.

On the other hand, if the start address of the lottery table according to the RT state is specified by using the lottery address table according to the RT state, the process until the start address of the lottery table according to the RT state can be specified can be shortened. At the same time, it is not necessary to define a program for designating the start address of the lottery table according to the RT state, so that the amount of ROM 54 used by the program can be reduced.

(9) In the 16th to 19th embodiments, the lottery table common to all RTs (for example, FIGS. 79 to 79) is first used regardless of the RT state (non-RT, RT1, RT2, RT3, or RT4) except when 1BB is operating. The lottery determination was made using FIG. 82 (a)). Then, when the winning number was determined to be "00 (H)" in the lottery determination using the lottery table common to all RTs, the lottery determination was then performed using the lottery table according to the RT state. However, it is not limited to this.
For example, except when 1BB is operating, the lottery determination may be made first using the lottery table according to the RT state. Then, when the winning number is determined to be "00 (H)" in the lottery determination using the lottery table according to the RT state, the lottery determination may be performed using the lottery table common to all RTs. ..

(10) In the 16th to 19th embodiments, when "0" is stored in "_NB_CND_AT" (storage area of the advantageous section number) at the start of the game this time, a lottery regarding the transition from the normal section to the advantageous section is made. When the player was elected (decided to move to the advantageous section), a value other than "0" was stored in "_NB_CND_AT". That is, the value of "_NB_CND_AT" was updated. However, it is not limited to this.
For example, even if a value other than "0" is stored in "_NB_CND_AT" at the start of the game this time, an additional advantageous section is added (the performance is changed so that the gaming state in the advantageous section is advantageous to the player, or the performance is changed. A lottery regarding (including adding the number of AT games in the advantageous section) may be executed, and the value of "_NB_CND_AT" may be changed according to the result.

For example, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" (storage area of the accessory condition device number) is "0", a lottery for adding an advantageous section may be executed. ..
Further, in a situation where "1" is stored in "_NB_CND_AT" and the value of "_NB_CND_BNS" is "0", a lottery for adding an advantageous section is executed, and "2" is set in "_NB_CND_AT" according to the result. You may execute the control process which memorizes.
When the value of "_NB_CND_BNS" is "1" (so-called internal), the lottery for adding the advantageous section is not executed.

(11) For example, as shown in FIG. 79, in the 16th to 19th embodiments, lottery data relating to the accessory condition device (1BBA, 1BBB, etc.) is set in the lottery table common to all RTs.
However, the present invention is not limited to this, and the lottery data relating to the accessory condition device may not be defined in the lottery table common to all RTs, but may be defined only in the lottery table according to the RT state.
More specifically, since the RT4 o'clock lottery table is the lottery table used in RT4 (inside), the lottery data related to the accessory condition device is not defined in the all RT common lottery table and the RT4 o'clock lottery table. It may be specified only in the RT1 o'clock lottery table, the RT2 o'clock lottery table, and the RT3 o'clock lottery table.

(12) For example, when the probability data is different for each set value, it is preferable to make the number of bytes of each probability data uniform.
For example, in the 1BBA + small winning combination E2 condition device lottery data of the all RT common lottery table (1) of FIG. 79, the probability data is different for each set value. And each probability data is set to 1 byte.
Further, in the small winning combination A condition device lottery data of the lottery table (3) common to all RTs in FIG. 81, the probability data is different for each set value. And each probability data is set to 2 bytes.

In this way, when the probability data is different for each set value, each probability data is set to 1 byte or set to 2 bytes so that the 1-byte probability data and the 2-byte probability data are mixed. Do not set to.
As a result, the lottery determination process can be simplified, so that the amount of ROM 54 used by the program can be reduced.

(13) In the 16th to 19th embodiments, the range of "0" to "65535" is set as one cycle, a counter that counts 1 in 200 n (nano) sec is provided, and the count value of this counter is set as a random value. ..
However, the present invention is not limited to this, and for example, a value obtained by calculating (for example, adding or subtracting) a predetermined value (for example, another random value or a specific value) with respect to the count value obtained from the counter may be used as a random value. good.

(14) In the 16th to 19th embodiments, the carry flag is turned on (“1”) by storing the random number value in a predetermined register and subtracting the probability data from the value of the predetermined register (“1”). It was judged whether or not the carry occurred), and when the carry flag was turned on, it was judged that the player was elected.
However, not limited to this, for example, by storing a random number value in a predetermined register and adding probability data to the value of this predetermined register, it is possible to determine whether or not the carry flag is turned on. good.

Then, when the carry flag is turned on, it is judged that the player has won.
On the other hand, when the carry flag is not turned on, the value obtained by adding the probability data to the value of the predetermined register is stored as the value of the new predetermined register. That is, the value of a predetermined register is updated. After that, by adding new probability data to the value of the predetermined register after the update, it is repeated to determine whether or not the carry flag is turned on until the carry flag is turned on.
From the above, determining whether or not a player has won based on the value stored in a predetermined register and the probability data may be referred to as a comparison operation.

(15) How to determine the winning number shown in the 16th to 19th embodiments, how to determine the conditional device number, the correspondence relationship between the winning number and the conditional device number, and the correspondence between the conditional device number and the conditional device (winning combination). Relationship, type of condition device (winning combination) corresponding to the winning number, correspondence relationship between the winning number and probability data, probability data to win (decide to shift) to the advantageous section, win (shift) to the advantageous section The winning number to be determined), the winning number to be won (decided to be added) to the addition of the advantageous section, etc. are merely examples, and can be appropriately set according to the game content.
For example, when winning the 1BBA condition device, there is a 100% probability that the advantageous section will be won (decided to shift), and when the predetermined winning number is won, there is a 100% probability that the advantageous section will be won. Probability data and the like can be determined as described above.

(16) In the flowcharts shown in the 16th to 19th embodiments, the order of processing is not limited to the order shown in the figure, and when the order of processing can be changed, the order of processing is changed. Is also possible.
(17) In the 16th to 19th embodiments, the lottery relating to the transition from the normal section to the advantageous section has been described, but the lottery other than the lottery relating to the transition from the normal section to the advantageous section (for example, the lottery of the combination, the condition device). It can also be applied to lottery, AT lottery, RT transition lottery).
(18) In the 16th to 19th embodiments, the slot machine 10 is taken as an example of the gaming machine, but it can also be applied to a bullet gaming machine, an enclosed gaming machine, and the like.
(19) The 16th to 19th embodiments and the various modifications described above are not limited to being carried out individually, but can be carried out in combination as appropriate.

<20th Embodiment>
Subsequently, the twentieth to twenty-fourth embodiments of the present invention will be described.
The twentieth to twenty-fourth embodiments relate to lighting control of LEDs such as the management information display LED 74.
FIG. 124 is a diagram illustrating a more detailed configuration of the main CPU 55, ROM 54, and RWM 53 according to the twentieth embodiment.
As shown in FIG. 1, a main CPU 55, an RWM 53, and a ROM 54 are provided on the main control board 50.

More specifically, as shown in FIG. 20, a one-chip microprocessor (hereinafter, simply referred to as a “chip”) is mounted on the main control board 50, and the main is contained in the chip. It is equipped with a CPU 55. Further, the main CPU 55 has a built-in memory, and the built-in memory has a (built-in) ROM 54 and a (built-in) RWM 53. The addresses of ROM 54 and RWM 53 are continuous.

The storage capacity of the ROM 54 is set to "16 KB or less" in this embodiment, and has a used area having a capacity of "7.5 KB or less" and an outside of the other used area. Further, the used area has a control area having a capacity of "4.5 KB or less" and a data area having a capacity of "3.0 KB or less".
Here, the "used area" refers to a storage area in which information other than the information necessary for preventing unauthorized modification or other changes is stored or is to be stored (the same applies to the ROM 54 and RWM 53).
Further, the "control area" refers to a storage area other than the data area in the used area, and various programs executed by the main control means 50 are stored. The control area may be referred to as a "program area".
Furthermore, the "data area" refers to a storage area in which only information other than the program is stored or is to be stored, and data used when the program is executed is stored.

Further, "outside the used area" includes a control area and a data area as well as the used area. The control area of the used area may be referred to as a first control area, and the control area outside the used area may be referred to as a second control area. A program not related to the progress of the game (for example, a program used at the time of a test, a program for preventing fraud, etc.) is stored in the control area (second control area) outside the use area. This point will be described later.
Further, the storage capacity of the RWM 53 is "1,024 K or less" in the present embodiment, and has a used area having a capacity of "512 KB or less" and an outside of the other used area.
Both the used area and the outside of the used area include a work area and a stack area. An LED display counter or the like, which will be described later, is stored in the used area of the RWM 53.

Furthermore, as shown in FIG. 124, the ROM 54 includes a program management area and the like as other areas in addition to the used area and the outside of the used area.
Further, the RWM 53 includes an unused area and the like as other areas in addition to the used area and the area outside the used area.
Further, among the storage areas of the entire built-in memory, a built-in register area, an unused area, and the like are provided as areas other than the ROM 54 and the RWM 53.
As described above, the built-in register area is provided with, for example, A register to L register, a transmission register, and the like.

FIG. 125 (A) is a diagram showing various LEDs on the display board 75 in the 20th embodiment, and FIG. 125 (B) is a diagram showing the management information display LED 74 in the 20th embodiment more specifically. .. FIG. 125 (A) is a diagram corresponding to FIG. 2 of the first embodiment, and FIG. 125 (B) is a diagram corresponding to the management information display LED 74 shown in FIG. 3 (a) of the first embodiment. ..

In FIG. 125 (A), in the twentieth embodiment, as in the first embodiment, the storage number display LED 76 composed of digit 1 (upper digit) and digit 2 (lower digit) and digit 3 (upper digit). It also includes an acquisition number display LED 78 composed of a digit 4 (lower digit).
However, unlike the first embodiment, the digits 1 to 4 each use a 7-segment display that does not have a dot segment (segment DP (hereinafter, simply referred to as “segment P”)). Therefore, the first digit 1 to 4 uses a 7-segment display. In the embodiment, as shown in FIG. 2, the segment P of the digit 2 does not constitute the advantageous section display LED 77. In the 20th embodiment, the advantageous section display LED 77 is provided separately and independently. , I will omit the explanation about this point.

Further, seven LEDs are mounted on the display board 75, and these seven LEDs are collectively referred to as a status display LED 79.
First, 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 lit. 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 lit.

Further, the game start display LED 79d is an LED that lights up when a medal is inserted and the start switch 41 is in an operable state. Therefore, it does not light up when the medal 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, it lights up before the game is completed and the medal for shifting to the next game is inserted, indicating a so-called bet waiting state. Even after the replay is activated, it lights up when betting is possible according to the number of stored sheets.

The replay display LED 79f is an LED that lights up when the replay wins, and when an automatic bet is made based on the replay winning, the replay display LED 79f lights up to notify the player that the automatic bet state is in effect.
The effect display LED 79g is an LED used when displaying various effects, and may also be used as a settlement display LED (LED that lights up during the settlement process).

In FIG. 125 (B), the four digits 6 to 9 used for the management information display LED 74 are 7-segment displays including dot segments (segments P), unlike the digits 1 to 4 described above. Digits 6 to 9 are the same as those in the first embodiment in that they display the upper information type, the lower information type, the upper numerical value, and the lower numerical value, respectively.
Further, the segment P of the digit 7 (lower information type) functions as a digit grouping display LED. The digit delimiter display LED is used to clarify the delimiter between the information type and the numerical value.

Further, the segment P of the digit 6, the digit 8 and the digit 9 is an LED that lights up when an unrecoverable error occurs. Unlike the digits 1 to 4, the segments P are provided in the digits 6 to 9, but when the segments are physically provided in this way, it is required to turn on the lights at any timing. Therefore, in the present embodiment, when an unrecoverable error occurs, all the segments P of the digits 6 to 9 are controlled to light up.

FIG. 126 is a diagram illustrating details of the digits and segments in the 20th embodiment, and is a diagram corresponding to FIG. 4 of the first embodiment.
In the twentieth embodiment, as described above, the 7-segments of digits 1 to 4 themselves are composed of segments A to G, and no dot segment (segment P) is provided.
However, the segments P of the digits 1, 3, and 4 constitute any one of the above-mentioned status display LEDs 79. As shown in FIG. 126, for example, the segment P of the digit 1 constitutes the game start LED 79d.
Further, the segment P of the digit 3 constitutes the closing display LED 79e.
Furthermore, the segment P of the digit 4 constitutes the replay display LED 79f.

Further, although not shown, in the 20th embodiment, the set value display LED 73 (digit 5) uses a 7-segment display having no dot segment (segment P) as in the digits 1 to 4. Then, the segment P of the digit 5 constitutes 79 g of the effect display LED.
The segment P of the digit 2 is unused in the twentieth embodiment.
Furthermore, the segments P of the digits 6-9 are as described above.

FIG. 127 is a diagram showing a data table stored in the ROM 54. The data table is a table that stores display data and display offset data when the digits 1 to 9 are turned on.
As shown in FIG. 127, the data tables are a data table in the used area stored in the data area of the used area of the ROM 54 (address “1200H ~” in FIG. 124) and a data area outside the used area of the ROM 54 (FIG. FIG. In 124, the data table outside the used area stored at the address “2300H ~”) is provided.

The data table in the used area includes an LED segment table 1 (TBL_SEG_DATA1) and an LED segment table 2 (TBL_SEG_DATA2).
The LED segment table 1 is a table that stores display data (alphabetic character data) used when displaying error information on the acquired number display LEDs 78 (digits 3 and 4).
Further, the LED segment table 2 is a table that stores numerical display data and data for displaying "=" when displaying push order instruction information.
In FIG. 127, “DEFB” refers to storing 1-byte (8-bit) data in the assembler language.

In FIG. 127, for example, the “C” display data is “00111001B”. That is, the segments A, D, E, and F are "1 (on; lighting)", and the segments B, C, and G are "0 (off, turning off)". Therefore, in FIG. 126, when the segments A, D, E, and F are turned on, "C" is displayed by the 7-segment display.
The "=" display data is "01001000B". That is, in FIG. 126, the segments D and G are "1 (on; lit)", the horizontal segments in the center and the lower part are lit, and "=" is displayed by the 7-segment display.

The LED segment table 1 (TBL_SEG_DATA1) and the LED segment table 2 (TBL_SEG_DATA2) are stored in consecutive addresses. For example, assuming that the start address of the "C" display data is "1811", each display data of the LED segment table 1 is stored in order from this "1811". In this case, the start address of the LED segment table 2 is "1816", and each display data of the LED segment table 2 is stored in order from this "1816".

Thereby, each display data of the LED segment table 1 can be represented by an offset value from the start address "1811". Similarly, each display data of the LED segment table 2 can be represented by an offset value from the start address "1816".
For example, when reading the display data of the LED segment table 2, the start address "1816" is specified, and when the content to be displayed is "5", the address obtained by adding the offset value "5" to the start address "1816". That is, if the data of "181B" is read, the "5" display data can be read.

On the other hand, the out-of-use data table is a data table that stores data for displaying the management information display LEDs 74 (digits 6 to 9), and is an identification segment offset table (TBL_SEGID_DATA) and a ratio display segment data table (TBL_SEGRATE_DATA). ) And. The identification segment offset table and the ratio display segment data table are stored in consecutive addresses as in the LED segment tables 1 and 2 described above.
The "identification segment" is used as an abbreviation for "information type".

Further, in the identification segment of the 20th embodiment, English characters and numerical values are set in reverse for the information type shown in FIG. 38.
In particular,
Advantageous section ratio: U7 → 7U
Continuous character ratio (6000 games): y6 → 6y
Character ratio (6000 games): y7 → 7y
Continuous character ratio (cumulative): A6 → 6A
Character ratio (cumulative): A7 → 7A
And.

For example, the display offset data of "7U" indicating the identification segment of the advantageous section ratio is "07AH" as shown in FIG. 127, but "7" indicates the offset value of the upper digit (digit 6; 1000 digits). , "A" indicates the offset value of the lower digit (digit 7; 100 digits). Further, the offset value here indicates an offset value from the start address of the ratio display segment data table.
Therefore, the offset value "7" specifies the "7" display data (for the ratio), and the offset value "A" specifies the "U" display data.
The display data is different in order to distinguish between the "7" displayed on the management information display LEDs 74 (digits 6 to 9) and the "7" displayed on the digits 1 to 5. “7” displayed on the digits 6 to 9 is data defined in FIG. 126 so as to light the segment F (the fifth bit is set to “1”).

As described above, the numerical display data is the same as the LED segment table 2 except for the “7” display data. Nevertheless, the reason why the data table in the used area and the data table outside the used area are stored separately is as follows.
It is the control performed within the used area that controls the lighting display of the stored number display LED76 (digits 1 and 2), the acquired number (or error) display LED78, and the set value display LED73 (digit 5). Therefore, the control data performed in the used area is stored in the data area in the used area.
On the other hand, controlling the lighting display of the management information display LED 74 (digits 6 to 9) is a control performed outside the used area. Therefore, the control data performed outside the used area is stored in the data area outside the used area.

FIG. 128 is a diagram showing output ports 2 to 5 provided on the main control board 50 and each signal in the 20th embodiment. In FIG. 128, the left column is the 20th embodiment, and the right column is also described as a “reference example” before the present invention.
The "reference example" is an example when the digits 6 to 9 are not provided, and is an example described for comparison with the twentieth embodiment, and means a known technique or a well-known technique for the present invention. It's not a thing.
Further, in FIG. 128, the output ports are shown as output ports 2 to 5, but in reality, more output ports are provided. The illustration of other output ports is omitted (the same applies to the drawings of output ports of other embodiments).
As shown in FIG. 1 of the first embodiment, the main control board 50 is provided with an input port 51 and an output port 52.

Examples of the input port 51 include input ports 0 to 2 (actually, other input ports are also provided).
The input port 0 is a port to which the signals of the settlement switch 46, the bet switch 40, the start switch 41, and the stop switch 42 are input.
Further, the input port 1 is a port to which signals such as a passage sensor 43a, a setting key switch 12, a setting switch 13, a reset switch 14, and a (left, middle, right) reel sensor 39 are input.
Furthermore, signals such as a power failure signal (a signal output when a power failure occurs), an input sensor 44, and a payout sensor 37 are input to the input port 2.

Then, as information processing for advancing the game, a main process performed once per game is provided. In the main process, the inserted medals are detected, and the winning process after all reels 31 are stopped is performed.

During this main processing, the main processing is temporarily exited and interrupt processing (timer interrupt processing) is executed (FIG. 133; I_INTR described later). Then, in the interrupt process, a process of detecting the input ports 0 to 2 (step S1407 in FIG. 133) is executed, and after the process is executed, a process of returning to the main process is periodically performed. The interval of the interrupt time is 2.235 ms in this embodiment. That is, the data of the input ports 0 to 2 is acquired for each interrupt process at 2.235 ms intervals.

Then, based on the acquired data, for each of the input ports 0 to 2, the level data (data indicating on / off of each bit) and the rising data of the input port (the previous interrupt was off and the current interrupt is on). Generates data indicating which bit the data has become (data indicating which bit the data has become) and data indicating the falling edge of the input port (data indicating which bit the data was turned on at the time of the previous interrupt and turned off at the time of the interrupt this time). And remember. Therefore, these data are updated every 2.235 ms.

As the output port, for example, output ports 0 to 10 are provided. Of these output ports, FIG. 128 illustrates output ports 2 to 5 related to the twentieth embodiment.
The feature of the output port of the twentieth embodiment is that there are two output ports (digit ports) for transmitting digit signals (output ports 2 and 4) and one output port (segment port) for transmitting segment signals. (Output port 3).

First, the output port 2 is a port that outputs three bet display signals and digit 1 to 5 signals. The 1-bet display signal to the 3-bet display signal are signals for lighting the 1-bet display LED 79a to the 3-bet display LED 79c, respectively.
Further, the digit 1 signal to the digit 5 signal are drive signals of the digit 1 to the digit 5, respectively.
For example, when the signal of "01111001" is output from the output port 2, it means that the drive signals of digits 1 to 4 and the 1-bet display signal are output.

The output port 3 is a port that outputs the segment A signal to the segment P signal. For example, as shown in FIG. 127, when "0" is displayed, "001111111" is output.
The segment signal of the output port 3 is a segment signal that also serves as all of the digits 1 to 9.
The output port 4 is a port that outputs a drive signal of the digit 6 signal (D0) to the digit 9 signal (D3).
Therefore, which digit is lit by the signal output from the output port 2 or 4, and which segment is lit by the signal output from the output port 3 is determined.

Here, the output port of the present embodiment can output signals of two consecutive output ports (1 byte each, 2 bytes in total) at one time. Therefore, the signals of the output ports 2 and 3 can be output at the same time, and the signals of the output ports 3 and 4 can be output at the same time. Therefore, the output port 2 and the output port 4 are used as output ports for the digit 1 to 5 signals and the digit 6 to 9 signals, respectively, and the output port 3 in between is set as the output port for the segment signal. ..

As a result, for example, when outputting a signal displaying digit 1 as "1", the signal output from the output port 2 becomes "00001000 (assuming that the signal other than digit 1 signal is" 0 ")", and the output port. The signal output from 3 is "00000011". Therefore, “00001000/0000110” (“/” indicates the boundary between the signal output from the output port 2 and the signal output from the output port 3) is output from the output ports 2 and 3.

An external (outer end) signal to the external centralized terminal plate 100 is output from the output port 5, and in the present embodiment, external signals 1 to 5, a data strobe signal, a medal insertion signal, and a medal payout signal are output.
Here, the "external signal" is a signal to be output to the outside of the slot machine 10 (such as a hall computer 200 or a data counter installed in a hall) via the external centralized terminal plate 100. Specifically, for example, an AT, a specific RT, an external signal 1 to 3 indicating that a specific special game is in progress, an external signal 4 indicating that an error or power failure has occurred in the slot machine 10, a slot, or the like. An external signal 5 indicating that the front door of the machine 10 is open is provided.

The data strobe signal is a signal transmitted to the sub control board 80. When the sub control board 80 receives the data strobe signal, the sub control board 80 controls to acquire the sub control data signal from the buffer provided in the sub control board 80 based on the rising edge of the data strobe signal.
From the output ports other than the output ports 2 to 5 described above, for example, the signal of the motor 32, the signal of the blocker 45, the drive signal of the hopper motor 36, the condition device signal (so-called winning number), the sub-control data signal, the test signal, etc. It is output.

129 to 131 are circuit diagrams showing wiring of electric signals of the main control board 50, the display board 75, digits 1 to 9, and the status display LED 79.
129 and 130 show the wiring of the electric signal on the main control board 50, and FIG. 131 shows the wiring of the electric signal on the display board 75.
As shown in FIG. 125, the digits 1 and 2 constituting the stored number display LED 76, the digits 3 and 4 constituting the acquired number display LED 78, and the seven status display LEDs 79 are mounted on the display board 75. There is. On the other hand, the set value display LED 73 (digit 5) and the management information display LED 74 (digits 6 to 9) are mounted on the main control board 50 as shown in FIG. 3 of the first embodiment.

As shown in FIG. 129, a main CPU 55 and three ICs (IC2, IC3 and IC4) are mounted on the main control board 50. Although the main control board 50 is actually provided with ICs other than these three, the illustration is omitted in the present embodiment.
The output from the D0 to D7 output terminals of IC2 to IC4 continues until the input of the clock input terminal is turned from on to off.

The IC 2 is an IC related to the control of the bet display signal and the digit 1 to 5 signals, and the IC 3 is an IC related to the control of the segment signal. Further, the IC4 is an IC related to the control of the digit 6 to 9 signals.
Each of IC2 to IC4 is provided with a clock signal input terminal. On the other hand, the main CPU 55 has XCS2, XCS3, and XCS4 output terminals, the XCS2 output terminal and the IC2 clock input terminal are connected, the XCS3 output terminal and the IC3 clock input terminal are connected, and the XCS4 output terminal is connected. Is connected to the clock input terminal of the IC4.

Further, the main CPU 55 has D0 to D7 output terminals. Then, the D0 to D7 input terminals of the IC2 and the D0 to D7 output terminals of the main CPU 55 are connected.
Furthermore, the D0 to D7 output terminals of the main CPU 55 and the D0 to D7 input terminals of the IC3 are connected, respectively.
Further, the D0 to D3 output terminals of the main CPU 55 and the D0 to D3 input terminals of the IC4 are connected, respectively. The D4 to D7 input terminals of the IC4 are connected to the ground.

The IC 2 has an output port 2 (see FIG. 128) composed of D0 to D7 output terminals, and the D0 to D7 input terminals and the D0 to D7 output terminals correspond to each other. Then, 1-bet display signal lines to 3-bet display signal lines are output from the D0 to D2 output terminals, respectively, and in FIG. 131, the 1-bet display signal line (terminal 16) and the 2-bet display signal line (17) of the display board 75 are output. Terminal)), connected to the 3-bet display signal line (terminal 18).
Further, among the output ports 2, digit 1 signal lines to digit 5 signal lines are output from the D3 to D7 output terminals, respectively, and these five signal lines are the display board 75 (terminals 3 to 7 in FIG. 131). The digit 5 signal line is connected to the drive signal line of the digit 5 (set value display LED 73) mounted on the main control board 50.

Further, the IC 3 has an output port 3 (see FIG. 128) composed of D0 to D7 output terminals, and the D0 to D7 input terminals and the D0 to D7 output terminals correspond to each other. Then, the segment A signal line to the segment P signal line are output from the D0 to D7 output terminals, respectively, and these signal lines are firstly connected to the respective segments A to P of the digit 5, and secondly, the digit. Each of 6 to 9 is connected to segments A to P (FIG. 130), and thirdly, it is connected to a display board 75 (terminals 8 to 15 in FIG. 131).
Furthermore, the IC 4 has an output port 4 (see FIG. 128) composed of D0 to D3 output terminals, and the D0 to D3 input terminals and the D0 to D3 output terminals correspond to each other. As shown in FIGS. 128 and 129, the D4 to D7 output terminals of the output port 4 are unused (NC).

Then, the digit 6 signal line to the digit 9 signal line are output from the D0 to D3 output terminals, respectively, and these signal lines are connected to the drive signal lines of the digits 6 to 9, respectively.
In FIG. 129, for example, the signal lines emitted from the D0 to D2 output terminals of the output port 2 and the signal lines emitted from the D0 to D7 of the output port 3 pass through transistors and resistors to the digit and the display board 75, respectively. Although connected, in FIG. 129, these transistors and resistors are not shown.

In FIG. 130, the digit 6 signal to the digit 9 signal are connected to the drive signal lines of the digits 6 to 9, respectively.
Further, each of the digits 6 to 9 has eight LEDs (LEDs constituting the segments A to G and P). Then, the LEDs constituting the segments A to G and P of the digits 6 to 9 are connected to the segments A to G and P signal lines, respectively.

As shown in FIG. 131, the display board 75 is provided with digits 1 to 4. The output terminals (terminals 3 to 6) of the digit 1 signal line to the digit 4 signal line of the display board 75 and the drive signal lines of the digits 1 to 4 are connected to each other.
Further, each of the digits 1 to 4 has 7 LEDs (LEDs constituting the segments A to G) as in the case of the digit 5 described above. The LEDs of the segments A to G of the digits 1 to 4 are connected to the output terminals (terminals 8 to 14) of the segment A to G signal lines, respectively.

Further, as shown in FIG. 131, the display board 75 has seven LEDs (see FIG. 125) constituting the status display LED 79, specifically, a 1-bet display LED 79a, a 2-bet display LED 79b, and a 3-bet display LED 79c. , The game start display LED 79d, the input display LED 79e, the replay display LED 79f, and the effect display LED 79g are provided.

Then, the game start display LED 79d, the input display LED 79e, the replay display LED 79f, and the effect display LED 79g are connected to the output terminal (15th terminal) of the segment P signal line.
Further, the game start display LED 79d is connected to the output terminal (terminal 3) of the digit 1 signal line, the input display LED 79e is connected to the output terminal (terminal 5) of the digit 3 signal line, and the replay display LED 79f is a digit 4 signal. It is connected to the output terminal (terminal 6) of the wire, and the effect display LED 79g is connected to the output terminal (terminal 7) of the digit 5 signal line.

Further, as shown in FIG. 131, the output terminals (terminals 16 to 18) of the 1-bet to 3-bet display signal lines of the display board 75 are connected to the 1-bet to 3-bet display LEDs 79a to 79c, respectively. There is. Further, the + 5V power supply voltage terminals (terminals 1 and 2) of the display board 75 and the 1-bet to 3-bet display LEDs 79a to 79c are connected.

In the above configuration, in FIG. 129, the main CPU 55 normally applies a high level (about 5 V; the same applies hereinafter) voltage to the XCS2 to XCS4 output terminals, and has a high level to a low level (almost zero V). When (the same applies hereinafter) is set (the voltage is changed by a switch (circuit) provided in the main CPU 55), the voltage becomes active. For example, if you want to drive (select, specify) IC2, activate the XCS2 output terminal. As a result, the active signal (chip select signal) is output from the XCS2 output terminal and input to the clock input terminal of the IC2. As a result, the IC2 is in the driving state (also referred to as the selected state or the designated state). If the XCS3 and XCS4 output terminals are activated in the same manner as described above, the IC3 and IC4 are put into the driving state, respectively.

Further, a low level voltage is normally applied to the D0 to D7 output terminals of the main CPU 55, and a high level voltage is applied when the data (data signal) of "1" is output.
For example, when the data signal of "1" is output from the D0 output terminal of the main CPU 55, the data signal is input to the D0 input terminals of IC2 and IC4, respectively. At this moment, when the XCS2 output terminal is active, IC2 The data signal is input to the D0 input terminal of.

Furthermore, a high level voltage is normally applied to the output port 2 of the IC 2, and a low level voltage is applied to the output terminal corresponding to the input terminal to which the data signal is input. For example, when the data signal of "1" is output from the D7 output terminal of the main CPU 55 and the XCS2 output terminal is active at this moment, the data signal is input to the D7 input terminal of the IC2. Then, when the D7 output terminal of the IC2 is set to a low level, current can flow through the LEDs of segments A to G of the digit 5.

Furthermore, when the data signal of "1" is output from the D0 and D1 output terminals of the main CPU 55 and the XCS3 output terminal is activated, the data signal is input to the D0 and D1 input terminals of the IC3.
A high level voltage is normally applied to the output port 3 of the IC3. When a high level voltage is applied, the circuits after the transistor (not shown) in FIG. 129 have high impedance (neither low nor high).

Then, when the D0 and D1 output terminals of the IC3 are set to the low level, a current flows from the emitter of the transistor connected to the high level (+ 5V) to the collector as the current changes between the emitter and the base, and the current flows to the segment A and B signal lines. Current flows.
Therefore, as described above, when the D7 output terminal of the IC2 is set to a low level and a current can flow through the LEDs of the segments A to G of the digit 5, the IC3 D0 and D1 are described as described above. When the output terminal is set to the low level, a current flows through the signal lines of the segments A and B, and the LEDs of the segments A and B of the digit 5 are turned on.

In other words, although current flows through the segment A and B signal lines of all digits, a voltage of about 5 V is applied to the digits other than digit 5, so no potential difference occurs and digits 1 to 4 and 6 to 9 occur. The LEDs of segments A and B corresponding to are not lit. That is, the current flows only to the digit 5 to which about 0 V is applied, and the LEDs of the segments A and B of the digit 5 are turned on.

Further, for example, the D3 output terminal (digit 1 signal) of the IC2 is set to a low level.
Further, when the D7 output terminal (segment P signal) of the IC3 is set to a low level, a current flows from the emitter connected to the high level to the collector and a current flows through the segment P signal line as the current between the emitter and the base changes. As a result, in FIG. 131, the game start display LED 79d lights up.

In other words, although current flows through the segment P signal lines of all digits, a voltage of about 5 V is applied to the digits other than digit 1, so no potential difference occurs and the digits other than digit 1 are associated with each other. The input display LED 79e, the replay display LED 79f, and the effect display LED 79g are not lit. That is, the current flows only to the digit 1 to which about 0V is applied, and the game start display LED 79d associated with the digit 1 is turned on.

Further, a low level voltage is normally applied to the D0 to D7 output terminals of the output port 2 of the IC2. Then, when a high level voltage is applied to any of the D0 to D2 output terminals of the IC2, a current flows from the collector of the transistor to the emitter, and the collector side of the transistor becomes a low level.
On the other hand, as shown in FIG. 131, a high level voltage is constantly applied to the power supply voltage terminals (terminals 1 and 2) connected to the upstream side of the 1-bet to 3-bet display LEDs 79a to 79c. There is. Therefore, in FIG. 129, for example, when the D0 output terminal of the IC2 is set to a high level, the 16th terminal of the 1-bet display signal becomes a low level in FIG. 131, a current flows through the 1-bet display LED 79a, and the 1-bet display LED 79a lights up. do.

In the present embodiment, only one of the digits 1 to 9 is set to be lit. Here, in order to enable lighting of all the digits individually, it is necessary to provide independent wiring for each digit and each segment. However, when set in this way, the number of wires increases, the cost increases, and the assembly load also increases.
On the other hand, as shown in FIGS. 129 to 131, for example, in the case of a segment A signal, the number of wires can be reduced if the circuit configuration is connected to the segment A signals of all the digits 1 to 9.

Even in the circuit configuration as in the present embodiment, if the digits to be turned on are sequentially switched for each interrupt process, it is substantially the same as the state in which all the digits are turned on at the same time (human visual observation shows that they are turned on at the same time). You can make it look like you are doing it.
Further, if the LED to be turned on is different for each interrupt process, power consumption can be suppressed and LED burn-in can be suppressed.
Further, the brightness can be increased by repeating the point emission as compared with the LED which is always lit.

FIG. 132A is a diagram showing the relationship between the interrupt, the LED display counter (_CT_LED_DSP), and the output signal in the 20th embodiment.
Further, FIG. 3B is a diagram showing an LED display request flag (_FL_LED_DSP).
As described above, in the present embodiment, the interrupt processing is executed once every 2.235ms in parallel with the main processing.
On the other hand, a storage area of the LED display counter is provided at a predetermined address of the used area of the RWM53. The LED display counter is 1-byte data and is a counter that is continuously updated for each interrupt.

The LED display counter of the twentieth embodiment takes a value of "00000001" as an initial value. Then, each interrupt process is updated by shifting the bit "1" to the left by one digit. When this update is continued, in FIG. 132, when the interrupt “8” is changed to “9”, the bit “1” overflows and becomes “0000000000”. When the LED display counter value becomes "00000000000", the LED display counter initialization process is executed in the next interrupt process. This initialization process is to set "1" in the D0 bit, that is, to set the LED display counter to "00000001". Therefore, as shown in FIG. 132, each interrupt process is continuously updated in the order of "1"-> "2"-> ...-> "9"-> "1"-> .... Therefore, the LED display counter is a counter with 9 interrupts per cycle.

First, when the LED display counter value is "00000001", the output signals are the 1-bet display signal and the digit 6 signal, so that the 1-bet display LED 79a and the digit 6 are to be lit (this). At this point, the LED display request flag described later is not considered (the same applies hereinafter). Therefore, in the interrupt processing when the LED display counter value becomes "00000001", the signal of "00000001" is output from the output ports 2 and 4. As a result, the 1-bet display signal is output from the D0 output terminal of the output port 2, and the digit 6 signal is output from the D0 output terminal of the output port 4. Therefore, the 1-bet display LED 79a and the digit 6 can be turned on.

In FIG. 132, "inside the used area" and "outside the used area" are displayed as programs and data for controlling the lighting of the 1-bet to 3-bet display LEDs 79a to 79c and the digits 1 to 5. Is stored in the used area of the ROM 54, and the program and data for controlling the lighting of the digits 6 to 9 are stored outside the used area of the ROM 54. The inside and the outside of the used area are displayed separately.

Similarly, in the interrupt processing when the LED display counter value becomes "00000010", the signal of "00000010" is output from the output ports 2 and 4. As a result, the 2-bet display signal is output from the D1 output terminal of the output port 2, and the digit 7 signal is output from the D1 output terminal of the output port 4. Therefore, the 2-bet display LED 79b and the digit 7 can be turned on. Further, when the digit 7 is lit, the segment P (digit separator display LED) is also lit at all times.
For digits 6, 8 and 9 other than digit 7, segment P is not turned on in interrupt processing. The segment P of these digits is turned on at the time of an unrecoverable error in which interrupt processing is prohibited (details of this point will be described later).

Next, in the interrupt processing when the LED display counter value becomes "00000100", the signal of "00000100" is output from the output ports 2 and 4. As a result, the 3-bet display signal is output from the D2 output terminal of the output port 2, and the digit 8 signal is output from the D2 output terminal of the output port 4. Therefore, the 3-bet display LED 79c and the digit 8 can be turned on.
Further, in the interrupt processing when the LED display counter value becomes "00001000", the signal of "00001000" is output only from the output port 2 (there is no output from the output port 4). As a result, the digit 1 signal is output from the D3 output terminal of the output port 2. Therefore, the digit 1 and the game start display LED 79d corresponding to the segment P of the digit 1 can be turned on.

Furthermore, in the interrupt processing when the LED display counter value becomes "00010000", the signal of "00010000" is output only from the output port 2. As a result, the digit 2 signal is output from the D4 output terminal of the output port 2. Therefore, the digit 2 can be turned on. There is no LED assigned to segment P of digit 2 (FIG. 126).
Further, in the interrupt processing when the LED display counter value becomes "00100000", the signal of "00100000" is output only from the output port 2. As a result, the digit 3 signal is output from the D5 output terminal of the output port 2. Therefore, the digit 3 and the on-in display LED 79e corresponding to the segment P of the digit 3 can be turned on.

Further, in the interrupt processing when the LED display counter value becomes "01000000", the signal of "01000000" is output only from the output port 2. As a result, the digit 4 signal is output from the D6 output terminal of the output port 2. Therefore, the digit 4 and the replay display LED 79f corresponding to the segment P of the digit 4 can be turned on.
Furthermore, in the interrupt processing when the LED display counter value becomes "10000000", the signal of "10000000" is output only from the output port 2. As a result, the digit 5 signal is output from the D7 output terminal of the output port 2. Therefore, the digit 5 and 79 g of the effect display LED corresponding to the segment P of the digit 5 can be turned on.

Next, in the interrupt processing when the LED display counter value becomes "0000000000", the signal of "00001000" is output only from the output port 4 (there is no output from the output port 2). As a result, the digit 9 signal is output from the D3 output terminal of the output port 4. Therefore, the digit 9 can be turned on.
The LED display counter is 8-bit data, and if it is attempted to manage 9 digits with 8-bit data, one digit cannot be assigned to each bit, resulting in a shortage of one bit. .. Therefore, in the present embodiment, when the LED display counter is "0", the output timing of the digit 9 signal is set.

Further, the LED display request flag shown in FIG. 132B is a flag indicating which LED has a lighting request, and is a predetermined address in the used area of the RWM53 as 1-byte data consisting of 8 bits (D0 to D7). Is remembered in.
Digits 1 to 5 and digits 6 to 8 corresponding to each bit of the LED display request flag are set to the same bits as the LED display counter. Further, the D0 to D2 bits of the LED display request flag correspond to 1 bet to 3 bets.
The LED display request flag does not have a bit corresponding to digit 9. This is because, as described above, the bit corresponding to the digit 9 cannot be provided.

In the LED display request flag, for example, during normal operation (during a game and during a game standby), the set value display LED 73 (digit 5) can be turned off, and 1 bet to 3 bets and digits 1 to 4, 6 to 8 can be turned on. Therefore, it becomes "011111111". Bit "1" of the LED display request flag indicates that lighting is possible, and bit "0" indicates that lighting is not possible.
Further, during the setting change, the D7 bit becomes "1" because the set value is displayed on the digit 5, and the D3 and D4 bits become "0" because the digits 1 and 2 (stored number display LED76) are hidden. Since "88" indicating that the setting is being changed is displayed on the digits 3 and 4 (acquired number display LED78), the D5 bit and the D6 bit are set to "1". Therefore, the LED display request flag during the setting change is "11100000B".

Furthermore, during the setting confirmation, the set value is displayed on the digit 5 as in the case of changing the setting, so that the D7 bit becomes “1”. Further, "8" is displayed on the digits 1 to 4. Therefore, the LED display request flag during the setting confirmation is "11111000B".

Then, when the LED display control (“I_LED_OUT” described later) is actually performed in the interrupt processing, the LED display counter and the LED display request flag are AND-calculated, and a digit signal is output so as to correspond to the calculation result (“I_LED_OUT” described later). Turn on the digit).
For example, as shown in FIG. 132 (A), in the case of the interrupt "4", the LED display counter is "00001000", and if that time is normal, the LED display request counter is "01111111". Therefore, when both are ANDed, it becomes "00001000", so that the signal output at the time of the interrupt processing is only the digit 1 signal (upper digit of the stored number display LED 76).
Further, in the case of the interrupt "8", the LED display counter is "10000000", and if that time is normal, the LED display request counter is "01111111". Therefore, when both are ANDed, it becomes "00000000000", so that there is no signal to be output at the time of the interrupt processing.

FIG. 133 is a flowchart showing interrupt processing (I_INTR) by the main control board 50 (main CPU 55). As described above, the main control board 50 performs the interrupt processing shown in FIG. 133 in a cycle of 2.235 ms (however, the cycle is not limited to the cycle) in parallel with the main process.
First, when the process shifts to the interrupt processing in step S1401, in step S1402, register value saving and duplicate interrupt prohibition processing are performed as initial processing. Here, since the register of the main CPU 55 used in the main processing is used in the interrupt processing, the current register value is saved in the stack area of the RWM 53. Furthermore, the interrupt disable flag is turned on so that the next interrupt processing is not started during the interrupt processing. This is because, for example, an interrupt processing execution request may be made during the execution of the power off processing.

In the next step S1403, it is determined whether or not a power failure is detected. Here, when the power supply voltage falls below a predetermined value by a voltage monitoring device (power supply disconnection detection circuit) provided on the main control board 50 (not shown), a power supply disconnection detection signal is sent to a predetermined bit of a predetermined input port. Is input, it is detected whether or not the signal has been input.
Then, when the power outage is detected, the process proceeds to the power outage process in step S1419, and when it is determined that the power outage is not detected, the process proceeds to step S1404.

In step S1404, the interrupt counter value is updated.
In the next step S1405, 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 passed can be mentioned.
Next, the process proceeds to step S1406, and LED display control (I_LED_OUT; FIG. 134) is performed. Here, it is a process of turning on the LEDs (digits 1 to 5) according to the state of the slot machine 10. The details of this process will be described later.

The errors that occur in the slot machine 10 include a non-recoverable error and a recoverable error. In the non-recoverable error, an error display is output by the main processing as described later, but the recoverable error display is interrupt processing. This LED display control is used every hour.

Next, the process proceeds to step S1407 to read the input port 51. As a result, whether or not the bet switch 40, the start switch 41, the stop switch 42, etc. have been 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, Fall-down data) is generated and stored at a predetermined address of RWM53.

In the next step S1408, it is determined whether or not the set value is within the normal range. Here, the set value data stored in the predetermined address of the RWM 53 is read, and it is determined whether or not the range of the set value is within the normal range (whether it is within the range of "1" to "6"). When it is determined that the set value is within the normal range, the process proceeds to step S1409, and when it is determined that the set value is not within the normal range, the process proceeds to step S1420, and the process proceeds to the unrecoverable error processing 2 (FIG. 137 described later). The error in this case is referred to as an "E6" error in the present embodiment, and the fact that it is "E6" is displayed on the acquired number display LED 78.

Here, a recoverable error and a non-recoverable error will be described.
The recoverable error is an error that can be recovered without turning the power on / off, and examples thereof include a front door open error and a medal jam error when there is no medal in the hopper 35.
On the other hand, the unrecoverable error is an error that cannot be recovered unless the power is turned off and the power is turned on again. Specific non-recoverable errors include the following. However, it is not limited to these unrecoverable errors.
"E1" error: When it is determined that the recovery from the power failure is not normal "E5" error: When it is determined that a display (stop symbol) error has occurred when the reel 31 is stopped "E6" error: Step S1408 When it is determined that the set value is not in the normal range in "E7" error: When it is determined that a random number error has occurred in step S1410.

Further, in the present embodiment, the E1 error and the E5 error are referred to as an unrecoverable error 1, and the E6 error and the E7 error are referred to as an unrecoverable error 2.
The program for determining the unrecoverable error 1 is stored in the used area. Further, the program when the unrecoverable error 1 occurs (FIG. 136, which will be described later; SS_ERROR_STOP1) is stored in the control area in the used area of the ROM 54. Therefore, the process is also referred to as an in-use area process.
On the other hand, the program for determining the unrecoverable error 2 is stored outside the used area. A program for executing step S1408 and step S1410 in the above-mentioned interrupt processing corresponds to this. Further, the program processing (FIG. 137; SS_ERROR_STOP2, which will be described later) when the unrecoverable error 2 occurs is stored in the control area outside the used area of the ROM 54. Therefore, the process is also referred to as an out-of-use area process.

Return to the explanation of the flowchart.
In step S1409, the built-in random number check process is performed. In the present embodiment, a flag that turns on when an error occurs in the built-in random number is provided, and it is determined whether or not this flag is on.
Specifically, for example, when a clock frequency abnormality of a random number for a winning combination lottery (when the random number update is slow, etc.) is detected, the error flag is turned on.
Then, the process proceeds to step S1410, and it is determined whether or not an error has occurred in the built-in random number (whether or not the error flag is on). When it is determined that the occurrence has occurred, the process proceeds to step S1420, and the process proceeds to the unrecoverable error processing 2. The error display content at this time is "E7".

In step S1411, the drive control of the reel 31 is performed. This control is performed in 31 reel units (left, middle, right), and includes stopping, 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 S1412, and the port output process is performed. In this process, the exciting output of the motor 32 (for reels) and the hopper motor 36 and the exciting output of the blocker 45 are performed.

In the next step S1413, the input error check process is executed. This process is a process of determining whether or not there is an abnormality in various sensors.
In the next step S1414, the control command transmission process is performed. This process is a process of transmitting the set control command (untransmitted control command stored in the command buffer 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 point (in principle, if the command buffer is empty, the interrupt processing that arrives next to that point in time), this step S1414 The control command is transmitted to the sub-control board 80.

In the next step S1415, the data for the external signal stored in the RWM 53 is stored in the register. Then, in the next step S1416, the external signal is output (the signal is transmitted to the external centralized terminal plate 100) by writing (setting) the data to the output port 5.
Next, the process proceeds to step S1417 to perform random number update processing. In the next step S1418, the register value saved in step S1402 is restored to allow the next interrupt. Specifically, the register data stored at the start of interrupt processing is restored, and the interrupt prohibition flag is turned off so that the next interrupt processing can be started. Then, the process according to this flowchart is completed.

As shown in the above processing, the on / off of the stored number display LED76, the acquired number display LED78, the status display LED79 (79a to 79g), and the set value display LED73 is controlled by the interrupt processing every 2.235 ms.
Further, 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 unrecoverable error processing (interrupt processing is interrupted until normal recovery).
An unrecoverable error is a serious error that cannot normally occur, and processing based on abnormal data (data update of RWM53 based on data from an input port, transmission of a control command to the sub control board 80, etc.) is executed. The interrupt itself is prohibited to prevent it from happening.
If an untransmitted command is stored in the control command buffer when an unrecoverable error occurs, the command is not transmitted to the sub-control board 80. This is because the control commands stored in the buffer may be incorrect.

FIG. 134 is a flowchart showing the LED display control (I_LED_OUT) in step S1406 of FIG. 133.
First, in step S1431, the output ports 2 and 3 are turned off. The output port 2 is an output port corresponding to the digit 1 signal to the digit 5 signal, and the output port 3 is an output port corresponding to the segment A to segment P signals. By outputting "00000000000" to these output ports 2 and 3, the output of digits 1 to 5 is temporarily prevented. As a result, when switching the LED display, it is prevented that different LEDs are lit and displayed at the same time even for a moment (they are covered and displayed) (afterimage prevention).

In the next step S1432, the output port 4 is turned off in the same manner as in step S1431. The output port 4 is an output port corresponding to the digit 6 signal to the digit 9 signal. By outputting "00000000000" also to this output port 4, the management information display LED 74 is temporarily prevented from being output. As a result, the same effect as above (afterimage prevention) is exhibited.

In the next step S1433, the LED display counter (_CT_LED_DSP) is updated. Updating the LED display counter is a process of shifting the bit "1" to the left by one digit. The updated value is stored in the predetermined address of the RWM53. Then, the process proceeds to step S1434.
In step S1434, it is determined whether or not the LED display counter has been updated 9 times. Here, when the LED display counter before the update is "00000000000", it is determined that the LED display counter has been updated 9 times. If the LED display counter before the update is "00000000000", the process proceeds to step S1435. On the other hand, when the LED display counter is not "000000", the process proceeds to step S1436.

In step S1435, the LED display counter is initialized. Here, the LED display counter value is set to "00000001" and stored at a predetermined address of the RWM53. Then, the process proceeds to step S1436.
In step S1436, the LED display counter and the LED display request flag are acquired. Both the LED display counter and the LED display request flag are stored in the predetermined address of the RWM53. Then, the value of the LED display counter is stored in the E register, and the value of the LED display request flag is stored in the A register.
Next, the process proceeds to step S1437, and the segment display confirmation set of the digit to be displayed this time is performed. In this process, the LED display request flag value and the LED display counter value are ANDed, and the data of the LED to be turned on this time is created.

for example,
LED display counter value: 00001000B
LED display request flag value: 01111111B
After AND operation: 00001000B
Will be.
Or, for example
LED display counter value: 10000000B
LED display request flag value: 01111111B
After AND operation: 00000000000B
Will be.
Then, the calculation result is stored in the A register. Further, the value stored in the A register is stored in the D register.

Next, the process proceeds to step S1438, and it is determined whether or not the A register value (the value obtained by AND-calculating the LED display counter value and the LED display request flag value) is "0". When it is determined that the value is "0", it is determined that there is no display request, and the process proceeds to step S1456. On the other hand, when it is determined that the value is not "0", it is determined that there is a display request, and the process proceeds to step S1439.
In step S1439, error display data is acquired. When an error occurs, the error display data is stored in the address indicating the error display data in the RWM53, so the process of reading the data and storing it in the B register is executed.
In the next step S1440, the LED segment table 2 is set. The LED segment table 2 is “TBL_SEG_DATA2” shown in FIG. 127, and is stored in the used area of the ROM 54. The start address of this data is read and the value is stored in the HL register.

Next, the process proceeds to step S1441 to acquire the set value display data. Here, the current set value stored at the predetermined address of the RWM53 is read and stored in the A register. Next, the process proceeds to step S1442, and it is determined whether or not there is a set value display request. This determination determines whether or not the D7 bit (bit corresponding to digit 5) of the AND-operated value stored in the D register is "1" (whether it is "10000000B"). Then, when it is "1", it is determined that there is a setting value display request, and the process proceeds to step S1455. On the other hand, when it is determined that there is no set value display request, the process proceeds to step S1443.

In step S1443, the stored number data stored at the predetermined address of the RWM53 is acquired and stored in the A register. In the next step S1444, the offset for the upper digit is acquired. This process is a process of executing an operation of dividing the stored number data acquired in step S1443 by "10 (decimal number)", storing the quotient value in the A register, and storing the remainder value in the C register.
In the next step S1445, it is determined whether or not there is a request for displaying the upper digit of the number of stored sheets. This process determines whether or not the D3 bit (bit corresponding to digit 1) of the AND-operated value stored in the D register is "1", and if it is "1", it is determined as "Yes". do. If it is determined that there is a display request for the upper digit of the number of stored sheets, the process proceeds to step S1455, and if it is determined that there is no display request, the process proceeds to step S1446.

In step S1446, it is determined whether or not there is a request for displaying the lower digit of the number of stored sheets. This process determines whether or not the D4 bit (bit corresponding to digit 2) of the AND-operated value stored in the D register is "1", and if it is "1", it is determined as "Yes". Then, the process proceeds to step S1454. On the other hand, when it is determined that there is no request to display the lower digit of the number of stored sheets, the process proceeds to step S1447.

In step S1447, the setting changing display data, the acquired number of sheets data, or the push order instruction number is acquired and stored in the A register. This process is a process of reading the acquired number of sheets data stored in the predetermined address of the RWM 53 and storing it in the A register. At the timing of displaying the acquired number of sheets, the acquired number of sheets data is stored at the predetermined address, and at the timing of displaying the push order instruction number during ART, the push order instruction number is stored at the predetermined address. There is. Further, when the setting is being changed, the data for displaying "8" is stored.

In the next step S1448, it is determined whether or not the error is displayed. This process proceeds to step S1450 when it is determined in step S1448 of determining whether or not the B register value is "0" and determining "No" when it is "0", and when it is determined that an error is not displayed. If it is determined that an error is displayed, the process proceeds to step S1449.

In step S1449, the LED segment table 1 (“TBL_SEG_DATA1” in FIG. 127) is set. This process executes a process of storing the start address of the LED segment table 1 in the HL register.
Next, the process proceeds to step S1450 to acquire an offset for the high-order digit. In this process, if no error has occurred, the operation of dividing the acquired number data or the push order instruction number stored in the A register at this point by "10 (decimal number)" is executed, and the quotient is calculated. Store in the A register and store the remainder in the C register. On the other hand, when an error occurs, the operation of dividing the B register value by "10 (decimal number)" is executed, the quotient is stored in the A register, and the remainder is stored in the C register.

In the next step S1451, it is determined whether or not there is a display request for the upper digit of the acquired number display LED 78. This process determines whether or not the D5 bit (bit corresponding to digit 3) of the AND-operated value stored in the D register is "1", and if it is "1", there is a display request. Judge. If it is determined that there is a display request, the process proceeds to step S1455, and if it is determined that there is no display request, the process proceeds to step S1452.

In step S1452, it is determined whether or not there is a display request for the lower digit of the acquired number display LED 78. This process determines whether or not the D6 bit (bit corresponding to digit 4) of the AND-operated value stored in the D register is "1", and if it is "1", a display request is made. to decide. If it is determined that there is a display request, the process proceeds to step S1454, and if it is determined that there is no display request, the process proceeds to step S1453.

In step S1453, bet signal data is acquired. This process is a process of ANDing the LED display counter and the bet number display data and acquiring the calculation result.
Here, the bet number display data is stored in the predetermined address of the RWM53, and is as follows.
At the time of 0 bet: 00000000000B
At the time of one bet: 00000001B
When betting two cards: 000000111B
When betting 3 cards: 00000111B
Therefore, for example, when the LED display counter value is "00000100B" and the bet number display data is "000000111B", the AND operation of both results in "00000100B", and the D2 bit (bit corresponding to the 3-bet display LED) is The data of "1" is created. Then, the process proceeds to step S1456.

When it becomes "Yes" in step S1446 or "Yes" in step S1452 and proceeds to step S1454, an offset for the lower digit is acquired. This process is a process of storing the data stored in the C register in the A register.
Next, the process proceeds to step S1455 to acquire segment output data. This process adds the data stored in the HL register (the start address of the LED segment table 1) and the data stored in the A register (offset value corresponding to the display data), and corresponds to the added address. This is a process of storing data in the D register.
for example,
HL register value = 1816H (before addition)
A register value = 1H
HL register value = 1817H (after addition)
D register value = 00000110 (B): “1” Display data is displayed.
When the push order instruction number is stored in the acquired number data, the "=" display data is acquired.

Next, the process proceeds to step S1456, and it is determined whether or not there is a display request for the segment P. Here, data indicating on / off of the status display LEDs 79d to 79g is stored in a predetermined address of the RWM53. Specifically, it is as follows.
D0 bit: unused D1 bit: unused D2 bit: unused D3 bit: "1" when the game can be started, other "0"
D4 bit: unused D5 bit: "1" when medals can be inserted, other "0"
D6 bit: "1" at the time of replay winning, other "0"
D7 bit: "1" when the effect can be displayed, "0" for others
The relationship between the bit and the status display LED 79 is in agreement with that shown in FIG. 132 (A).

This data is read and stored in the A register, and the value and the value (LED display counter) stored in the E register are ANDed, and when the calculation result is "0", it is determined that there is no display request. .. When it is determined that there is a segment P display request, the process proceeds to step S1457, and when it is determined that there is no display request, the process proceeds to step S1458.

In step S1457, the segment P output data is set. This process is a process of setting the D7 bit (bit corresponding to the segment P) of the data (display data) stored in the D register to “1”. Next, the process proceeds to step S1458, and the LED digit and segment signals are output from the output ports 2 and 3. Specifically, the data (digit data) stored in the E register is output from the output port 2, and the data (segment data) stored in the D register is output from the output port 3. Then, the process proceeds to the ratio display process (S_LED_OUT) in step S1459.

FIG. 135 is a diagram showing the ratio display process (S_LED_OUT) in step S1459.
The "ratio" is an abbreviation for the management information displayed by the management information display LED 74 in the present embodiment, and is displayed by the digits 6 to 9.
The interrupt processing shown in FIG. 133 and the LED display control program shown in FIG. 134 are stored in the used area of the ROM 54. On the other hand, the ratio display processing program of FIG. 135 is stored outside the used area of the ROM 54.
In FIG. 134, in the LED display control which is a program in the used area, when the process proceeds to step S1458, the process proceeds to the ratio display process which is a program outside the used area, and when this ratio display process is completed, the program of FIG. 134 is displayed again. It returns and ends the LED display control (step S1460).

As described above, the LED display control (I_LED_OUT) is executed by the program stored in the used area of the ROM 54, while the ratio display process (S_LED_OUT) is executed by the program stored in the used area of the ROM 54. This is because the lighting control of the digits 1 to 5 is executed by the program in the used area, and the lighting control of the digits 6 to 9 (management information (ratio)) is executed by the program outside the used area. Further, as shown in FIG. 127, the data used in the LED display control (I_LED_OUT) is also stored in the data area in the used area of the ROM 54, and the data used in the ratio display process (S_LED_OUT) is stored in the ROM 54. It is stored in a data area outside the used area.

In FIG. 135, in step S1471, the LED display counter is acquired. This process is the same as the LED display counter acquisition process in step S1436. The LED display counter acquired here is stored in the D register.
In the next step S1472, it is determined whether or not there is a ratio display request. Here, it is determined whether or not there is a display request for any of the digits 6 to 9. Specifically, the LED display counter value stored in the D register and "11111000" are ANDed. Then, when the AND calculation result is not "0", it is determined that there is no ratio display request, and the process according to this flowchart is terminated (that is, in order to return to the process in the used area, the process proceeds to step S1460 in FIG. 134). On the other hand, when the AND calculation result is "0", it is determined that there is a ratio display request, and the process proceeds to step S1473.

In particular,
LED display counter value: 00010000 (digit 2 signal is on)
After AND calculation: 00010000 (≠ "0") → No ratio display request is made.
or,
LED display counter value: 00000001 (digit 6 signal is on)
After AND calculation: 00000000000 → There is a ratio display request.

In the next step S1473, it is determined whether or not the LED display counter value stored in the D register is "0". If it is determined to be "0", the process proceeds to step S1474, and if it is determined that the value is not "0", the process proceeds to step S1475.
In step S1474, a ratio (single digit) display request is set.
Here, the management information display LED 74 displays four digits with digits 6 to 9, as shown in FIG. 125 (B).
Digit 9th place: Ratio (1 digit)
Digit 8th place: Ratio (10 digits)
Digit 7th place: Ratio (100 digits)
Digit 6th place: Ratio (1000 digits)
It is called.

As shown in FIG. 132, when the D0 bit of the LED display counter is "1", the digit 6 signal becomes "1", and when the D1 bit is "1", the digit 7 signal becomes "1" and D2. When the bit is "1", the digit 8 signal is "1". When the LED display counter is "0", the digit 9 signal is on.
However, since nine digits 1 to 9 are managed by an 8-bit LED display counter, even if the digit 9 signal is on, all bits become "0", which corresponds to digit 9. It does not become the data in which the bit to be set is "1". Therefore, when the LED display counter is "0000000000B" (when the digit 9 signal is on), the digit 9 signal is assigned to the D3 bit, so that the digit data "00001000B" with the D3 bit set to "1" is created. .. In step S1474, this process is executed, and "00001000B" is stored in the D register of this digit data. Then, the process proceeds to step S1475.
In step S1471 or S1474 described above, digit data in which any one of the digit 6 (D0) to digit 9 (D3) signals is “1” (on) is stored in the D register.

In the next step S1475, the ratio display number is acquired. Here, the ratio display number refers to the numbers "1" to "5" shown in FIG. 38. Since the switching display is executed at predetermined time intervals from the advantageous section ratio of "1" to the accessory ratio (cumulative) of "5", which number management information is displayed in this interrupt is displayed. get. The acquired ratio display number is stored in the E register.
Next, the process proceeds to step S1476 to set the identification segment offset table. This process is a process of storing the start address of the identification segment offset table (“TBL_SEGID_DATA” in FIG. 127) in the HL register. In the next step S1477, the identification segment offset value is acquired. Specifically, it is a process of reading the offset value corresponding to the ratio display number stored in the E register in step S1475 from the identification segment offset table. For example, the display offset data when the ratio display number is "1" is "7U", and the offset value at this time is "07AH". The display offset data when the ratio display number is "2" is "6y", and the offset value at this time is "06BH". This identification offset value is acquired and stored in the A register.

In the next step S1478, it is determined whether or not there is a display request (display request for digit 6) of the ratio (1000 digits). Here, it is determined whether or not the D0 bit of the value stored in the D register is "1", and if it is "1", it is determined that there is a display request. Specifically, for example, the D register value and "00000001" are ANDed, and if the calculation result is "0", it is determined that there is no display request, and if it is not "0", it is determined that there is a display request. If there is a display request for the ratio (1000 digits), the process proceeds to step S1482, and if there is no display request, the process proceeds to step S1479.

In step S1479, it is determined whether or not there is a display request (display request for digit 7) of the ratio (100 digits). Here, it is determined whether or not the D1 bit of the value stored in the D register is "1", and if it is "1", it is determined that there is a display request. Specifically, for example, the D register value and "00000010" are ANDed, and if the calculation result is "0", it is determined that there is no display request, and if it is not "0", it is determined that there is a display request. If there is a display request for the ratio (100 digits), the process proceeds to step S1483, and if there is no display request, the process proceeds to step S1480.

When the process proceeds to step S1480, there is no request for displaying the ratio (1000 digits) and the ratio (100 digits), that is, there is no request for displaying the identification segment (information type). Therefore, in step S1480, the ratio data is acquired. Here, the "ratio data" corresponds to, for example, "50 (%)" of the advantageous section ratio in the example of FIG. 38.
In this step S1480, the numerical value corresponding to the ratio display number stored in the E register is acquired. For example, when the ratio display number acquired in step S1475 is "1", the ratio data of the advantageous section ratio is acquired. Since the method of acquiring the ratio data is the same as that of the first embodiment, the description thereof will be omitted.

Next, the process proceeds to step S1481 to determine whether or not there is a ratio (single digit) display request (digit 9 display request). This process is a process of determining whether or not the D3 bit of the value stored in the D register is "1". Specifically, the D register value and "00000100" are ANDed, and if the calculation result is "0", it is determined that there is no display request, and if it is not "0", it is determined that there is a display request. If there is a display request for the ratio (1 digit), the process proceeds to step S1483, and if there is no display request, the process proceeds to step S1482.
When there is no request for displaying the ratio (1 digit) in step S1481, it means that there is a request for displaying the ratio (10 digits).

Through the above processing, if there is a request to display the ratio (1000 digits) or the ratio (10 digits), the process proceeds to step S1482, and if there is a request to display the ratio (100 digits) or the ratio (1 digit), the process proceeds to step S1483. ..
In step S1482, the offset for the upper digit is set. At this point, the identification segment offset value (step S1477) or the ratio data (step S1480) is stored in the A register. Then, the process of storing the upper digit in the A register and storing the lower digit in the C register is executed. For example, assuming that the identification segment offset value "07AH" of the advantageous section ratio is stored in the A register, the process of storing "7" in the A register and storing "A" in the C register is executed.
When "50" is stored in the A register as the ratio data, the process of storing "5" in the A register and storing "0" in the C register is executed. Then, the process proceeds to step S1483.

In the next step S1483, the ratio display segment data table (TBL_SEGRATE_DATA) is set. This process is a process of storing the start address of the ratio display segment data table in the HL register in FIG. 127.
Next, the process proceeds to step S1484 to acquire segment output data. In this process, the value stored in the HL register (the start address of the ratio display segment data table) and the value stored in the A register are added, and the data corresponding to the address of the ratio display segment data table after the addition is added. This is a process of storing in the E register.

Specifically, for example
HL register value = 1810H (before addition; start address value of ratio display segment data table)
A register value = 5H
When is
HL register value = 1815H (after addition)
E register value = 01101101B: “5” display data.

Next, the process proceeds to step S1485, and it is determined whether or not the segment P is displayed. In the present embodiment, when the digits 6 to 9 are displayed, the segment P (dot) of the digit 7 is always displayed. Therefore, when there is a request to display the ratio (100 digits), it is determined that the segment P is displayed. .. On the other hand, when there is a display request for the ratio (1 digit), the ratio (10 digits), and the ratio (1000 digits), it is determined that there is no display request for the segment P.
Here, for example, it is determined whether or not the D1 bit of the value stored in the D register is "1", and if it is "1", it is determined that there is a display request for the segment P, and if it is not "1". Determines that there is no display request for segment P.
When it is determined that there is a display request for the segment P, the process proceeds to step S1486, and when it is determined that there is no display request, the process proceeds to step S1487.

In step S1486, the output data corresponding to the segment P is set. Since the segment P corresponds to the D7 bit of the 8-bit data, the segment data (E register value) acquired in step S1484 and "10000000" are OR-operated, and the operation result is acquired and stored in the E register. Remember.
In the next step S1487, in order to output the digit signal and the segment signal, the segment signal is output from the output port 3 and the digit signal is output from the output port 4. At this point, the data corresponding to the digit signal is stored in the D register, and the data corresponding to the segment signal is stored in the E register. Therefore, the E register value is output from the output port 3 and output. The D register value is output from port 4.
After the execution of step S1487, the process returns to the flowchart of FIG. 134. That is, the process proceeds to step S1460 to end the LED display control.

Subsequently, the non-recoverable error processing will be described. In the present embodiment, the non-recoverable error processing 1 and the non-recoverable error processing 2 are provided as the non-recoverable error processing.
As mentioned above, the types of irreversible errors (not limited to the errors exemplified here) are:
"E1" error: When it is determined that the recovery from power failure is not normal "E5" error: When it is determined that a display (stop symbol) error has occurred when the reel 31 is stopped "E6" error: Step S1408 In the case where it is determined that the set value is not in the normal range, "E7" error: When it is determined that a random number error has occurred in step S1410, and the like can be mentioned.

Then, no matter which non-recoverable error occurs, the error number is displayed on the acquired number display LED 78. For example, when an "E1" error occurs, "E" is displayed in digit 3 and "1" is displayed in digit 4. The same is displayed for other unrecoverable errors.

Further, it is determined that the recovery from the power failure is not normal, and the "E1" error is determined during the "program start process (stored in the used area of the ROM 54)" (not shown).
Further, it is determined that a display (stop symbol) error has occurred, and the "E5" error is determined during "main processing (stored in the used area of ROM 54)" (not shown).

On the other hand, the "E6" error is an error when it is determined in step S1408 during interrupt processing that the set value is not in the normal range, but the actual program in step S1408 (set value error (outside the set value range)). The determination program) is stored outside the used area of the ROM 54. In FIG. 133, when the process proceeds to step S1408, the set value error (outside the set value range) determination program stored outside the used area is executed, and then the program is set to return to step S1408.

Similarly, the "E7" error is an error when the random number value is determined to be an error in step S1410 during interrupt processing, but the actual program (random number abnormality check program) in step S1410 is the ROM 54. It is stored outside the used area. When the process proceeds to step S1410, the random number abnormality check program stored outside the used area is executed, and then the process returns to step S1410.

Then, when a non-recoverable error is determined by the program in the used area, the non-recoverable error processing 1 is executed, and when a non-recoverable error is determined by the program outside the used area, the non-recoverable error is executed. Process 2 is executed.
FIG. 136 is a flowchart showing the non-recoverable error processing 1 (SS_ERROR_STOP1). Further, FIG. 137 is a flowchart showing the non-recoverable error processing 2 (SS_ERROR_STOP2).
The program of the non-recoverable error processing 1 is stored in the used area of the ROM 54, and the program of the non-recoverable error processing 2 is stored outside the used area of the ROM 54.
Further, in the non-recoverable error processing 1, only the digits 3 and 4 (acquired number display LED 78) are turned on and controlled. On the other hand, in the non-recoverable error processing 2, the digits 3 and 4 (acquired number display LED78) and the segments P of the digits 6 to 9 (management information display LED 754) are turned on and controlled.

In FIG. 136, in step S1491, error display data (lower digit) is set. In the process here, the process of storing the data (01000000B) in which only the digit 4 is set to "1" is executed in the H register. This value corresponds to the data in which the D6 bit of the output port 2 is set to "1".
Next, the process proceeds to step S1492, and the high-order digit is set as the error display data. In the process here, the process of storing the data (00100000B) in which only the digit 3 is set to "1" is executed in the D register. This value corresponds to the data in which the D5 bit of the output port 2 is set to "1".

Further, in step S1492, segment data for displaying the upper digit "E" of the unrecoverable error, that is, "01111001B" is stored in the E register.
Before shifting to the non-recoverable error processing, segment data for displaying the lower digit of the current non-recoverable error is stored in the L register. For example, when the non-recoverable error this time is an "E1" error, the lower digit is "1", so that segment data, that is, "00000011B" is stored.
In the following example, it is assumed that the non-recoverable error 1 this time is an E1 error.

From the above, the D, E, H, and L register values are, at this point,
D register value: Data (00100000B) in which only the upper digit (digit 3) of the unrecoverable error is set to "1".
E register value: Display data (01111001B) indicating the upper "E" of the unrecoverable error.
H register value: Data (01000000B) in which only the lower digit (digit 4) of the unrecoverable error is set to "1".
L register value: Display data (0000001110B) indicating the lower "1" of the non-recoverable error this time.
Will be.

In the next step S1493, the output port address and the number of output ports to be cleared are set. In the present embodiment, the output ports to be cleared in the unrecoverable error processing 1 are output ports 0 to 6, and an address is set for each port. Therefore, the address and the number of output ports (7) are set. set.
In the next step S1494, the output ports 0 to 6 are sequentially turned off. Specifically, all "0"("0000000000") are output from each address indicating the output ports 0 to 6 for each output port. In step S1495, the next output port address is set. That is, the address indicating the output port is incremented by "1". For example, when the address of the output port 0 is "0F1H", the address "0F2H" of the output port 1 is set as the next address.
Next, the process proceeds to step S1496, and it is determined whether or not all the output ports have been completed, that is, whether or not the output ports 6 have been completed. When it is determined that the process has not been completed, the process returns to step S1494, and when it is determined that the process has been completed, the process proceeds to step S1497.

As described above, by turning off all the output ports 0 to 6, the active signal that was output before the process was executed is turned off. This makes it possible to prevent LED burn-in, motor 32 burn-in, and medal swallowing. For example, if the power is cut off while the blocker signal is being output, the blocker 45 will continue to be on (the state of forming the medal flow path) unless the process is executed (medal detection). The medal is swallowed because no processing occurs).
Further, if the power supply is cut off while the excitation signal of the motor 32 is being output, the excitation signal of the motor 32 will continue to be output until the reset signal is input unless the process is executed.

In the next step S1497, display data is output from the output ports 2 and 3 in order to display the upper digit of the error. The data stored in the D register is output from the output port 2, and the data stored in the E register is output from the output port 3.

Next, the process proceeds to step S1498, and standby (waiting) for preventing LED flicker is executed. Here, how much standby is performed depends on the performance of the LED, but for example, it may be set to about "0.1 ms". Here, for example, a predetermined value (for example, "255") is stored in the B register, this value is subtracted by the internal system clock, for example, and when the B register value becomes "0", it is determined that the waiting time has elapsed. Then, the process proceeds to the next step S1499.
In step S1499, "0" is output from the output ports 2 and 3. This process is a process for preventing an afterimage, similar to step S1431 in FIG. 134 described above.

Next, the process proceeds to step S1500 to execute a standby (wait) for preventing LED flicker. This is a process for surely quenching the LED after outputting "0" from the output ports 2 and 3. Next, the process proceeds to step S1501 to switch between the upper digit and the lower digit.
Specifically, the DE register value and the HL register value are exchanged. This will
<Before replacement>
D register value: data in which only the upper digit (digit 3) of the unrecoverable error is set to "1" E register value: display data indicating the upper "E" of the unrecoverable error H register value: lower in the unrecoverable error Data with only the digit (digit 4) set to "1" L register value: Display data indicating the lower "1" of this unrecoverable error <after replacement>
D register value: data in which only the lower digit (digit 4) of the unrecoverable error is set to "1" E register value: display data indicating the lower "1" of the unrecoverable error this time H register value: unrecoverable error Data in which only the upper digit (digit 3) of is set to "1" L register value: Display data indicating the upper "E" of the unrecoverable error.

Then, the process proceeds to step S1502, and the display data is output from the output ports 2 and 3 in order to display the lower digit of the error. Similar to step S1497, the D register value is output from the output port 2, and the E register value is output from the output port 3. As a result, the output port 2 outputs "01000000" whose digit 4 signal is "1", and the output port 3 outputs display data "00000011" indicating "1".
Next, the process proceeds to step S1503, and the standby for preventing flicker is executed. This process is the same as in step S1498. Next, the process proceeds to step S1504, and “0” is output from output ports 2 and 3 in the same manner as in step S1499. Further, in the next step S1505, a standby for preventing flicker is executed. This process is the same as in step S1500. Then, the process returns to step S1497.

By the above processing, for example, when an "E1" error occurs, the display of "E" by the digit 3 and the display of "1" by the digit 4 are alternately and repeatedly displayed at predetermined time intervals.
As described above, the LED display control (and the ratio display process) is executed in the timer interrupt process, but the timer interrupt process is not executed (prohibited) at the time of an unrecoverable error, and is shown in FIG. 136. As described above, the display of the unrecoverable error is executed by the arithmetic processing using the register and the hardware configuration.

Subsequently, the non-recoverable error processing 2 (SS_ERROR_STOP2) of FIG. 137 will be described. As described above, the unrecoverable error process 2 is a process executed when a program outside the used area of the ROM 54 determines that an unrecoverable error occurs (for example, an “E6” error or an “E7” error). ..
In FIG. 137, the same processes as those in FIG. 136 are assigned the same step numbers.
Steps S1491 to S1505 are the same as those in FIG. 136.
The non-recoverable error process 1 is a process of displaying an error number on the digits 3 and 4 (acquired number display LED 78). On the other hand, the non-recoverable error process 2 includes a process of displaying an error number on the digits 3 and 4 (acquired number display LED 78) and displaying predetermined information on the management information display LED 74 as well.

In FIG. 137, after step S1505, the process proceeds to step S1506. In step S1506, the process of lighting the segment P of the digit 6 is executed. Specifically, the output port 3 outputs the signal of "10000000B" (only the segment P is on), and the output port 4 outputs the signal of "00000001B" (only the digit 6 is on). Next, the process proceeds to step S1507 to execute a standby process for preventing flicker. This process is the same as step S1498 and the like. Next, the process proceeds to step S1508, and the signal of "0" is output from the output ports 3 and 4. This process is the same as step S1499.

Next, the process proceeds to step S1509 to execute a standby process for preventing flicker. This process is the same as in step S1500.
The above process is repeated for digits 7 to 9. That is,
(1) Output a signal of "10000000B" (only segment P is on) from output port 3 and output a signal with the corresponding digit turned on ("1") from output port 4 (2) For flicker prevention Standby processing (3) Turn off output ports 3 and 4 (output "0")
(4) Execute standby processing to prevent flicker.
By the above processing, the segments P of the digits 6, 7, 8 and 9 are sequentially lit. After the process of step S1521, the process returns to step S1497.

<21st Embodiment>
FIG. 138 is a diagram showing a configuration of an output port in the 21st embodiment, and is a diagram corresponding to FIG. 128 in the 20th embodiment.
The feature of the output port of the 21st embodiment is that, assuming that the digit 5 is not provided, there is one output port (digit port) for transmitting the digit signal (output port 3), and the output for transmitting the segment signal. The point is that there is one port (segment port) (output port 4).
In the 21st embodiment of FIG. 138, unlike the 20th embodiment, the output port 2 is not assigned a digit signal (of course, a segment signal is also not assigned).

The output port 3 is set as an output port dedicated to the digit signal. Digit 1 to 4 signals and digit 6 to 9 signals are assigned to the 8 bits of the output port 3.
Therefore, the digit 5 signal is not assigned to the output port 3. When the number of digits including the digit 5 is 9, if an attempt is made to allocate this to an 8-bit signal, one bit is insufficient. Therefore, if the digit 5 is not provided, or if the digit 5 is provided, it is assigned to another port (for example, the output port 5), and the digits 1 to 4 and 6 to 9 signals are assigned to one output port 3. Even when the digit 5 is provided, the digit 5 is a digit that does not need to be lit during normal operation (except during setting change or setting confirmation), so that the digits 1 to 4 and 6 to be lit during normal operation are required. Nine signals are set to be managed by one output port 3.

Further, the output port 4 is an output port dedicated to the segment, and is the same as the output port 3 of the 20th embodiment.
In the 21st embodiment, when the digit 5 is not provided, the set value is displayed by the stored number display LED 76 (either digit 1 or 2) or the acquired number display LED 78 (digit 3 or 4) while the setting is being changed or the setting is being confirmed. Display in any of). In this way, it is not necessary to assign a bit dedicated to the digit 5 signal to the output port. In this case, in FIG. 138, the D5 bit of the output port 5 becomes an unused (free) bit.
However, as in the 20th embodiment, when the set value display LED 73 (digit 5) is provided and the digit 5 signal is output, it can be assigned to, for example, the D5 bit of the output port 5 as shown in FIG. 138. ..

Also in the 21st embodiment, since the output port 3 that outputs the digit signal and the segment output port 4 that outputs the segment signal are continuous output ports, the digit data and the segment data (2 bytes in total) can be input at one time. It becomes possible to output.
Further, when the set value display LED 73 (digit 5) is not provided, the total number of digits 1 to 4 and 6 to 9 is eight, and a digit can be assigned to each bit of the 8-bit data. Therefore, the digit can be assigned to each bit. There is an advantage that the number of output ports for outputting signals can be one, which makes it easier to manage.

FIG. 139 (A) is a diagram showing the relationship between the digit and the segment in the 21st embodiment, and FIG. 139 (B) is a diagram showing the LED display counter of the 21st embodiment. The example of FIG. 139 shows an example in the case where the digit 5 is not provided.
In the 21st embodiment, the allocation of the digit and the segment is the same as that of the 20th embodiment (FIG. 126) except that the digit 5 is not provided. Therefore, in the 21st embodiment, among the status display LEDs 79, the effect display LED 79g is not provided. If 79 g of the effect display LED is provided, it can be assigned to the segment P of the digit 2.

Further, as shown in FIG. 3B, the signal assigned to the bit of the LED display counter and the signal assigned to the bit of the output port 3 are matched. In the figure (B), when the bit "1" is shifted to the left by one digit at the time of the next interrupt after the interrupt "8", the LED display counter becomes "0", but when it becomes "0", it becomes "0" at the time of the interrupt. Initialize the LED display counter to "00000001". As a result, the LED display counter becomes a counter in which one cycle has 8 interrupts.
Furthermore, unlike the 20th embodiment, the LED display counter is not assigned a 1-bet display signal to a 3-bet display signal. In the 21st embodiment, the 1-bet display LED 79a to the 3-bet display LED 79c are statically lit instead of dynamically lit.
As described above, since the bet number display data is stored in the predetermined address of the RWM 53, this data may be read periodically and the bet display signal may be constantly output from the output port 2.
Furthermore, the allocation of the segment P to the digit signal is the same as in the 20th embodiment.
In the 21st embodiment, the illustration of the circuit wiring diagram (FIGS. 129 to 131) shown in the 20th embodiment is omitted.

FIG. 140 is a flowchart showing the LED display control (I_LED_OUT) in the 21st embodiment, and is a flowchart corresponding to FIG. 134 in the 20th embodiment. In the flowchart described below, the steps for executing the same processing as those in the twentieth embodiment are assigned the same step numbers, and duplicate description will be omitted. Further, steps having contents different from those of the 20th embodiment are underlined in step numbers.
First, step S1531 is a step corresponding to step S1431 in FIG. 134, and here, the output port 3 (digit port) and the output port 4 (segment port) are turned off. By outputting "0000000000B" from these output ports 3 and 4, the outputs of digits 1 to 4 and 6 to 9 are temporarily prevented from being output. This is to prevent different LEDs from being turned on and appearing at the same time (being covered and displayed) even for a moment when the LED display is switched, as in the 20th embodiment (afterimage prevention). ).

In the next step S1433, the LED display counter is updated. Here, as described above, the process of shifting the bit of "1" to the left by one digit is executed. Next, the process proceeds to step S1532, and it is determined whether or not the LED display counter is “0”. If it is determined to be "0", the process proceeds to step S1435, and if it is determined that the value is not "0", the process proceeds to step S1436.
In step S1435, the LED display counter is initialized. Here, the process of setting the LED display counter to "00000001" is executed.

Steps S1435-Step S1446 are the same as those in FIG. 134 (20th embodiment). However, in the 21st embodiment, the processing of steps S1441 and S1442 in FIG. 134 is not performed. In the 20th embodiment, it is determined whether or not there is a display request for the digit 5 (set value display LED 73), but in the 21st embodiment, the set value is displayed on the digits 3 and 4 (acquired number display LED 78). , Acquire the set value display data in step S1533.
After step S1446, the process proceeds to step S1533 to acquire the set value display data, the acquired number of sheets data, and the push order instruction number. If the setting is being changed, the set value data acquired in step S1533 is displayed in digit 3 or 4 (whichever is arbitrary).

Further, in the 21st embodiment, since the 1-bet display LED 79a to the 3-bet display LED 79c execute static lighting, the processes of steps S1452 and S1453 in FIG. 134 are not executed.
In FIG. 140, when it is determined as "No" in step S1451, it is determined that there is a display request for the acquired lower digit (digit 4), and the process proceeds to step S1454.
Further, step S1534 is a step corresponding to step S1458 in FIG. 134, and here, the digit signal is output from the output port 3 and the segment signal is output from the output port 4. Then, the process proceeds to step S1535 to proceed to the ratio display process.
Other than the above, it is the same as the 20th embodiment.

FIG. 141 is a flowchart showing the ratio display process in the 21st embodiment, and is a flowchart corresponding to FIG. 135 in the 20th embodiment.
In FIG. 141, the difference from FIG. 135 is that it does not have step S1473 and step S1474. That is, after step S1472, the process proceeds to step S1475.
As shown in FIG. 139, the LED display counter of the 21st embodiment is a counter having 8 interrupts in one cycle, and when the LED display counter becomes "0" as in the 20th embodiment. These steps are not required as it is not determined that there is a particular ratio display request.
Other than the above, it is the same as the 20th embodiment.

<22nd Embodiment>
FIG. 142 (A) is a diagram showing various LEDs on the display board 75 in the 22nd embodiment, and FIG. 142 (B) is a diagram showing the management information display LED 74 in the 22nd embodiment more specifically. , FIG. 2C is a diagram showing a set value display LED 73 according to the 22nd embodiment. FIG. 142 is a diagram corresponding to FIG. 125 of the 20th embodiment.
In the 20th embodiment (the same applies to the 1st embodiment), each LED is divided into digits 1 to 9, but in the 22nd embodiment, the relationship between the digit and the LED is as follows.
Digit 1a: Upper digit of storage number display LED76 Digit 2a: Lower digit of storage number display LED76 Digit 3a: Upper digit of acquisition number display LED78 Digit 4a: Lower digit of acquisition number display LED78 Digit 5a: Status display LED79
Digit 1b: Management information display LED74 (information type high-ranking (1000 digits))
Digit 2b: Management information display LED74 (information type lower (100 digits))
Digit 3b: Management information display LED74 (upper digit (10 digits))
Digit 4b: Management information display LED74 (lower digit of numerical value (1 digit))
Digit 5b: Set value display LED73
Furthermore, as will be described later, the segments of the digits 1a to 5a are referred to as segments 1A to 1P, and the segments of the digits 1b to 5b are referred to as segments 2A to 2P.

As shown in FIG. 142 (A), the digits 1a to 4a are all 7-segment displays having dot segments (segments 1P) in 7 segments (in this respect, the digits 1 to 4 in the 20th embodiment). different). Therefore, in the 22nd embodiment, the digits 1a to 4a and 1b to 5b can use the same 7-segment display.
Further, in the first embodiment, as shown in FIG. 2, the digit 2, that is, the dot segment (segment P) of the lower digit of the stored number display LED 76 is used as the advantageous section display LED 77. On the other hand, in the 22nd embodiment, the dot segment (segment 1P) of the digit 4a indicating the lower digit of the acquired number display LED 78 is used as the advantageous section display LED 77.

Further, in the management information display LED 74, the dot segment (segment 2P) of the digit 2b functions as a digit-separated display LED as in the twentieth embodiment.
Furthermore, the dot segments (segments 2P) of the digits 1b, 3b and 4b function as non-recoverable error display LEDs as in the twentieth embodiment.

FIG. 143 is a diagram showing the relationship between the digit and the segment in the 22nd embodiment.
As described above, the segments of the digits 1a to 5a are the segments 1A to 1P, and the segments of the digits 1b to 5b are the segments 2A to 2P.

In FIG. 143, the segments 1P of the digits 1a to 3a are unused. On the other hand, the segment 1P of the digit 4a (the digit indicating the lower digit of the acquired number display LED 78) is used as the advantageous section display LED 77 as described above.
Further, the digit 5a constitutes the status display LED 79, and the segments 1A to 1G and 1P of the digit 5a are as shown in FIG. 143.
Segment 1A: 1 bet display LED 79a
Segment 1B: 2-bet display LED 79b
Segment 1C: 3-bet display LED 79c
Segment 1D: Game start display LED 79d
Segment 1E: Input display LED 79e
Segment 1F: Replay display LED 79f
Segment 1G: Unused Segment 1P: Unused.
Therefore, for example, when the digit 5 signal is output and the segment 1A signal is output, the 1-bet display LED 79a is turned on.
Further, the segment 2P of the digit 5b (set value display LED73) is unused.

FIG. 144 is a diagram showing an output port according to the 22nd embodiment.
The feature of the output port of the 22nd embodiment is that there is one output port for transmitting the digit signal (output port 2) and two output ports for transmitting the segment signal (output ports 3 and 4). Is.
Therefore, the differences from the above-described 20th embodiment and the like are the output port for transmitting the segment signal of the management information display LED 74 (digits 1b to 4b) and the segment signal of the storage number display LED 76 and the like (digits 1a to 4a). It is a point that a separate output port for transmitting is provided.

First, digit 1 to 5 signals are assigned to the D0 to D4 bits of the output port 2, 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, it is driven by both digit 1a (storage number display LED76 (upper digit)) and 1b (management information display LED74 (information type upper)). The 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 1A to 1P signals, and the segments 1A to 1P signals are assigned to the D0 to D7 bits.
Similarly, the output port 4 is an output port for the segment 2A to 2P signals, and the segment 2A to 2P signals are assigned to the D0 to D7 bits.
The output port 5 is the same as that of the twentieth embodiment.

145 to 147 are circuit diagrams showing wiring of electric signals of the main control board 50, the display board 75, and digits 1 (1a, 1b) to 5 (5a, 5b), respectively. It is a figure corresponding to 129 to FIG. 131.
Note that, in FIG. 145, the transistor and the like are not shown, as in FIG. 129 of the 20th embodiment.
145 and 146 show the wiring of the electric signal on the main control board 50, and FIG. 147 shows the wiring of the electric signal on the display board 75.

As shown in FIG. 146, digits 5b constituting the set value display LED 73 and digits 1b to 4b constituting the management information display LED 74 are provided on the main control board 50.
Further, as shown in FIG. 147, on the display board 75, the digits 1a and 2a constituting the stored number display LED 76, the digits 3a and 4a constituting the acquired number display LED 78, and the six digits constituting the digit 5a are formed. A status display LED 79 is mounted.

As shown in FIG. 145, a main CPU 55 is provided on the main control board 50, and IC2 to IC4 having output ports 2 to 4 are provided, respectively. Although the main control board 50 is actually provided with ICs other than these three, the illustration is omitted in the present embodiment.

IC2 is an IC related to the control of digit 1 to 5 signals, and IC3 is an IC related to the control of segments 1A to 1P signals. Further, the IC4 is an IC related to the control of the segments 2A to 2P signals.
The points that each of the ICs 2 to IC4 is provided with a clock signal input terminal and the like are the same as those in the 20th embodiment, and thus the description thereof will be omitted.

Digit 1 to 5 signal lines are output from the D0 to D4 output terminals of the output port 2, respectively, one of which is connected to the digits 1b to 5b of the main control board 50, and the other is connected to the display board 75.
Further, segment 1A to 1P signal lines are output from the D0 to D7 output terminals of the output port 3, respectively, and these signal lines are connected to the display board 75.
Furthermore, segment 2A to 2P signal lines are output from the D0 to D7 output terminals of the output port 4, respectively, and these signal lines are connected to the digits 1b to 5b of the main control board 50.

In FIG. 146, the digit 1 to 5 signals are connected to the drive signal lines of the digits 1b to 5b, respectively.
The digits 1b to 5b are LEDs having eight segments (segments 2A to 2G and 2P), respectively. Then, the LEDs constituting the segments 2A to 2G and 2P of the digits 1b to 5b are connected to the segments 2A to 2G and 2P signal lines, respectively.

As shown in FIG. 147, digits 1a to 5a are connected to the display board 75. The output terminals of the digit 1 signal line to the digit 4 signal line of the display board 75 and the drive signal lines of the digits 1a to 4a are connected to each other.
Further, all of the digits 1a to 4a are LEDs having seven segments (segments 1A to 1G and 1P), similarly to the digits 1b to 5b. Then, each LED of the segments 1A to 1G of the digits 1a to 3a is connected to the output terminal of the segment 1A to 1G signal line, respectively. Since each segment 1P of the digits 1a to 3a is unused, it is not connected to the segment 1P signal line.
On the other hand, the segments 1A to 1G and 1P of the digit 4a are connected to the output terminals of the segments 1A to 1G signal lines.
Furthermore, six status display LEDs 79, specifically, 1-bet display LED 79a, 2-bet display LED 79b, 3-bet display LED 79c, game start display LED 79d, input display LED 79e, and replay display LED 79f are connected to the digit 5 signal line. Has been done.

The 1-bet display LED 79a is connected to the output terminal of the segment 1A signal line, the 2-bet display LED 79b is connected to the output terminal of the segment 1B signal line, and the 3-bet display LED 79c is connected to the output terminal of the segment 1C signal line. There is.
Further, the game start display LED 79d is connected to the output terminal of the segment 1D signal line, the input display LED 79e is connected to the output terminal of the segment 1E signal line, and the replay display LED 79f is connected to the output terminal of the segment 1F signal line.

In the above configuration, for example, when the data signal of "1" is output from the D0 output terminal of the main CPU 55, the data signal is input to the D0 input terminals of IC2 and IC4, respectively. At this moment, the XCS2 output terminal is active. At that time, the data signal is input to the D0 input terminal of the IC2.
As a result, the digit 1 signal is output, so that the drive signal is supplied to both the digit 1a (the upper digit of the storage number display LED 76) and the digit 1b (the upper digit of the information type of the management information display LED 74).

Further, when the digit 1 signal is output as described above, for example, when the data signal of "1" is output from the D0 and D1 output terminals of the main CPU 55 and the XCS3 output terminal is active at this moment, The data signal is input to the D0 and D1 input terminals of the IC3. As a result, the segments 1A and 1B signals are output to the display board 75, so that current can flow through the segments 1A and 1B of the digit 1a.
Of course, even if the segments 1A and 1B signals are output, the segments 2A and 2B of the digit 1b are not lit.

On the other hand, when the digit 1 signal is output as described above, for example, when the data signal of "1" is output from the D0 and D1 output terminals of the main CPU 55 and the XCS4 output terminal is active at this moment, The data signal is input to the D0 and D1 input terminals of the IC4. As a result, the segments 2A and 2B signals are output to the digit 1b, so that a current can flow through the segments 2A and 2B of the digit 1b.
Of course, even if the segments 2A and 2B signals are output, the segments 1A and 1B of the digit 1a are not lit.

Further, for example, when the digit 5 signal is output from the D4 output terminal of the IC2 and the segment 1A, 1B and 1C signals are output from the D0, D1 and D2 output terminals (segments 1A, 1B and 1C signals) of the IC3, 1 bet is output. The display LED 79a, the 2-bet display LED 79b, and the 3-bet display LED 79c can be turned on.
Even if the digit 5 signal is output, the digit 5b (set value display LED73) does not light unless the segments 2A to 2G signals are output.
As described above, in the 22nd embodiment, the digit 1 to 5 signals, the segments 1A to 1G and 1P signals, the segments 2A to 2G and 2P signals, 9 7-segments, and 6 status display LEDs 79 are used. Control lighting.

FIG. 148 (A) is a diagram showing the relationship between the interrupt, the LED display counter (_CT_LED_DSP) value, and the digit signal and the segment signal in the 22nd embodiment. Further, FIG. 3B is a diagram showing an LED display request flag (_FL_LED_DSP). FIG. 148 is a diagram corresponding to FIG. 132 of the 20th embodiment.
In FIG. 148 (A), the LED display counter of the 22nd embodiment sets the bit “1” of the LED display counter value as the interrupt “1” → “2” → ... (for each interrupt). It is updated so that it shifts to the right by one digit. Then, in the figure, in the interrupt next to the interrupt "5", the LED display counter becomes "00000000000" by shifting to the right by one digit. At the time of the interrupt, the LED display counter is initialized and the LED display counter is turned on. Set to "00010000". As a result, the LED display counter repeats the values of "5"->"4"->...->"1"->"5"->"4"-> ... for each interrupt process. That is, 5 interrupts make one cycle.

From the above, the LED display counter value is
"N" interrupt: 00010000
"N + 1" interrupt: 00001000
"N + 2" interrupt: 00000100
"N + 3" interrupt: 000000010
"N + 4" interrupt: 00000001
"N + 5" interrupt: 00000000000 → 00010000 (initialization; same value as "N" interrupt)
"N + 6" interrupt: 00001000
:
Will be.

In the 22nd embodiment, the 5 interrupts are in one cycle, and the digits 1a to 5a and the digits 1b to 5b are turned on. Specifically, in FIG. 148 (A), for example, when the interrupt is "1", that is, when the LED display counter value is "00010000", a digit 5 signal is output, and the status display LED 79 and the set value display LED 73 are displayed. It can be lit. At the time of the next interrupt "2", the LED display counter becomes "00001000", the digit 4 signal is output, and the lower digit of the acquired number display LEDD78 and the numerical lower digit of the management information display LED74 can be lit.

Further, as shown in FIG. 3B, in the LED display request counter, the D0th bit corresponds to the digit 1 signal, the D1 bit corresponds to the digit 2 signal, ..., And the D4 bit corresponds to the digit 5 signal. It is data. Each bit of the LED display request counter matches the bit of the output port 2.
The difference from the 20th embodiment in the LED display request counter is that the D4 bit (bit corresponding to digit 5) is "1" even in normal times. This is to output the segments 1A to 1G signals of the digit 5a and turn on the status display LED 79 during normal operation.
In the twentieth embodiment, since one cycle has five interrupts, the time during which the LED is turned off can be shortened, and the flicker of the LED can be further reduced.

For example, if the LED display counter is "00010000" and the LED display request flag is "00011111 (normally)", the AND operation of both results in "00010000" and only the digit 5 signal is turned on. However, normally, only the segment 1 signal is output so that the status display LED 79 can be turned on, but the segment 2 signal is not output and the set value display LED 73 (digit 5b) is controlled so as not to be turned on.

On the other hand, during the setting change, for example, at the interrupt timing (LED display counter is "00010000") when the digit 5 signal is turned on, the segment 2 signal is output and the set value display LED 73 (digit 5b) can be turned on.
Further, during the setting change, for example, at the interrupt timing when the digit 3 signal is turned on (LED display counter is "00000100"), the segment 1 signal is output for digit 3a (upper digit of the acquired number display LED 78), and "8". Is displayed.

Furthermore, when the LED display counter generates the segment 1 signal at the interrupt timing of "00001000" (interrupt "2" in the figure), it is determined whether or not it is in the advantageous section. Whether or not it is in the advantageous section is determined, for example, by determining whether the advantageous section flag that is turned on during the advantageous section is on / off (the advantageous section flag is stored in a predetermined address of the RWM 53). Then, when it is determined that the section is in the advantageous section, the value obtained by ORing the generated segment 1 signal and "10000000" is output as the segment 1 signal from the output port 3. As a result, the segment 1P (advantageous section display LED 77) of the digit 4a can be turned on when the advantageous section is in progress.

FIG. 149 is a flowchart showing the LED display control (I_LED_OUT) in the 22nd embodiment, and is a flowchart corresponding to FIG. 134 in the 20th embodiment. As described above, the step numbers different from those in the 20th embodiment are underlined. Further, the steps for executing the same processing as those in the 20th embodiment are assigned the same step numbers, and the description thereof will be omitted.
In FIG. 149, step S1541 turns off the LED digit and segment 1 (output ports 2 and 3). This process is a process common to step S1431 in FIG. 134, and is a process of outputting "0000000000B" from the output ports 2 and 3. In the next step S1542, segment 2 (output port 4) is turned off. Similar to the above process, this process is also a process of outputting "0000000000B" from the output port 4.

In step S1453, the LED display counter is updated. In the 22nd embodiment, as shown in FIG. 148, the bit "1" is updated by shifting it to the right by one digit.
In the next step S1544, it is determined whether or not the LED display counter is "0", and if it is determined to be "0", the process proceeds to step S1545, and if it is determined that the LED display counter is not "0", the process proceeds to step S1436. ..
In step S1545, the LED display counter is initialized. That is, in the determination of step S1544, when the LED display counter is "000000000", the process of setting it to "00010000" is executed. Then, the process proceeds to step S1436.

Step S1436 is the same process as in the 20th embodiment. In the next step S1546, error display data, LED display data, and bet signal data are acquired. The acquisition of the error display data is the same as the process of step S1439 in FIG. 134. Further, the LED display data is data indicating on / off of the status display LED 79, and is stored at a predetermined address in the used area of the RWM 53. Specifically, the data is as follows.
D0: Unused D1: Unused D2: Unused D3: "1" when the game can be started, "0" when the game cannot be started
D4: "1" when medals can be inserted, "0" when medals cannot be inserted
D5: "1" when replay wins, "0" when replay does not win
D6: unused D7: unused

In the above data, the bits D0 to D7 correspond to the segments 1A to 1P of the status display LED 79 shown in FIG. 143, and this value is acquired.
Further, the bet signal data is the same as the data acquired in step S1454 in FIG. 134.
At the time of 0 bet: 00000000
At the time of one bet: 00000001
When betting two cards: 000000111
When betting 3 cards: 00000111
Since any value of is stored in a predetermined address in the used area of the RWM53, the value is acquired.

Next, the process proceeds to step S1547, the LED display data and the bet signal data are combined, and the data for the output port 3 is set. This process is a process of ORing the LED display data and the bet signal data and storing the calculation result.
Next, the process proceeds to step S1548, and the segment 2 data for the output port 4 is cleared. This process is a process of clearing the register for setting the segment 2 data.
The following steps S1438 to S1455 are the same as in FIG. 134. However, FIG. 149 does not have step S1439 in FIG. 134. This is because the error display data has already been acquired in step S1546.
Further, when it is determined in step S1451 that there is no request for displaying the upper digit of the acquired number, there is a request for displaying the lower digit of the acquired number, so that there is no determination branch in step S1452 of FIG.

After step S1455, the process proceeds to step S1549 to set segment 2 data for the output port 4. The data set here is segment 2 data (segments 2A to 2G) corresponding to the set value display data. This is because the digits 1b to 4b are lit by the ratio display process described later, so that the segment 2 data of the digits 1b to 4b may not be set in this flowchart.
Next, the process proceeds to step S1550, and it is determined whether or not there is a display request for the digit 5b (set value display LED 73). Here, the display request for the digit 5b is made when the LED display counter value is "00010000" and the setting is being changed or confirmed. When it is determined that there is a display request for the digit 5b, the process proceeds to step S1554, and when it is determined that there is no display request, the process proceeds to step S1551.

In step S1551, segment 1 (1A to 1G) data for the output port 3 is set. The segment 1 data for the output port 3 is stored in a predetermined register in step S1547. Next, the process proceeds to step S1552, and the data of the advantageous section display LED 77 is set. Here, whether or not the game is in the advantageous section is determined by, for example, the advantageous section flag that is turned on during the advantageous section. Then, when it is determined that the section is in the advantageous section, it is determined whether or not the digit lit by the interrupt processing this time is the digit 4. When the LED display counter value is "00001000", it is determined that the digit 4 is lit. In this case, the segment 1 data set in step S1551 and the data obtained by ORing "10000000" are set as the segment 1 data for the output port 3. As a result, data that can light the segment 1P of the digit 4a is set.

Next, the process proceeds to step S1553, and the segment 2 data for the output port 4 set in step S1549 is cleared. This is to prevent the digit 5b from being turned on when there is no display request for the digit 5b (set value display LED 73) (when “No” in step S1550).
Then, the process proceeds to step S1554, the digit signal is output from the output port 2, and the segment 1 signal is output from the output port 3. Next, the process proceeds to step S1555, and the segment 2 signal is output from the output port 4. Here, when the segment 2 data is cleared in step S1553, "00000000000" is output from the output port 4. Then, the process proceeds to step S1556, and the process proceeds to the ratio display process outside the used area.

FIG. 150 is a flowchart showing the ratio display process in the 22nd embodiment, and is a flowchart corresponding to FIG. 135 in the 20th embodiment.
Comparing FIG. 150 and FIG. 135, they differ in that they do not have step S1473 and step S1474.
Further, in step S1561, the digit signal is output from the output port 2, and the segment 2 signal is output from the output port 4.
The points other than the above are the same as those in the 20th embodiment.

<23rd Embodiment>
FIG. 151 is a diagram showing output ports 2 to 6 in the 23rd embodiment, and is a diagram corresponding to FIG. 144 in the 22nd embodiment.
In the 23rd embodiment, as in the 22nd embodiment, there is one output port for transmitting the digit signal (output port 3) and two output ports for transmitting the segment signal (output ports 4 and 6). be. ..
The output port 2 of the 23rd embodiment is a port that outputs a bet display signal and a data strobe signal.
In the 22nd embodiment, the 1-bet display LED 79a to the 3-bet display LED 79c are included in the digit 5a to perform dynamic lighting. On the other hand, in the 23rd embodiment, the 1-bet display LED 79a to the 3-bet display LED 79c are statically lit in the same manner as in the 21st embodiment.

FIG. 152 is a diagram showing the relationship between the digit and the segment in the 23rd embodiment.
As shown in FIG. 152, the 23rd embodiment has digits 1 to 5 as described above, and these are divided into digits 1a to 5a and digits 1b to 4b.
The digit 1a is composed of a storage number display LED76 (upper digit) and a game start display LED79d, the former being composed of segments 1A to 1G and the latter being composed of segments 1P.
The digit 2a is composed of a storage number display LED 76 (lower digit) and an input display LED 79e, the former being composed of segments 1A to 1G and the latter being composed of segments 1P.

The digit 3a is composed of an acquired number display LED 78 (upper digit) and a replay display LED 79f. The former is composed of segments 1A to 1G, and the latter is composed of segments 1P.
The digit 4a is composed of an acquired number display LED 78 (lower digit) and an advantageous section display LED 77, the former is composed of segments 1A to 1G, and the latter is composed of segments 1P.
The digit 5a includes a set value display LED 73. Segment 1P of digit 5a is unused.
On the other hand, the digits 1b to 4b are the same as those in the 22nd embodiment (FIG. 143). The digit 5b is not provided in the 23rd embodiment.

FIG. 153 (A) is a diagram showing the relationship between the interrupt, the LED display counter (_CT_LED_DSP) value, and the digit signal and the segment signal in the 23rd embodiment. Further, FIG. 3B is a diagram showing an LED display request flag (_FL_LED_DSP). FIG. 153 is a diagram corresponding to FIG. 148 of the 22nd embodiment.
In the 23rd embodiment, an LED display counter that cycles once with 5 interrupts is used. Similar to the 22nd embodiment (FIG. 148), this LED display counter shifts the bit "1" to the right by one digit for each interrupt, and when it becomes "0", the initial value "00010000" at the time of the interrupt processing. ". As a result, as in the 22nd embodiment, the counter has one cycle with 5 interrupts.

As shown in FIG. 153 (A), when the interrupt is “1”, the digit 5 signal is output, and the set value display LED 73 becomes the LED to be lit.
Further, when the interrupt is "2", the digit 4 signal is output, and the lower digit of the acquired number display LED 78 and the numerical lower digit of the management information display LED 74 are targeted for lighting.
Furthermore, when the interrupt is "3", the digit 3 signal is output, and the upper digit of the acquired number display LED 78 and the numerical upper digit of the management information display LED 74 are targeted for lighting.
Further, when the interrupt is "4", the digit 2 signal is output, and the lower digit of the stored number display LED 76 and the lower information type of the management information display LED 74 are targeted for lighting.
Further, when the interrupt is "5", the digit 1 signal is output, and the upper digit of the stored number display LED 76 and the upper information type of the management information display LED 74 are targeted for lighting.

Further, as described above, among the status display LEDs 79, the 1-bet display LEDs 79a to the 3-bet display LEDs 79c are statically lit, and therefore are not LEDs to be lit during interrupt processing. Among the status display LEDs 79, the game start display LED 79d is assigned to the upper digit segment 1P of the stored number display LED 76, and the input display LED 79e is assigned to the lower digit segment 1P of the stored number display LED 76. Further, the replay display LED 79f is assigned to the upper digit segment 1P of the acquired number display LED 78. Further, the advantageous section display LED 77 is assigned to the lower digit segment 1P of the acquired number display LED 78, as in the 22nd embodiment (FIG. 143). Further, in the 23rd embodiment, as in the 22nd embodiment, the effect display LED 79g is not provided.

As described above, if the status display LED 79 and the advantageous section display LED 77 excluding the 1-bet display LED 79a to the 3-bet display LED 79c are assigned to the segment 1P of the digits 1a to 4a, the LED display counter having 5 interrupts per cycle is used. , The status display LED 79 and the advantageous section display LED 77 can be dynamically lit.

<24th Embodiment>
FIG. 154 is a diagram showing output ports 2 to 7 in the 24th embodiment, and is a diagram corresponding to FIG. 128 in the 20th embodiment.
In the 24th embodiment, two output ports (output ports 3 and 6) for outputting digit signals are provided, and two output ports (output ports 4 and 7) for outputting segment signals are further provided. It is characterized by.
In the 24th embodiment, the digits 1 to 9 are provided as in the 20th embodiment.
Further, the segments of digits 1 to 5 are designated as segments 1A to 1P.
Furthermore, the segments of digits 6 to 9 are designated as segments 2A to 2P.
The digit 5 may or may not be provided as in the 23rd embodiment. If the digit 5 is not provided, the D4 bit of the output port 3 becomes an empty bit. Then, in this case, as in the above, any one of the digits 1 to 4 is used as the set value display LED.

In the 24th embodiment, the 1-bet display signal to the 3-bet display signal are assigned to the D0 to D2 bits of the output port 2 as in the 20th embodiment.
The digit port includes an output port 3 that outputs digit 1 to 5 signals and an output port 6 that outputs digit 6 to 9 signals.
Further, the segment port includes an output port 4 for outputting the segments 1A to 1P signals corresponding to the digits 1 to 5 and an output port 7 for outputting the segments 2A to 2P signals corresponding to the digits 6 to 9.

Therefore, for example, when the digits 1 to 5 are turned on, the digit signal is output from the output port 3 and the segment 1 signal is output from the output port 4.
Further, when the digits 6 to 9 are turned on, the digit signal is output from the output port 7 and the segment 2 signal is output from the output port 6.

FIG. 155 is a diagram showing the relationship between the digit and the segment in the 24th embodiment. The relationship between the digits 1 to 5 and the segments 1A to 1P is the same as the relationship between the digits 1a to 5a and the segments 1A to 1P in the 23rd embodiment (FIG. 152).
Further, the relationship between the digits 6 to 9 and the segments 2A to 2P is the same as the relationship between the digits 1b to 4b and the segments 2A to 2P in the 23rd embodiment (FIG. 152).

FIG. 156 is a diagram showing Example 1 of the LED display counter according to the 24th embodiment. This LED display counter is the same as the LED display counter of the 23rd embodiment shown in FIG. 153 (A), and is a counter that cycles once with 5 interrupts.
Then, for example, the interrupt "1" outputs the digit 5 signal, and the interrupt "2" outputs the digit 4 signal and the digit 9 signal. Further, in the interrupt "3", a digit 3 signal and a digit 8 signal are output. Furthermore, the interrupt "4" outputs a digit 2 signal and a digit 7 signal. Further, the interrupt "5" outputs a digit 1 signal and a digit 6 signal.

FIG. 157 is a diagram showing Example 2 of the LED display counter according to the 24th embodiment. In this example 2, the LED display counter 1 is provided in the used area of the RWM 53, and the LED display counter 2 is provided outside the used area of the RWM 53.
The LED display counter 1 is a counter for outputting a digit 1 signal to a digit 5 signal for each interrupt, and is a counter having 5 interrupts in one cycle.
On the other hand, the LED display counter 2 is a counter for outputting the digit 6 signal to the digit 9 signal for each interrupt, and is a counter having four interrupts in one cycle.
As described above, the LED display counter for lighting the digits 1 to 5 and the LED display counter for lighting the digits 6 to 9 may be provided separately and independently. Further, since one cycle of the LED display counters of both is different, the lighting timing of the digits 1 to 5 and the lighting timing of the digits 6 to 9 are different. There is no particular problem even if the lighting timings are different.

FIG. 158 is a flowchart showing the LED display control (I_LED_OUT) in the 24th embodiment, and is a diagram corresponding to FIG. 134 in the 20th embodiment.
The LED display counter is assumed to be the above Example 1 (FIG. 156).
First, in step S1571, "0" is output from the output ports 3 and 4 in order to turn off the output ports 3 and 4. This is to turn off the digits 1 to 5 completely once.
Next, the process proceeds to step S1572, and “0” is output from the output ports 6 and 7 in order to turn off the output ports 6 and 7. This is to turn off the digits 6 to 9 completely.

In step S1573, the value is updated so that the bit "1" of the LED display counter is shifted to the right by one digit. In the next step S1574, it is determined whether or not the LED display counter is "0". If it is determined that it is not "0", the process proceeds to step S1436, and if it is determined that it is "0", the process proceeds to step S1475. In step S1475, the LED display counter is initialized. That is, as shown in FIG. 156, the value is set to "00010000". Then, the process proceeds to step S1436.

The following steps S1436 to S1451 are the same as in FIG. 134 (20th embodiment).
In the 24th embodiment, as shown in FIG. 156, the 1-bet display LED 79a to the 3-bet display LED 79c perform static lighting, and thus do not have the process of step S1453 in FIG. 134.
Further, when "No" is obtained in the determination of step S1451, it means that there is a display request for the acquired lower digit, so there is no determination branch as to whether or not there is a display request for the acquired lower digit, and step S1454. Proceed to. Steps S1454 to S1457 are the same as in FIG. 133 (20th embodiment).
After step S1457, the process proceeds to step S1576, and a digit (any of digits 1 to 5) signal is output from the output port 3 and a segment 1 signal is output from the output port 4. Then, the process proceeds to step S1577.

FIG. 159 is a flowchart showing the ratio display process (S_LED_OUT) in the 24th embodiment, and is a diagram corresponding to FIG. 135 of the 20th embodiment.
If it is determined in step S1472 that there is a ratio display request, the process proceeds to step S1475 in the same manner as in the 21st embodiment (FIG. 141).
The processing from step S1475 to step S1486 is the same as in FIG. 135 (20th embodiment). After step S1486, the process proceeds to step S1581, the digit signal is output from the output port 6, and the segment 2 signal is output from the output port 7. Then, the process returns to step S1460 of FIG. 158.

Although the 20th to 24th embodiments have been described above, the present invention is not limited to the above embodiments, and various modifications such as the following are possible.
(1) In the above embodiment, the LED display control (I_LED_OUT) program is stored in the used area, and the ratio display processing (S_LED_OUT) program is stored outside the used area. The reason for setting in this way is to prevent pressure on the capacity in the used area. Therefore, if there is a margin in the used area, the ratio display processing (S_LED_OUT) program can be stored in the used area.
Similarly, the data table outside the used area shown in FIG. 127 can also be stored in the used area.
That is, the program and data for controlling the lighting of the management information display LED 74 do not necessarily have to be stored outside the used area.

In general, a program for preventing fraud (goto) may be stored outside the used area. Since it can be said that the display of management information such as the advantageous section ratio is for fraud prevention, it is stored outside the used area in the above embodiment.
In addition to the above, the programs stored outside the used area include the set value error (outside the set value range) determination program used in the process of step S1408 in FIG. 133 and the random number abnormality used in the process of step S1410. Examples include a check program and a backflow check program for medal selectors.

(2) Taking the 20th embodiment as an example, for example, as shown in FIGS. 134 and 135, the LED display control (I_LED_OUT) (lighting control of digits 1 to 5) is first executed, and then the ratio display process is performed. (S_LED_OUT) (lighting control of digits 6 to 9) was executed, but the order is not limited to this. For example, after executing the ratio display process (S_LED_OUT) which is the lighting control outside the used area, it is possible to shift to the LED display control (I_LED_OUT) which is the lighting control inside the used area.

(3) The segment P (or segment 2P) of the digits 6 to 9 (in the 23rd embodiment, the digits 1b to 4b) is a segment to be turned on when an unrecoverable error occurs.
However, the present invention is not limited to this, and the segment may be set to light when a predetermined condition other than the unrecoverable error is satisfied. Alternatively, the segment can be physically present but unused.

<25th Embodiment>
In the 25th embodiment, when a specific symbol combination (combination of symbols in which "cherry" stops in the left middle row when the left reel 31 is stopped: middle row cherry) becomes a stopable lottery result (small winning combination E1 winning). Always shifts to the advantageous section and indicates that the section is advantageous by the advantageous section display LED 77.

Further, in the 25th embodiment, when 1BBA is won, it is possible to shift to the advantageous section, and when 1BBB is won, it does not shift to the advantageous section. Further, the winning probability of 1BBA is set to be the same for all the set values, and the winning probability of 1BBB is set to increase as the set value increases. As a result, the probability of transition to the advantageous section at the time of winning 1BB (total of 1BBA and 1BBB) increases as the set value decreases.

Furthermore, in the 25th embodiment, when the advantageous section ends, the first initialization process (initialization process at the end of the advantageous section) is executed, and when the set value is changed, the second initialization process is executed. (Initialization process when changing settings) is executed. Further, in the first initialization process, the RT shifts to the normal section while maintaining the RT at the end of the advantageous section, and in the second initialization process, the RT shifts to the non-RT and shifts to the normal section. Further, in the first initialization process and the second initialization process, the information regarding the advantageous section is cleared. As a result, the time when the first initialization process is executed and the time when the second initialization process is executed shift to the normal section in which the information regarding the advantageous section is the same.

Further, in the 25th embodiment, when the instruction function is operated at least once in the advantageous section, the advantageous section can be terminated. Further, in the advantageous section, when 1BB (1BBA or 1BBB) is won before the operation of the first instruction function, the advantageous section can be ended without operating the instruction function. Then, after shifting to the advantageous section, until the specific condition is satisfied, the instruction function is activated even if the game has an advantageous operation mode of the stop switch 42 (the game when the push order bell (small winning combination B group) is won). I won't let you.

FIGS. 160 to 167 are diagrams showing the number of accessory condition devices and winning and replay condition devices for each RT, and correspond to FIGS. 17 and 18 in the first embodiment.
Dividing the numerical values shown in FIGS. 160 to 167 by "65536" gives the winning probability. For example, in FIG. 160, the number of units for which 1 BBA is independently won is set to "70" in both non-RT and RT1 to RT3. Therefore, the probability of winning 1BBA alone is "70/65536".

FIG. 160 is a table of number of condition devices that can be set in common and can be shifted to an advantageous section, and corresponds to FIG. 17 of the first embodiment.
Here, "common setting" means that there is no setting difference, that is, that the settings 1 to 6 have the same number, which is the same as that of the first embodiment.
Further, in FIG. 160, in the normal section, "○" means to shift to the advantageous section, "x" means not to shift to the advantageous section, and in the advantageous section, "△" means the game of the advantageous section. It is the same as in FIG. 17 of the first embodiment that the number of times can be added and the “x” means that the number of games in the advantageous section is not added.

In FIG. 17 of the first embodiment, 1BBA has a case of winning a single winning combination, a case of winning a duplicate winning combination with the small winning combination D, and a case of winning a duplicate winning combination with the small winning combination E1. Only a single win is made, and there is no case where a small role and a duplicate win are made. As shown in FIG. 160, the number of units for which 1 BBA is independently won is "70" for all settings.
Further, in FIG. 17 of the first embodiment, the small winning combination E1 has a case of winning a single winning combination and a case of winning a duplicate with 1BBA, but in the 25th embodiment, the small winning combination E1 only wins a single winning combination. , There is no case of duplicate winning with a special role.

Furthermore, in FIG. 17 of the first embodiment, when the small winning combination E1 is won, there are a time when the normal section shifts to the advantageous section and a time when the normal section does not shift to the advantageous section. When the winning combination E1 is won, the section always shifts from the normal section to the advantageous section. As shown in FIG. 160, the number of single wins for the small winning combination E1 is "1000" for all settings. Then, in the normal section, when the small winning combination E1 is won, the section always shifts to the advantageous section.

Further, the small winning combination D is divided into a number that shifts from the normal section to the advantageous section and a number that does not shift from the normal section to the advantageous section, as in FIG. 17 of the first embodiment. As shown in FIG. 160, the total number of single winnings of the small winning combination D is "550", of which the number of positions that shift from the normal section to the advantageous section is "50", from the normal section to the advantageous section. The number that does not shift is "500". That is, in the normal section, when the small winning combination D is won alone, if the number "50" is won, the section shifts to the advantageous section, but if the number "500" is won, , Do not shift to advantageous section.

161 to 167 are table numbers of condition devices that do not shift to the advantageous section and do not add the advantageous section, and correspond to FIG. 18 of the first embodiment.
In FIG. 18 of the first embodiment, the number of settings 1 and 6 is shown as a representative, but in the 25th embodiment, the number of settings for each of the set values of settings 1 to 6 is shown.
Further, in the 25th embodiment, the transition to the advantageous section or the addition of the advantageous section is limited to the time when the condition device shown in FIG. 160 is won, and when the condition device shown in FIGS. However, it does not shift to the advantageous section and does not add the advantageous section.

FIG. 161 illustrates the number of settings 1 to 6 at the time of non-RT. Similarly, FIG. 162 illustrates the number of settings 1 to 6 at RT1, FIG. 163 illustrates the number of settings 1 to 6 at RT2, and FIG. 164 shows setting 1 at RT3. ~ The number of settings 6 is illustrated, and FIG. 165 illustrates the number of settings 1 to 6 at RT4.
Further, FIG. 166 illustrates the number of settings 1 to 6 during the 1BBA game (when 1BBA is operating), and FIG. 167 shows the number of settings 1 to 6 during the 1BBB game (when 1BBB is operating). Shown.

In FIG. 18 of the first embodiment, 1BBA is elected in duplicate with the small winning combination E2 with a different probability for each set value. Further, 1BBB has a case where a single winning is won and a case where a small winning combination D and a duplicate winning are won with different probabilities for each set value.
On the other hand, in the 25th embodiment, as shown in FIG. 160, as shown in FIG. There is no such thing. Further, as shown in FIGS. 161 to 164, 1BBB only wins independently with a different probability for each set value, and does not have a case of overlapping winning with a small winning combination.

As described above, in the 25th embodiment, the number of accessory condition devices and the winning and replay condition devices for each RT is defined as shown in FIGS. 160 to 167.
Therefore, in the 25th embodiment, when the small winning combination D (watermelon) is won by the winning combination lottery means 61, the section shifts to the advantageous section and the advantageous section display LED 77 lights up (indicates that the section is advantageous). ), And the advantageous section display LED 77 does not light (does not indicate that it is an advantageous section).
On the other hand, when the small winning combination E1 (middle-stage cherry) is won by the winning combination lottery means 61, the section always shifts to the advantageous section and the advantageous section display LED 77 lights up.

Further, when the small winning combination D is won by the winning combination lottery means 61, the transition to the advantageous section is made, and the advantageous section display LED 77 is turned on, the transition to the designated game section and the non-shifting to the designated game section are performed. Has.
Further, even when the small winning combination E1 is won by the winning combination lottery means 61, the transition to the advantageous section is made, and the advantageous section display LED 77 is turned on, the transition to the designated game section and the transition to the designated game section are not performed. Has.

FIG. 168 (a) is a diagram showing the transition to the advantageous section at the time of winning the rare combination in the first embodiment and the presence / absence of lighting of the advantageous section display LED 77, and FIG. 168 (b) is a diagram at the time of winning the rare combination in the 25th embodiment. It is a figure which shows the presence / absence of the advantageous section transition and the advantageous section display LED 77 lighting.
As shown in FIG. 168 (a), in the first embodiment, when the small winning combination E1 (middle-tier cherry) is won by the winning combination lottery means 61, there is a probability of "250/65536" that the section shifts to the advantageous section and the section is changed to the advantageous section. The advantageous section display LED 77 lights up, but the probability of "750/65536" does not shift to the advantageous section, and the advantageous section display LED 77 does not light up.

Similarly, in the first embodiment, when the small winning combination D (watermelon) is won by the winning combination lottery means 61, there is a probability of "50/65536" that the interval shifts to the advantageous section and the advantageous section display LED 77 lights up. , With a probability of "500/65536", the advantageous section does not shift and the advantageous section display LED 77 does not light.
Here, in the game in which the small winning combination E1 is won, the "cherry" (that is, the "middle cherry") can be stopped in the left middle stage when the left reel 31 is stopped. In addition, if the small winning combination E1 is won, there is a case where the game shifts to the designated game section. Therefore, when the middle cherry stops, the player expects to shift to the designated game section. As described above, the small role E1 is a rare role with a high degree of expectation of transition to the designated game section.

However, when the small winning combination E1 is won, if the time of shifting to the advantageous section and the time of not shifting to the advantageous section are provided, in the game in which the small winning combination E1 is won, depending on whether or not the advantageous section display LED 77 is lit, the advantageous section is set. The player knows whether or not to make the transition. In this case, it is not possible to maintain the player's expectation for the transition to the designated game section by winning the small role E1.
On the other hand, if the small winning combination E1 is always shifted to the advantageous section and the small winning combination E1 is always shifted to the designated gaming section in this advantageous section, the small winning combination E1 winning means the transition to the designated gaming section, and the game is played. It becomes monotonous.

Therefore, in the 25th embodiment, as shown in FIG. 168 (b), the small winning combination E1 (middle-tier cherry) is won by the winning combination lottery means 61 with a probability of "1000/65536", and at this time, the advantageous section is always used. And the advantageous section display LED 77 lights up.
Further, when the small winning combination E1 is won by the winning combination lottery means 61 to shift to the advantageous section and the advantageous section display LED 77 lights up, there is a probability of "64/256" to shift to the indicated game section (AT). However, there is a probability of "192/256" that the game does not shift to the indicated game section. As a result, the probability of transition to the indicated game section (AT) when the middle cherry can be stopped is 25%.

In this way, it can be seen that when the small winning combination E1 (middle-stage cherry) is won, it always shifts to the advantageous section and by turning on the advantageous section display LED 77, it shifts to the advantageous section. Since it is not known whether or not it is, it is possible to give the player a sense of expectation for the transition to the indicated game section over a plurality of games.

Further, as shown in FIG. 168 (b), when the small winning combination D (watermelon) is won by the winning combination lottery means 61, the advantage section is shifted to the advantageous section with a probability of "50/65536", and the advantageous section display LED 77 is displayed. Although it lights up, there is a probability of "500/65536" that it does not shift to the advantageous section and the advantageous section display LED 77 does not light up.
Further, when the small winning combination D is won by the winning combination lottery means 61 to shift to the advantageous section and the advantageous section display LED 77 lights up, the winning combination is shifted to the indicated game section (AT) with a probability of "32/256". However, there is a probability of "224/256" that the game does not shift to the indicated game section.

In this way, when the small winning combination D (watermelon) is won, the player can be notified whether or not to shift to the advantageous section depending on whether or not the advantageous section display LED 77 is lit. Further, when the small winning combination D is won and the advantageous section shifts to the advantageous section and the advantageous section display LED 77 lights up, it is not known whether or not to shift to the indicated game section. Can be given to the player over a plurality of games.

Further, in the 25th embodiment, when the small winning combination E1 (middle-stage cherry) is won by the winning combination lottery means 61, the AT determines whether or not to shift to the instruction game section (AT) separately from the winning combination lottery means 61. A lottery (two-stage lottery) will be held.
Furthermore, when the small winning combination D (watermelon) is won with the number "50", the AT lottery is performed in the same manner as when the small winning combination E1 is won.
In the 25th embodiment, an AT lottery counter that counts in the range of "0" to "255" as one cycle is provided on the main control board 50. Then, the AT lottery is performed using the 1-byte random value acquired from the AT lottery counter.

In addition, when the small winning combination E1 is won, if the player wins the AT lottery (decided to shift to the designated game section), the designated game section is selected until the predetermined number of games (for example, 32 games) is exhausted after shifting to the advantageous section. When the predetermined number of games is exhausted without shifting to, the game shifts to the indicated game section. That is, after shifting to the advantageous section, until the predetermined number of games is exhausted, it is in the omen (this precursor), and when the predetermined number of games is exhausted, the AT is entered.
On the other hand, when the small winning combination E1 is won and the AT lottery is not won (decided not to shift to the instruction game section), the advantageous section can be ended by operating the instruction function at least once. It will be possible. In other words, it is a so-called ghost sign.

In addition, even when the small winning combination D is won with the number "50" and the AT lottery is won, the predetermined number of games after the transition to the advantageous section is the same as when the small winning combination E1 is won in the AT lottery. After a precursor (this precursor), it rushes into AT.
Furthermore, when the small role D is won with the number "50" and the AT lottery is not won, the so-called Gase precursor is the same as when the small role E1 is won and the AT lottery is not won. It becomes.

In this way, for the winning combination (small winning combination E1) with high expectation of transition to the designated gaming section (AT), the advantageous section display LED 77 is always turned on at the time of winning, regardless of whether or not the transition to the designated gaming section (AT) is performed. By designing to play a game (a sign of this or a sign of a ghost) in an advantageous section, it is possible to give the player a sense of expectation for the transition to the designated game section over a plurality of games.
On the other hand, for a combination (small combination D) with a low expectation of transition to the instruction game section (AT), it is designed to have a case where the advantageous section display LED 77 is turned on and a case where it is not turned on at the time of winning. , It is possible to prevent the player from having an excessive expectation for the transition to the indicated game section.

Further, in the 25th embodiment, when the small winning combination D is won with the number "50", the transition to the designated game section is made based on the result of the AT lottery as in the case of winning the small winning combination E1. Although it is designed to have a case where it is not performed, it may be designed so that when the small winning combination D is won in the number "50", the game always shifts to the designated game section.
In this case, the advantageous section display LED77 is always turned on at the time of winning, and the small winning combination E1 that can incite the transition to the indicated game section in the game (main omen or gase omen) in the advantageous section and the advantageous section display LED77 at the time of winning. The role of the small winning combination D, which can immediately determine whether or not to shift to the indicated game section depending on the presence or absence of lighting, becomes clearer, and a sharp game playability can be designed.

FIG. 169 is a diagram showing the 1BB winning probability and the advantageous section transition probability at the time of 1BB winning for each set value in the 25th embodiment.
In the 25th embodiment, there are two types of special roles, 1BBA and 1BBB.
Further, in the 25th embodiment, when 1BBA is won in the normal section, the section always shifts to the advantageous section. On the other hand, in the normal section, when 1BBB is won, the section does not shift to the advantageous section.

Furthermore, in the 25th embodiment, as shown in FIG. 160, the number of 1BBA winning numbers is set to "70" in common for both non-RT and RT1 to RT3.
Therefore, as shown in FIG. 169, the winning probability of 1BBA is "70/65536" in both non-RT and RT1 to RT3. That is, the winning probability of 1BBA is set to be the same for all set values.

Further, in the 25th embodiment, as shown in FIGS. 161 to 164, the number of 1BBB winning numbers is "80" when the setting is 1 and "80" when the setting is 1 in any of the non-RT and RT1 to RT3. Is set to "88", setting 3 is set to "96", setting 4 is set to "104", setting 5 is set to "112", and setting 6 is set to "120".
Therefore, the winning probability of 1BBB is as shown in FIG. 169, and increases as the set value increases.

Further, in the 25th embodiment, the total value of the number of units that wins 1BB, that is, the number of units that wins 1BBA and the number of units that wins 1BBB is "150" when setting 1 and "158" when setting 2. , "166" for setting 3, "174" for setting 4, "182" for setting 5, and "190" for setting 6.
Therefore, the winning probability of 1BB (the winning probability of 1BBA and 1BBB in total) is as shown in FIG. 169, and increases as the set value increases.

Therefore, the probability of transition to the advantageous section at the time of winning 1BB is (70 ÷ 150 × 100 ≈) “46.7”% at the time of setting 1. Similarly, setting 2 is "44.3"%, setting 3 is "42.2"%, setting 4 is "40.2"%, and setting 5 is "38.5"%. , When the setting is 6, it becomes "36.8"%.
That is, the probability of transition to the advantageous section at the time of winning 1BB increases as the set value decreases.

Here, in the slot machine 10, as the set value increases, the winning probability of the special combination (1BB) generally increases.
However, when a special role is won, in addition to making it possible to shift to a special game, if it is possible to shift to an advantageous section, the difference in the player's advantage between the low setting and the high setting becomes large. It may be too much.

Therefore, in the 25th embodiment, as shown in FIG. 169, the winning probability of 1BBA that can shift to the advantageous section is made the same for all the set values, and the winning probability of 1BBB that does not shift to the advantageous section becomes higher. I try to get higher according to.
As a result, the winning probability of 1BB, that is, the winning probability of 1BBA and 1BBB in total increases as the set value increases, and the transition probability to the advantageous section at the time of winning 1BB increases as the set value decreases. Become. Therefore, it is possible to prevent the difference in the player's advantage from becoming too large between the low setting and the high setting.

Further, the winning probability of 1BB increases as the set value increases, but the transition probability to the advantageous section at the time of winning 1BB increases as the set value decreases. Even though there is no setting difference, it is possible to give the player the impression that there is a setting difference in the transition probability to the advantageous section.

Furthermore, the player can be made to estimate the set value from the probability of transition to the advantageous section at the time of winning 1BB. That is, it is possible to provide the player with an element for estimating the set value.
Further, the decision not to shift to the advantageous section originally disappoints the player, but the higher the probability of deciding not to shift to the advantageous section when 1BB is won, the higher the set value is. Therefore, even if it is decided not to shift to the advantageous section at the time of winning 1BB, the player can be expected to have a high set value, and the player can not be disappointed.

Further, when the instruction function is operated at least once in the advantageous section, the advantageous section can be terminated. In particular, in an advantageous section that does not shift to the instruction game section (AT), the instruction function is activated at least once in order to enable the end of the advantageous section.
Here, the "operation of the instruction function at least once" is a condition device (small combination B group) capable of acquiring the maximum number of payouts ("9") among the games having an advantageous operation mode of the stop switch 42. It is necessary to play in the game that won the prize.
Therefore, even if the instruction function is activated when the small winning combination C group is won (up to 3 cards), it does not correspond to "operation of the instruction function at least once".
Hereinafter, when the push order bell of the small winning combination B group is meant, it is described as "pushing order bell (small winning combination B group)".

It should be noted that the operation of the instruction function at least once, which is required to enable the termination of the advantageous section having no instruction game section, may be referred to as "collateral navigation" or the like.
Further, when the special combination (1BBA or 1BBB) is won before the operation of the first instruction function, it is possible to end the advantageous section without operating the instruction function.
In the 25th embodiment, as a special combination, only 1BB (type 1 accessory continuous operation device) is provided, and 2BB (type 2 accessory continuous operation device) is not provided, but the first instruction function is provided. Even if 2BB is won before the operation, it is possible to end the advantageous section without operating the instruction function.

Further, the "one-time instruction determination flag" is a flag indicating that the instruction function has been activated at least once to enable the end of the advantageous section.
A storage area for storing the instruction determination flag once is provided on the RWM 53.
Then, when the one-time instruction determination flag is on, "1" is stored in the storage area of the one-time instruction determination flag on the RWM53, and when the one-time instruction determination flag is off, "0" is stored. ..

FIG. 170 is a flowchart showing the flow of the instruction function operation process according to the 25th embodiment.
Proceeding to the instruction function operation process of FIG. 170, first, in step S2001, the main CPU 55 determines whether or not the push order bell (small winning combination B group) has been won. Here, if it is determined that the push order bell (small role B group) has been won, the process proceeds to the next step S2002. On the other hand, if it is determined that the push order bell (small winning combination B group) has not been won, the process according to this flowchart ends.

In the next step S2002, the main CPU 55 determines whether or not the user is staying in the advantageous section. Here, if it is determined that the user is staying in the advantageous section, the process proceeds to the next step S2003. On the other hand, if it is determined that the user is not staying in the advantageous section (staying in the normal section), the process according to this flowchart is terminated.
Proceeding to step S2003, the main CPU 55 determines whether or not the player is staying in the designated game section (AT). Here, when it is determined that the player is staying in the designated game section, the process proceeds to the next step S2004. On the other hand, when it is determined that the player is not staying in the designated game section, the process proceeds to step S2007.

In step S2004, the main CPU 55 activates the instruction function to display the push order instruction information on the acquisition number display LED 78. At this time, on the sub-control board 80 side, the image display device 23 notifies the correct answer pressing order. Then, the process proceeds to the next step S2005.
Proceeding to step S2005, the main CPU 55 determines whether or not the end condition of the advantageous section is satisfied. Specifically, the number of games played in the advantageous section was exhausted (the count value of the advantageous section counter 69a became "0"), and the instruction function was activated at least once (the correct answer pressing order was notified at least once). ) Or whether or not the special role (1BBA or 1BBB) was won. Here, when it is determined that the end condition of the advantageous section is satisfied, the process proceeds to the next step S2006. On the other hand, when it is determined that the end condition of the advantageous section is not satisfied, step S2006 is skipped and the process according to this flowchart is ended.

In step S2006, the main CPU 55 executes an initialization process (RAM clear process) at the end of the advantageous section. In the initialization process at the end of the advantageous section, the information regarding the advantageous section including the one-time instruction determination flag, which is stored in the storage area on the RWM 53, is cleared. Then, when the initialization process at the end of the advantageous section is executed, the process according to this flowchart ends.
In step S2007, the main CPU 55 determines whether or not the special combination (1BBA or 1BBB) has been won. Here, when it is determined that the special role has been won, the process proceeds to the next step S2008. On the other hand, when it is determined that the special role has not been won, step S2008 is skipped and the process proceeds to step S2005.

In step S2008, the main CPU 55 turns on the instruction determination flag once. Specifically, in step S2008, the main CPU 55 does not operate the instruction function, but sets "1" in the storage area of the one-time instruction determination flag on the RWM 53. Then, the process proceeds to step S2005.
In step S2009, the main CPU 55 determines whether or not the value of the storage area of the one-time instruction determination flag on the RWM 53 is “1”. Here, when it is determined to be "1", that is, once it is determined that the instruction determination flag is on, the process according to this flowchart is terminated. On the other hand, when it is "0", that is, when it is determined that the instruction determination flag is off once, the process proceeds to the next step S2010.

In step S2010, the main CPU 55 determines whether or not the specific condition (one-time instruction operation condition) is satisfied.
Here, the "one-time instruction operation condition" is a condition for permitting the operation of the instruction function at least once so that the advantageous section can be terminated.
In the 25th embodiment, as the "one-time instruction operation condition", "the predetermined number of games (for example," 15 games ") has been digested after the transition to the advantageous section" is defined.
Further, in the 25th embodiment, a digestion game number counter for counting the number of games after the transition to the advantageous section is provided on the main control board 50.

Then, in step S2010, the main CPU 55 determines whether or not the count value of the digestion game count counter is equal to or greater than a predetermined value (for example, “15”), and when it is determined that the count value is equal to or greater than the predetermined value, the main CPU 55 gives an instruction once. It is determined that the operating conditions are satisfied, and the process proceeds to the next step S2011. On the other hand, when it is determined that the value is less than the predetermined value, it is determined that the instruction operating condition is not satisfied once, and the process according to this flowchart is terminated.

Proceeding to step S2011, the main CPU 55 activates the instruction function to display the push order instruction information on the acquisition number display LED 78. Further, the operation of the instruction function in step S2011 is for enabling the end of the advantageous section. At this time, on the sub-control board 80 side, the image display device 23 notifies the correct answer pressing order. Then, when the instruction function is activated, the process proceeds to the next step S2012.
In step S2012, the main CPU 55 sets “1” in the storage area of the one-time instruction determination flag on the RWM 53. Then, the process proceeds to step S2005.

FIG. 171 is a time chart showing an example in which the instruction function is activated when the first push order bell (small winning combination B group) is won after shifting to an advantageous section having no instruction game section (AT).
An advantageous section that does not have an instruction game section can be terminated if the instruction function is activated at least once or if a special combination is won before the first operation of the instruction function.
As shown in FIG. 171, even if the push order bell (small winning combination B group) is won, the instruction function is not activated before the transition to the advantageous section. Then, after the transition to the advantageous section, the instruction function is activated by the game in which the push order bell (small winning combination B group) is first won. At this time, the instruction determination flag is turned on once on the main control board 50 side, and the correct answer pressing order is notified by the image display device 23 on the sub control board 80 side.

Further, when the instruction determination flag is turned on once, the state in which the instruction determination flag is turned on is maintained until the end of the advantageous section.
Further, when the instruction determination flag is turned on once, the instruction function is not activated even if the push order bell (small winning combination B group) is won.
Then, when the end condition of the advantageous section is satisfied, the advantageous section is ended and the initialization process (RAM clear process) at the end of the advantageous section is executed to turn off the instruction determination flag once.

FIG. 172 is a time chart showing an example in which the operation of the instruction function is canceled by winning a special combination before the operation of the first instruction function after shifting to the advantageous section having no instruction game section.
As shown in FIG. 172, even if the push order bell (small winning combination B group) is won, the instruction function is not activated before the transition to the advantageous section. Then, in FIG. 172, after the transition to the advantageous section, before the first push order bell (small winning combination B group) is won, that is, before the first operation of the instruction function, the special winning combination is won. At this time, the instruction function is not activated, but the instruction determination flag is turned on once. After that, the instruction determination flag remains on once until the advantageous section ends.

Also, when a special role is won, the special role winning information is turned on, and when the winning special role wins, the special role winning information is turned off. Furthermore, from the time when the special role is won until the prize is won, it is inside and the winning information of the special role is kept on.
Further, when the instruction determination flag is turned on once, the instruction function is not activated even if the push order bell (small winning combination B group) is won.
Then, when the end condition of the advantageous section is satisfied, the advantageous section is ended and the initialization process (RAM clear process) at the end of the advantageous section is executed to turn off the instruction determination flag once.

FIG. 171 shows an example in which the instruction function is activated when the first push order bell (small winning combination B group) is won after shifting to an advantageous section having no instruction game section (AT).
Here, in order to be able to end the advantageous section that does not have the designated game section at an early stage, at the earliest possible stage after shifting to the advantageous section that does not have the designated game section, when the push order bell (small role B group) is won. , It is preferable to activate the instruction function.

However, from the viewpoint of ball ejection design, in order to pay out as many game media (medals) as possible in the advantageous section having the designated game section, the payout of the game medium is suppressed as much as possible in the advantageous section not having the designated game section. Is preferable.
That is, the advantageous section that does not have the indicated game section is a game section that gives a sign that it is not necessary to pay out medals to the player when the push order bell (small role B group) is won, and the collateral navigation is executed in that game section. This means that the expected value of the number of medals to be paid out in the advantageous section having the designated game section must be set lower accordingly.
Therefore, in the 25th embodiment, even if the push order bell (small winning combination B group) is won until a specific condition (one-time instruction operation condition) is satisfied after shifting to an advantageous section that does not have the instruction game section. The instruction function is not activated. In addition, as the "one-time instruction operation condition", "the predetermined number of games (for example," 15 games ") has been exhausted after the transition to the advantageous section" is defined.

Here, as shown in FIG. 172, in the advantageous section having no instruction game section, when the special combination is won before the operation of the first instruction function, the advantageous section ends without operating the instruction function. It becomes possible to make it.
Therefore, even if the push order bell (small winning combination B group) is won, the instruction function is not activated until a specific condition (one instruction operation condition) is satisfied after shifting to an advantageous section that does not have an instruction game section. By doing so, it is possible to increase the probability of winning a special role before the first operation of the instruction function. As a result, the probability that the advantageous section can be ended without activating the instruction function can be increased, and by extension, the payout of the game medium can be suppressed as much as possible in the advantageous section that does not have the instruction game section. can.
In this way, by suppressing the payout of the game medium at unnecessary timing (advantageous section that does not have the designated game section: Gase omen), medals can be expected to be paid out at an appropriate timing (designated game section: AT). Ball design becomes possible.

Further, the number of games less than the number of games played in the advantageous section (initial value of the advantageous section counter 69a) can be defined as the number of games played under the one-time instruction operating condition. For example, "32 games" can be set as the number of games in the advantageous section, and "15 games" can be set as the number of games under the one-time instruction operation condition.
In this case, if the special combination is won before the number of games under the one-time instruction operation condition is exhausted, the advantageous section can be ended without operating the instruction function.
In addition, if the push order bell (small combination B group) is won after the number of games in the one-time instruction operation condition is exhausted and before the number of games in the advantageous section is exhausted, the instruction function can be activated at this time. Therefore, the advantageous section can be ended at the same time as the number of games played in the advantageous section is exhausted.

FIG. 173 is a time chart showing an example in which the instruction function is activated at the time of winning the first push order bell (small winning combination B group) after satisfying the instruction operation condition once in the advantageous section having no instruction game section. ..
As shown in FIG. 173, even if the push order bell (small winning combination B group) is won, the instruction function is not activated before shifting to the advantageous section. Further, even after shifting to the advantageous section, the instruction function is not activated even if the push order bell (small combination B group) is won until the instruction operation condition is satisfied once (the predetermined number of games are exhausted).

Then, after satisfying the instruction operation condition once, the instruction function is activated in the game in which the push order bell (small winning combination B group) is first won. At this time, the instruction determination flag is turned on once. After that, the state in which the instruction determination flag is turned on is maintained once until the end of the advantageous section.
Further, when the instruction determination flag is turned on once, the instruction function is not activated even if the push order bell (small winning combination B group) is won.
Then, when the end condition of the advantageous section is satisfied, the advantageous section is ended and the initialization process (RAM clear process) at the end of the advantageous section is executed to turn off the instruction determination flag once.

FIG. 174 is a time chart showing an example in which the operation of the instruction function is canceled by winning a special combination before the instruction operation condition is satisfied once in the advantageous section having no instruction game section.
As shown in FIG. 174, even if the push order bell (small winning combination B group) is won, the instruction function is not activated before shifting to the advantageous section. Further, even after shifting to the advantageous section, the instruction function is not activated even if the push order bell (small combination B group) is won until the instruction operation condition is satisfied once (the predetermined number of games are exhausted).
Then, in FIG. 174, the special combination is won before the instruction operation condition is satisfied once after shifting to the advantageous section. At this time, the instruction function is not activated, but the instruction determination flag is turned on once. After that, the instruction determination flag remains on once until the advantageous section ends.

Also, when a special role is won, the special role winning information is turned on, and when the winning special role wins, the special role winning information is turned off. Furthermore, from the time when the special role is won until the prize is won, it is inside and the winning information of the special role is kept on.
Further, when the instruction determination flag is turned on once, the instruction function is not activated even if the push order bell (small winning combination B group) is won. In FIG. 174, when the instruction determination flag is on once, the push order bell (small winning combination B group) is won three times, but the instruction function is not activated in any of the cases.
Then, when the end condition of the advantageous section is satisfied, the advantageous section is ended and the initialization process (RAM clear process) at the end of the advantageous section is executed to turn off the instruction determination flag once.

It should be noted that the "one-time instruction operating condition" is not limited to "the predetermined number of games has been exhausted after the transition to the advantageous section". For example, "the number of games played in the advantageous section has been exhausted (the count value of the advantageous section counter 69a has become" 0 ")" can be defined as the "one-time instruction operating condition".
Here, in the advantageous section having no designated game section, the number of games played in the advantageous section is exhausted (the count value of the advantageous section counter 69a becomes "0"), and the instruction function is activated at least once, or If you win a special role before the first instruction function is activated, you can finish it.
Further, for example, "32 games" can be set as the number of games in the advantageous section that does not have the designated game section.

FIG. 175 shows an example in which, in an advantageous section having no designated game section, after digesting the number of games in the advantageous section, the push order bell (small winning combination B group) is activated at the time of winning to end the advantageous section. It is a time chart.
As shown in FIG. 175, even if the push order bell (small winning combination B group) is won, the instruction function is not activated before shifting to the advantageous section. Further, even after shifting to the advantageous section, the instruction function is not activated even if the push order bell (small winning combination B group) is won until the number of games in the advantageous section (for example, "32 games") is exhausted.

Further, in FIG. 175, when the number of games played in the advantageous section is exhausted, the instruction function is not activated and the special role is not won. Therefore, even if the number of games played in the advantageous section is exhausted, the advantageous section is displayed. Does not end.
Then, in FIG. 175, after the number of games in the advantageous section is exhausted, the instruction function is activated by the game in which the push order bell (small winning combination B group) is first won. At this time, the instruction determination flag is turned on once. Then, when the instruction function is activated, the end condition of the advantageous section is satisfied. Therefore, by ending the advantageous section and executing the initialization process (RAM clear process) at the end of the advantageous section, the instruction is given once. Turn off the judgment flag.
In this case, when the instruction function is activated (notification of the correct answer pressing order is performed), the advantageous section ends, so that the player plays the game while expecting that the correct answer pressing order is not notified. Can be provided.

FIG. 176 is a time chart showing an example in which the operation of the instruction function is canceled by winning a special combination before the number of games in the advantageous section is exhausted in the advantageous section having no instruction game section.
As shown in FIG. 176, even if the push order bell (small winning combination B group) is won, the instruction function is not activated before shifting to the advantageous section. Further, even after shifting to the advantageous section, the instruction function is not activated even if the push order bell (small winning combination B group) is won until the number of games in the advantageous section (for example, "32 games") is exhausted.
Then, in FIG. 176, after shifting to the advantageous section, before the number of games played in the advantageous section is exhausted, the special role is won. At this time, the instruction function is not activated, but the instruction determination flag is turned on once. After that, the instruction determination flag remains on once until the advantageous section ends.

Also, when a special role is won, the special role winning information is turned on, and when the winning special role wins, the special role winning information is turned off. Furthermore, from the time when the special role is won until the prize is won, it is inside and the winning information of the special role is kept on.
Further, when the instruction determination flag is turned on once, the instruction function is not activated even if the push order bell (small winning combination B group) is won. In FIG. 176, when the instruction determination flag is on once, the push order bell (small winning combination B group) is won twice, but the instruction function is not activated in either case.

Then, in FIG. 176, since the special combination is won before the number of games played in the advantageous section is exhausted, the end condition of the advantageous section is satisfied when the number of games played in the advantageous section is digested. Therefore, when the number of games played in the advantageous section is exhausted, the instruction determination flag is turned off once by ending the advantageous section and executing the initialization process (RAM clear process) at the end of the advantageous section.
In this way, by defining "the number of games played in the advantageous section has been exhausted" as the "one-time instruction operation condition", the probability that the advantageous section can be ended without operating the instruction function can be reduced as much as possible. Can be high.

Further, here, although the content partially overlaps with that of the first embodiment, setting / changing of the set value will be described. To set / change the set value, the power switch 11, the setting key switch 12, and the setting switch 13 are used.
Specifically, when the power switch 11 is turned off and the setting key switch 12 is turned on (the setting key is rotated 90 degrees clockwise) and the power switch 11 is turned on, the main CPU 55 is changing the setting. That is, the mode is changed to the setting change mode. At this time, the main CPU 55 executes an initialization process (RAM clear process) at the time of setting change. Moreover, the normal start-up process is not performed.
The execution timing of the RAM clear process is not limited to the time when the setting change mode is changed (when the power switch 11 is turned on while the setting key switch 12 is turned on).
For example, the RAM clear process may be executed when the set value is confirmed (when the start switch 41 is turned on in the setting change mode), or when the setting change mode ends (when the setting key switch 12 is turned off in the setting change mode). When), the RAM clear process may be executed.

In the setting change mode, the main CPU 55 displays the current setting value on the setting value display LED 73.
Further, in the setting change mode, each time the setting switch 13 is operated (on) once, the main CPU 55 displays the set value by the set value display LED 73 ... → "1" → "2" → " 3 ”→“ 4 ”→“ 5 ”→“ 6 ”→“ 1 ”→“ 2 ”→ ...

Furthermore, when the start switch 41 is operated (on) in the setting change mode, the main CPU 55 determines the set value with the value displayed on the set value display LED 73. At this time, the main CPU 55 stores the set value data corresponding to the determined set value in the set value data storage area (_NB_RANK) on the RWM 53.
For example, when the set value is "1", the set value data "0" is stored in the set value data storage area (_NB_RANK). That is, when the set value is "N" (N is an integer of "1" to "6"), the set value data "N-1" is stored in the set value data storage area (_NB_RANK). As a result, the set value data "0" to "5" are stored in the set value data storage area (_NB_RANK).

Then, in the setting change mode, when the setting key switch 12 is turned off (the setting key is rotated 90 degrees counterclockwise), the game can be played with the changed set value.
Further, when the setting key switch 12 is turned from off to on (rotating the setting key 90 degrees clockwise) while the power switch 11 is on, the main CPU 55 shifts to the setting confirmation, that is, the setting confirmation mode. As described above, when only checking the set value, it is not necessary to turn on / off the power switch 11. During the setting confirmation, the current setting value is displayed on the setting value display LED 73 as in the case of changing the setting.

Further, in the 25th embodiment, the main CPU 55 executes the first initialization process when the advantageous section ends, and executes the second initialization process when the set value is changed.
Further, in the first initialization process, the lottery state (RT state) at the end of the advantageous section is maintained, and the section shifts to the normal section. In the second initialization process, the lottery state (non-RT) is set in advance. Shift and shift to the normal section.
Then, in the first initialization process and the second initialization process, the information regarding the advantageous section stored in the predetermined storage area in the RWM 53 is cleared. As a result, it shifts to the normal section in which the information regarding the advantageous section is the same when the first initialization process is executed and when the second initialization process is executed.

FIG. 177 shows the information on the RWM53 cleared by the initialization process (first initialization process) at the end of the advantageous section, the information on the RWM53 held even after the initialization process at the end of the advantageous section, and the initial stage when the setting is changed. It is a figure which shows the information on the RWM53 which is cleared by the conversion process (the second initialization process).
Information about the advantageous section is stored in the predetermined storage area on the RWM 53.
Further, examples of the information regarding the advantageous section stored on the RWM 53 include an advantageous section counter value, an AT counter value, an upper limit counter value, an additional counter value, an advantageous section flag, and a one-time instruction determination flag.

The advantageous section counter value indicates the number of games played in the advantageous section. When it is decided to shift to the advantageous section, the number of games determined at that time is set as the advantageous section counter value in the advantageous section counter 69a on the RWM53. In addition, the advantageous section counter value is decremented each time one game is digested in the advantageous section. Then, when the advantageous section counter value becomes "0", the advantageous section ends.
When the number of games played in the advantageous section is added in the advantageous section, the value corresponding to the added number is added to the advantageous section counter value.

The AT counter value indicates the number of games played in the indicated game section (AT). When it is decided to shift to the designated game section, the number of games determined at that time is set as the AT counter value. In addition, the AT counter value is decremented each time one game is digested in the indicated game section. Then, when the AT counter value becomes "0", the designated game section ends.
When the number of games in the designated game section is added in the designated game section, the value corresponding to the added number is added to the AT counter value.

The upper limit counter value indicates the upper limit number of games played in the advantageous section. At the start of the advantageous section, "1500" is set as the upper limit counter value in the upper limit counter 69b on the RWM 53. In addition, the upper limit counter value is decremented each time one game is digested in the advantageous section. Then, when the upper limit counter value becomes "0", the advantageous section and the indicated game section are terminated regardless of the advantageous section counter value and the AT counter value.
The additional counter value indicates the number of additional games in the indicated game section. Every time the number of games in the indicated game section is added, the number of additions is added to the counter value.

The advantageous section flag is a flag indicating that the advantageous section is in progress.
A storage area for storing the advantageous section flag is provided on the RWM 53.
Further, when the advantageous section flag is on, "1" is stored in the storage area of the advantageous section flag on the RWM53, and when the advantageous section flag is off, "0" is stored.
Then, when shifting to the advantageous section, the advantageous section flag is turned on. After that, the advantageous section flag is kept on until the end of the advantageous section, and the advantageous section flag is turned off at the end of the advantageous section.

The one-time instruction determination flag is a flag indicating that the instruction function has been activated at least once to enable the end of the advantageous section.
A storage area for storing the instruction determination flag once is provided on the RWM 53.
Further, when the one-time instruction determination flag is on, "1" is stored in the storage area of the one-time instruction determination flag on the RWM53, and when the one-time instruction determination flag is off, "0" is stored. ..
Then, in the advantageous section, when the first instruction function is activated, or when a special combination is won before the operation of the first instruction function, the one instruction determination flag is turned on. After that, the state in which the instruction determination flag is turned on is maintained until the end of the advantageous section, and the instruction determination flag is turned off at the end of the advantageous section.

Further, in the predetermined storage area on the RWM53, as information other than the information regarding the advantageous section, for example, the number of stored sheets data, the set value data, the RT state data, the internal middle flag, the accessory condition device number data, and the accessory operation. The status flag etc. are stored.
The stored number data is data indicating the number of stored sheets.
A storage area for stored number data is provided on the RWM 53. Then, data indicating the number of stored sheets (for example, "15" when the number of stored sheets is 15) is stored in the storage area of the number of stored sheets data.

The set value data is data indicating the set value.
As described above, the set value data is stored in the set value data storage area (_NB_RANK) on the RWM53.
The RT state data is data indicating the RT state (lottery state).
Here, a storage area (_NB_RT) for RT state data is provided on the RWM 53.
Then, in the storage area (_NB_RT) of the RT state data, data corresponding to RT, for example, "0" for non-RT, "1" for RT1, and so on are stored.

The internal medium flag is a flag indicating that the game is an internal game that carries over the winning information of the special role.
Here, a storage area (_FL_PRD_LOT) for the internal medium flag is provided on the RWM53. Then, "FF (H)" is stored in the storage area (_FL_PRD_LOT) of the internal flag when it is inside, and "0" is stored when it is not inside.

The accessory condition device number data is data indicating the accessory condition device number, that is, the type of the winning accessory condition device (special combination).
Here, a storage area (_NB_CND_BNS) for the accessory condition device number data is provided on the RWM 53. Then, when the character condition device is not won, "0" is stored in the storage area (_NB_CND_BNS) of the character condition device number data, and when any of the character condition devices is won, "0" is stored. A value (other than "0") corresponding to the accessory condition device number is stored.

The accessory operating state flag is a flag indicating the operating state of the accessory.
Here, a storage area (_FL_ACTION) for the accessory operating state flag is provided on the RWM 53. Then, when any of the accessories is activated, the bit of the storage area (_FL_ACTION) of the accessory operating state flag corresponding to the accessory is "1", and when the accessory is not activated, the bit is "0". It becomes.

As shown in FIG. 177, at the end of the advantageous section, the main CPU 55 executes the first initialization process. At this time, among the information stored in the storage area on the RWM53, the information regarding the advantageous section (advantageous section counter value, etc.) is cleared, but the predetermined information (RT state data, etc.) other than the information regarding the advantageous section is cleared. Hold without.
Further, in the 25th embodiment, "clearing the information stored in the storage area on the RWM53" means setting the value of the storage area on the RWM53 to "0".

Therefore, when the first initialization process (initialization process at the end of the advantageous section) is executed, the advantageous section counter value, the AT counter value, the upper limit counter value, the additional counter value, the advantageous section flag, and the one-time instruction on the RWM53 are instructed. The value of the storage area of the determination flag is "0".
On the other hand, even if the first initialization process is executed, the storage area of the stored number data, the set value data, the RT state data, the internal medium flag, the accessory condition device number data, and the accessory operating status flag on the RWM53. The value of is retained without being cleared.

Therefore, when the advantageous section ends and the first initialization process is executed, the process shifts to the normal section while maintaining the RT state at the end of the advantageous section. For example, if the user stays at RT3 at the end of the advantageous section, when the advantageous section ends and the first initialization process is executed, RT3 is maintained and the normal section is entered.
The process corresponding to the first initialization process is also performed in the third embodiment (FIGS. 43 to 52). For example, the process of steps S445 to S447 in FIG. 44 (e) corresponds to the first initialization process.

As shown in FIG. 177, when the setting is changed, the main CPU 55 executes the second initialization process. At this time, among the information stored in the storage area on the RWM53, the information regarding the advantageous section (advantageous section counter value, etc.) is cleared, and the predetermined information other than the information regarding the advantageous section (RT state data, etc.) is also cleared. ..

Therefore, when the second initialization process (initialization process at the time of setting change) is executed, the advantageous section counter value, the AT counter value, the upper limit counter value, the additional counter value, the advantageous section flag, and the one-time instruction determination on the RWM53 are executed. The value of the storage area of the flag is "0". In addition, the stored number data on the RWM53, the set value data, the RT state data, the internal medium flag, the accessory condition device number data, and the value of the storage area of the accessory operating status flag are all set to "0".
Therefore, when the set value is changed (including the resetting of the same set value) and the second initialization process is executed, the RT state shifts to the non-RT and shifts to the normal section. For example, if the user stays in RT3 before changing the set value, when the set value is changed and the second initialization process is executed, the process shifts to non-RT and shifts to the normal section.

Further, in both the first initialization process executed at the end of the advantageous section and the second initialization process executed at the end of the setting change, the information regarding the advantageous section stored in the storage area on the RWM 53 is cleared.
Therefore, the time when the first initialization process is executed and the time when the second initialization process is executed shift to the normal section in which the information regarding the advantageous section is the same.
Further, the "normal section in which the information regarding the advantageous section is in the same state" is the advantageous section counter value, AT counter value, upper limit counter value, additional counter value, advantageous section flag, and one-time instruction determination flag on the RWM53. It means a normal interval in which the values of the storage areas are all "0".

Here, each time the advantageous section ends, the ease of transition from the normal section to the advantageous section is changed, or when the advantageous section ends and when the set value is changed, the advantageous section from the normal section Different ease of transition to may impair fairness among players.
Therefore, in the 25th embodiment, both the first initialization process executed at the end of the advantageous section and the second initialization process executed at the end of the setting change relate to the advantageous section stored in the predetermined storage area on the RWM 53. Clear the information.
As a result, it is possible to make the ease of transition from the normal section to the advantageous section the same each time the advantageous section ends, and it is normal when the advantageous section ends and when the set value is changed. Since the ease of transition from the section to the advantageous section can be made the same, fairness among the players can be ensured.
<Modified example of the 25th embodiment>

Although the 25th embodiment has been described above, the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the 25th embodiment, whether or not to shift to the designated game section (AT) is determined by an AT lottery (two-stage lottery). However, it is not limited to this.
For example, when a predetermined condition is satisfied, for example, after winning a small winning combination E1 and shifting to an advantageous section, the number of times a predetermined winning combination has been won has reached the specified number of times, or the number of times a predetermined winning combination has been won has reached the specified number of times. In addition, it may be decided to shift to the designated game section.

(2) In FIG. 160, 1BBA has a common setting and has a probability of "70/65536" for a single win, and there is no case where a small win and a duplicate win are made. Further, the small winning combination E1 has a common setting and has a probability of "1000/65536", and there is no case where the small winning combination is won in duplicate with the special winning combination. However, it is not limited to this.
For example, a common setting has a probability of "40/65536" for a single win of 1BBA, a common setting with a probability of "30/65536" for a duplicate win of "1BBA + small winning combination E1", and a common setting of "1000/65536". There is a possibility that the small winning combination E1 will be won alone.

Here, when the small winning combination E1 is won alone, the middle-tier cherry can be stopped. Also, when the "1BBA + small role E1" is won twice, the middle cherry can be stopped. That is, both the single winning of the small winning combination E1 and the overlapping winning of "1BBA + small winning combination E1" are the lottery results in which the middle cherry can be stopped.
Then, when the small winning combination E1 is won alone, the section always shifts to the advantageous section and the advantageous section display LED77 lights up, and even when the "1BBA + small winning combination E1" is won twice, the advantageous section is always turned on. And the advantageous section display LED 77 is turned on.

In addition, when the small winning combination E1 is won independently and the section shifts to the advantageous section, the medal of the next game can be inserted (bet) and the settlement switch 46 can be operated (hereinafter, this timing is referred to as "predetermined timing". The advantageous section display LED 77 is turned on (timing 1 in FIG. 23).
On the other hand, when the "1BBA + small winning combination E1" is won in duplicate and the section shifts to the advantageous section, the advantageous section display LED 77 may be turned on by a predetermined timing, and the combination of symbols corresponding to 1BBA is displayed. The advantageous section display LED 77 may be turned on before this is done (timing 2 in FIG. 23).
Therefore, the lighting timing of the advantageous section display LED 77 may be the same or different depending on whether the small winning combination E1 is won alone or the "1BBA + small winning combination E1" is won twice.

Further, both when the small winning combination E1 is won alone and the section shifts to the advantageous section, and when the small winning combination E1 is won twice and the section shifts to the advantageous section, the instruction game section is transferred and the instruction is given. Have a time when it does not shift to the game section.
Even in this way, when the lottery result that the middle cherry can be stopped is obtained, the interval is always shifted to the advantageous section and the advantageous section display LED 77 is lit. Then, although it is known that the transition to the advantageous section is performed, it is not known whether or not the transition to the designated game section is performed. Therefore, it is possible to give the player a sense of expectation for the transition to the designated game section over a plurality of games.
When the player wins the "1BBA + small winning combination E1" in duplicate and shifts to the advantageous section, for example, at the end of the 1BBA game, it is possible to notify whether or not to shift to the designated game section.

(3) FIG. 178 (a) shows a modified example of the mathematical table (1) of FIG. 160, and FIG. 178 (b) shows the transition to the advantageous section at the time of winning the rare combination of FIG. 168 (b). It is a figure which shows the modification of whether or not the advantageous section display LED 77 is lit.
In FIG. 160, the number of single winnings of the small winning combination E1 is set to “1000” in common, and the number of single winnings of the small winning combination E2 is not defined. The number of winnings is set to "500" for the common setting, and the number of single winnings for the small winning combination E2 is also set to "500" for the common setting. Further, in FIG. 178 (a), when the small winning combination E1 is won, the normal section always shifts to the advantageous section, and when the small winning combination E2 is won, the normal section always shifts to the advantageous section.

Here, when the small winning combination E1 is won alone, the middle-tier cherry can be stopped, and when the small winning combination E2 is won alone, the middle-tier cherry can be stopped. That is, both the single winning of the small winning combination E1 and the single winning of the small winning combination E2 are the lottery results in which the middle cherry can be stopped.
Then, as shown in FIG. 178 (b), when the small winning combination E1 is won, the interval is always shifted to the advantageous section and the advantageous section display LED 77 is turned on.
Further, by winning the small winning combination E1, when the advantageous section shifts to the advantageous section and the advantageous section display LED 77 lights up, the probability shifts to the indicated game section (AT) with a probability of "128/256", but "128" With a probability of "/ 256", it does not shift to the indicated game section. As a result, the probability of transition to the indicated game section (AT) when the middle cherry can be stopped is 25%.
When the small winning combination E1 is won, whether or not to shift to the designated game section (AT) is determined by an AT lottery (two-stage lottery).

Further, as shown in FIG. 178 (b), even when the small winning combination E2 is won, as in the case of winning the small winning combination E1, the advantageous section is always shifted and the advantageous section display LED 77 lights up.
Further, when the small winning combination E2 is won to shift to the advantageous section and the advantageous section display LED 77 is turned on, the transition to the indicated game section is not performed.

In this way, when the small winning combination E1 is won and when the small winning combination E2 is won, the interval is always shifted to the advantageous section and the advantageous section display LED 77 is turned on. Further, when the small winning combination E1 is won, there are a time when the player shifts to the designated game section and a time when the player does not shift to the designated game section, and when the small winning combination E2 is won, the player does not shift to the designated game section.
Even in this way, when the lottery result is such that the middle cherry can be stopped, it is known that the section will shift to the advantageous section, but it will not be known whether or not the section will shift to the designated game section. It is possible to give the player a sense of anticipation for the transition of the game over a plurality of games.

(4) FIG. 179 (a) shows a modified example of the mathematical table (1) of FIG. 160, and FIG. 179 (b) shows the transition to the advantageous section at the time of winning the rare combination of FIG. 168 (b). It is a figure which shows the modification of whether or not the advantageous section display LED 77 is lit.
In FIGS. 178 and 179, the contents of the number table (1) in (a) are the same, but the contents of the advantageous section transition and the presence / absence of lighting of the advantageous section display LED 77 at the time of winning the rare combination in (b) are different.

As shown in FIG. 179 (b), when the small winning combination E1 is won, the interval is always shifted to the advantageous section and the advantageous section display LED 77 is lit.
Further, by winning the small winning combination E1, when the advantageous section shifts to the advantageous section and the advantageous section display LED 77 lights up, the probability shifts to the indicated game section (AT) with a probability of "64/256", but "192". With a probability of "/ 256", it does not shift to the indicated game section.

Furthermore, as shown in FIG. 179 (b), when the small winning combination E2 is won, the interval is always shifted to the advantageous section and the advantageous section display LED 77 is turned on.
Further, when the small winning combination E2 is won to shift to the advantageous section and the advantageous section display LED77 is turned on, there is a probability of "64/256" as in the case of winning the small winning combination E1. It shifts to AT), but does not shift to the designated game section with a probability of "192/256". As a result, the probability of transition to the indicated game section (AT) when the middle cherry can be stopped is 25%.
Whether or not to shift to the designated game section (AT) is determined by an AT lottery (two-stage lottery) regardless of whether the small winning combination E1 is won or the small winning combination E2 is won.

In this way, when the small winning combination E1 is won and when the small winning combination E2 is won, the interval is always shifted to the advantageous section and the advantageous section display LED 77 is turned on. , There is a time when it shifts to the designated game section and a time when it does not shift to the designated game section.
Even in this way, when the lottery result is such that the middle cherry can be stopped, it is known that the section will shift to the advantageous section, but it will not be known whether or not the section will shift to the designated game section. It is possible to give the player a sense of anticipation for the transition of the game over a plurality of games.

(5) FIG. 180 (a) shows a modified example of the mathematical table (1) of FIG. 160, and FIG. 180 (b) shows the transition to the advantageous section at the time of winning the rare combination of FIG. 168 (b). It is a figure which shows the modification of whether or not the advantageous section display LED 77 is lit.
In FIG. 180A, the number of single wins for the small winning combination E1 is set to "250" for the common setting, and the number of single winnings for the small winning combination E2 is set to "750" for the common setting. Further, in FIG. 180A, when the small winning combination E1 is won, the normal section always shifts to the advantageous section, and when the small winning combination E2 is won, the normal section always shifts to the advantageous section.

Further, as shown in FIG. 180 (b), when the small winning combination E1 is won, it always shifts to the advantageous section, and the advantageous section display LED 77 lights up, and even when the small winning combination E2 is won, it always shifts to the advantageous section. Moreover, the advantageous section display LED 77 lights up.
Further, by winning the small winning combination E1, the player shifts to the advantageous section, and whenever the advantageous section display LED 77 lights up, the player shifts to the indicated game section.
On the other hand, when the small winning combination E2 is won and the advantageous section shifts to the advantageous section and the advantageous section display LED 77 lights up, the transition to the indicated game section does not occur.
As a result, the probability of transition to the indicated game section (AT) when the middle cherry can be stopped is 25%.

In this way, when the small winning combination E1 is won and when the small winning combination E2 is won, the section is always shifted to the advantageous section and the advantageous section display LED77 is turned on. When the combination E2 is won, it is not allowed to shift to the designated game section.
Even in this way, when the lottery result is such that the middle cherry can be stopped, it is known that the section will shift to the advantageous section, but it will not be known whether or not the section will shift to the designated game section. It is possible to give the player a sense of anticipation for the transition of the game over a plurality of games.
Further, in any of the embodiments of FIGS. 168 (b), 178 (b), 179 (b), and 180 (b), the probability of transition to the indicated game section (AT) when the middle cherry can be stopped is It is 25%, and regardless of which aspect is adopted, the same effect can be exerted, and the same impression can be given to the player.

(6) In FIGS. 161 to 164, 1BBB is selected as a single winner, but the present invention is not limited to this.
For example, in FIGS. 161 to 164, instead of the single winning of 1BBB, a duplicate winning of "1BBA + small winning combination 34 (" Bell B "-" Red 7 "-" Red 7 ": 1 sheet)" may be used.

Specifically, in FIGS. 161 to 164, the number of duplicate winnings of "1BBA + small winning combination 34" is set to "80" in the case of setting 1, "88" in the case of setting 2, and "88" in the case of setting 3. Can be set to "96", set to "104" for setting 4, set to "112" for setting 5, and set to "120" for setting 6.
Even in this way, the winning probability of 1BB (the sum of the single winning and the overlapping winning of 1BBA) increases as the set value increases, and the transition probability to the advantageous section at the time of 1BB winning decreases the set value. It can be made higher according to.

(7) In FIG. 168 (b), when the small winning combination E1 (middle-stage cherry) is won, when the section shifts to the advantageous section and the advantageous section display LED77 lights up, there is a probability of "64/256" that the indicated game section ( It shifts to AT) and does not shift to the designated game section with a probability of "192/256". However, it is not limited to this.
For example, in FIG. 168 (b), the transition to the chance zone (CZ) may be made instead of the indicated game section (AT).

Specifically, in FIG. 168 (b), when the small winning combination E1 (middle-stage cherry) is won to shift to the advantageous section and the advantageous section display LED 77 lights up, there is a probability of "64/256". , It is possible to shift to the chance zone (CZ) and not to shift to the chance zone with a probability of "192/256".
Further, when the player shifts to the chance zone, there are a case where the player shifts to the designated game section (AT) (promotion) and a case where the player does not shift to the designated game section. For example, in the chance zone, if the transition condition to the designated game section is satisfied, the transition to the designated game section is performed, and if the transition condition to the designated game section is not satisfied, the advantageous section is terminated without shifting to the designated game section. Move to the normal section.

Further, as a condition for shifting from the chance zone to the designated game section, for example, the number of times a predetermined combination has been won has reached the specified number of times, and the number of times a predetermined number of winnings has been won has reached the specified number of times. can.
Even in this way, it can be seen that when the small winning combination E1 (middle-stage cherry) is won, it always shifts to the advantageous section and by turning on the advantageous section display LED 77, it shifts to the advantageous section, but it shifts to the instruction game section. Since it is not known whether or not to do so, it is possible to give the player a sense of expectation for the transition to the indicated game section over a plurality of games.

(8) In the 25th embodiment, as the "one-time instruction operating condition", "the predetermined number of games (for example," 15 games ") has been digested after the transition to the advantageous section" is defined, but the present invention is not limited to this. ..
For example, "the predetermined number of times the winning combination was won or won after the transition to the advantageous section", specifically, "the pushing order bell (small combination B group) was won or won five times after the transition to the advantageous section", "advantageous". "The replay has been won or won seven times after the section shift" can be defined as the "one-time instruction operating condition".

In addition, for example, "it was not won in the lottery held at a predetermined time after the transition to the advantageous section", specifically, "the probability of 50% when the push order bell (small winning combination B group) is won after the transition to the advantageous section". The lottery was held and the lottery was not won. ”“ Every time a game is played after the transition to the advantageous section, a lottery is held with a 70% probability of winning, and the lottery is not won. It is also possible to define "things" and the like as "one-time instruction operating conditions".

Furthermore, for example, "the conditions determined at the time of transition to the advantageous section were satisfied", specifically, "at the time of transition to the advantageous section, any of 10 games, 15 games, or 20 games was determined and determined by lottery." "The number of games has been exhausted", "At the time of transition to the advantageous section, any of 5, 7, or 10 times was decided by lottery, and then the number of times the push order bell (small role B group) was won was decided. "The number of times has been reached" and the like can also be defined as "one-time instruction operating condition".

Furthermore, for example, "the number of times the replay overlap (replay B group, replay C group) was won after the transition to the advantageous section reached 3 times," and "the freeze occurred after the transition to the advantageous section."", Etc. can also be defined as a" one-time instruction operating condition ".
Of course, each of the above conditions can be appropriately combined and defined as a "single instruction operating condition".

(9) In the 25th embodiment, when the setting is changed, the second initialization process (initialization process when the setting is changed) is executed to add the advantageous section counter value, AT counter value, upper limit counter value, and addition on the RWM53. The counter value, the advantageous section flag, the one-time instruction judgment flag, the RT state data, the number of stored sheets data, the internal medium flag, the accessory condition device number data, and the accessory operating status flag were cleared. However, it is not limited to this.

For example, when the setting is changed, only the stored number data among the RT status data, the number of stored sheets data, the internal medium flag, the accessory condition device number data, and the accessory operating status flag is cleared, and the RT status data, the internal medium flag, The accessory condition device number data and the accessory operating status flag may be retained without being cleared.

Here, the "information about the advantageous section" must be cleared at the end of the advantageous section, and must be cleared even when the setting is changed.
In addition, "RT status data", "internal middle flag", "accessory condition device number data", and "accessory operation status flag" must be retained without being cleared at the end of the advantageous section, and are set. At the time of change, it may be cleared or may be retained without being cleared.

Furthermore, the "stored number data" must be retained without being cleared at the end of the advantageous section, and must be cleared when the setting is changed.
As described above, the "stored number data" is the data on the RWM 53 that is handled differently at the end of the advantageous section and at the time of setting change.

(10) In the flowchart shown in the 25th embodiment, the order of processing is not limited to the order shown in the figure, and if the order of processing can be changed, the order of processing can be changed. be.
(11) The 25th embodiment and the above-mentioned various modifications are not limited to being carried out alone, but can be carried out in combination as appropriate.

<26th Embodiment>
Next, the 26th embodiment will be described.
The 26th embodiment relates to the lighting control of the management information display LED 74 shown in FIGS. 3 and 38 in the first embodiment.
FIG. 181 is a diagram showing management information displayed by the management information display LED 74 in the 26th embodiment, and is a diagram corresponding to FIG. 38 in the first embodiment.
In the 26th embodiment, as in the first embodiment, the advantageous section ratio (in the first embodiment (FIG. 38), the “advantageous section ratio” is displayed, but in the 26th embodiment, the “advantageous section ratio” is displayed. ), Continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), bonus ratio (cumulative), displayed on the management information display LED74 (digits 6-9) in this order. do.

Further, in the 26th embodiment, unlike the first embodiment (FIG. 38), the "information type" in FIG. 38 is referred to as an "identification segment", and the "numerical value" is referred to as a "ratio segment". The identification segment corresponds to digits 6 and 7, and the "ratio segment" corresponds to digits 8 and 9.
Further, in the 26th embodiment, as described in the 20th embodiment, numbers and letters are replaced in the identification segment with respect to the first embodiment (FIG. 38). Further, when displaying the identification segment, the "dot (DP)" of the digit 7 corresponding to the lower digit is lit (the dots of the digits 6, 8 and 9 are not lit).
Further, in FIG. 181, the value of the ratio segment is the same as that in FIG. 38.

Furthermore, in the above five items, in the slot machine that does not have the function corresponding to the item, the ratio segment is lit and displayed as "---".
For example, firstly, it is called a so-called "normal type" that has an accessory (BB, RB, CB, etc.) but does not have an advantageous section (for example, no AT, etc., and only a bonus). When displaying the advantageous section ratio, the ratio segment is lit up as "---". In other words, when displaying the advantageous section ratio, "7U." Is displayed in the identification segment of the management information display LED 74, and "---" is displayed in the ratio segment.
Further, for example, secondly, when "RB (Type 1 special accessory)" is not provided, there is no continuous accessory ratio, so when the ratio display numbers "2" and "4" are displayed, the ratio is displayed. Lights and displays the segment as "---". In other words, when the continuous bonus ratio (6000 times) is displayed, "6y." Is displayed in the identification segment of the management information display LED74, and "---" is displayed in the ratio segment, and the continuous bonus ratio (cumulative) is displayed. Occasionally, "6A." Is displayed on the identification segment of the management information display LED 74, and "---" is displayed on the ratio segment.

182 and 183 are diagrams showing the storage area of the RWM 53 in the 26th embodiment. Note that FIGS. 182 and 183 show a part of the storage areas used in the description of the 26th embodiment, and do not mean that they are limited to the storage areas shown in FIGS. 182 and 183.
As shown in FIG. 124 (20th embodiment), the RWM 53 is divided into a used area and an outside used area, and the addresses "F000 (H)" to "F1FF (H)" are in the used area. Is the storage area of, and the storage area after "F200 (H)" is a storage area outside the used area. In the present embodiment, "F200 (H)" to "F20F (H)" are so-called "unused areas". This unused area is an area in which the result of the game obtained by the progress of the game is not stored, and is provided to clearly distinguish between the address in the used area and the address outside the used area. For example, it is possible to reduce the possibility of accessing an RWM address outside the used area while executing a program in the used area due to a runaway of the main program or the like.

In FIG. 182, the address “F000 (H)” is a storage area for storing the set value data, and the values “0” to “5” are stored as the data. The data "0" is the data corresponding to the set value 1, the data "1" is the data corresponding to the set value 2, ..., The data "5" is the data corresponding to the set value 6.
The address "F001 (H)" is a storage area of the interrupt counter. The value of the interrupt counter is an increment counter having a range of "0" to "65535 (D)", and the value is updated ("+1") for each interrupt (every 2.235 ms). In the 26th embodiment, since "0" to "65535 (D)" are adopted as the values of the interrupt counter, the 2-byte addresses "F001 (H)" (lower 8 bits) and "F002 (H)" are used. Although (upper 8 bits) is used, for example, when the range of "0" to "255 (D)" is adopted, it is possible to use only the 1-byte address "F001 (H)".
The address “F010 (H)” is a storage area for the operating state flag, and each accessory is assigned as shown in FIG. 182.
In this embodiment, only RB (a type in which RB continuously operates during 1BB game) is provided as an accessory, and when the D3 bit corresponding to RB is "1" (00001000 (B)), When the accessory is activated and the continuous accessory is activated, and when the D3 bit is "0" (0000000000 (B)), the accessory is not activated and the continuous accessory is not activated.
Therefore, unlike the present embodiment, if there are other accessories such as SB (when SB is provided, for example, it is assigned to the D4 bit), CB (D1 bit), etc., any of the accessories corresponding to those accessories. Whether or not the accessory is operating can be determined based on whether or not the bit is "1".

The address "F018 (H)" is a storage area of the LED display counter. It is assumed that the LED display counter of the 26th embodiment is the same as that of the 20th embodiment (FIG. 132). As described in the twentieth embodiment, the LED display counter specifies the digit to be turned on at the time of the interrupt processing.

The address "F019 (H)" is a storage area for storing the LED display request flag. The LED display request flag is also the same as that of the 20th embodiment (FIG. 132). As described in the twentieth embodiment, the LED display request flag is a flag that specifies a digit that can be turned on depending on whether the LED display request flag is normal, the setting is being changed, or the setting is being confirmed.
The address "F020 (H)" is a game section flag, and is used when determining whether it is in a normal section, an advantageous section, or a standby section.
Specifically, the D0 bit corresponds to the advantageous section flag, and the D1 bit corresponds to the standby section flag. The D2 to D7 bits are unused.
The game section flag is configured to be updated at the time of the game start set (step S2172 in FIG. 188, which will be described later).

For example, when the advantageous section is won in the "N" game, the advantageous section is set from the "N + 1" game. At this time,
"N" game: Game section flag "0000000000 (B)"
"N + 1" game: Game section flag "00000001 (B)"
Will be.
In addition, when the advantageous section is won in the "N" game, the waiting section is changed from the "N + 1" game, and the advantageous section is changed from the "N + 3" game.
"N" game: Game section flag "0000000000 (B)"
"N + 1" game: Game section flag "00000010 (B)"
"N + 2" game: Game section flag "000000010 (B)"
"N + 3" game: Game section flag "00000001 (B)"
Will be.
Furthermore, when the end condition of the advantageous section is satisfied in the "N + x" game and the transition from the "N + x + 1" game to the normal section,
"N + x" game: Game section flag "00000001 (B)"
"N + x + 1" game: Game section flag "00000000000 (B)"
Will be.

The address "F024 (H)" is a storage area of the advantageous section counter. The advantageous section counter counts the number of games played in the advantageous section. Similar to the other embodiments described above, the continuation upper limit of the advantageous section is set to the "1500" game. A 2-byte storage area is provided to count "1500" at the maximum.

In the storage area of the medal payout number data of the address "F040 (H)", the payout number is stored when the small winning combination wins in the game and the payout number is determined (step S2188 in FIG. 188 described later). It is a storage area. Then, when a small winning combination is won, the medal payout process is executed, but one medal is paid out (one is added to the number of stored medals, or one of the actual medals (from the hopper 35) is paid out). Each time, "1" is subtracted. 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 medal payout number data becomes "0".

The medal payout number buffer of the address "F041 (H)" is paid out when a small winning combination wins in the game and the payout number is determined (step S2188 in FIG. 188, which will be described later), similarly to the medal payout number data. This is a storage area in which the number of sheets is stored. Here, unlike the medal payout number buffer, the medal payout number buffer is not subtracted for each medal payout process, and the initially stored value is maintained. Then, the value is maintained until the end of the next game. For example, when a small winning combination of 8 cards is won in the game, "8 (H)" is stored in the medal payout buffer, and when the winning combination is not won in the next game, the medal payout buffer is stored. Is overwritten with "0".

The 400 game counter at the address "F210 (H)" adds the number of games played with 400 games as a delimiter. This addition is an addition that circulates from "0" to "399 (D)", and is added by "1" for each game. Further, for example, when "399 (D)" is stored, adding "1" results in "0".
Contrary to the above, "399 (D)" may be set as the initial value, and "1" may be subtracted for each game. In this case, when the value becomes "0", it is determined that 400 games have been executed. Further, when "1" is subtracted from "0", "399 (D)" is reset.

The ring buffer number of the address "F212 (H)" defines the number of ring buffers to which the data is added when medals are paid out in the game, and updates the number of medals paid out. It is for specifying the ring buffer. Specifically, any one of "0" to "14 (D)" is stored.
The addresses "F213 (H)" to "F230 (H)" are storage areas of the total payout ring buffer, and are composed of 15 addresses. Each total payout ring buffer is composed of 2 bytes. For example, the total payout ring buffer 0 is composed of the addresses “F213 (H)” and “F214 (H)”, the address “F213 (H)” is the lower digit, and the address “F214 (H)” is the upper digit. In FIGS. 182 and 183, the lowest address number is displayed for the storage area having the number of bytes of "2" or more.

The total payout ring buffers 0 to 14 correspond to the 15 ring buffers shown in FIG. 28 (first embodiment) (addresses are different from those in FIG. 28). One ring buffer stores the total number of payouts for 400 games. For example, the number of payouts from the first game to the 400th game is stored in the addresses "F213 (H)" and "F214 (H)", and the number of payouts from the next 401th game to the 800th game is the address "F213 (H)" and "F214 (H)". It is stored in "F215 (H)" and "F216 (H)".
Here, whether or not the game has reached the 400th game is determined by referring to the 400 game counter at the address "F210 (H)" described above. Further, which ring buffer value to add (update the value) to the payout number in the game is determined by referring to the ring buffer number of the address "F212 (H)".

Then, as described above, when the total number of payouts from the first game to the 400th game is stored in the total payout ring buffer 0 of the addresses "F213 (H)" and "F214 (H)", the 5601 game ~ The total number of payouts up to the 6000th game is stored in the total payout ring buffer 14 of the addresses "F22F (H)" and "F230 (H)". Next, at the end of the 6000th game, the data stored in the total payout ring buffer 0 of the addresses "F213 (H)" and "F214 (H)" is cleared, and the number of payouts for the 6001st to 6400th games is cleared. Is stored in the total payout ring buffer 0 of the addresses "F213 (H)" and "F214 (H)".
The total payout ring buffers 0 to 14 are each composed of 2 bytes. As described in the first embodiment, assuming that the maximum number of payouts in one game is "15" (in the first embodiment, it is "10" as shown in the small winning combination 39 of FIG. 11, but according to the rules. The maximum number of cards that can be paid out between 400 games is 6000, so that it can be stored with a storage capacity of 2 bytes.
This point is the same for the continuous accessory payout ring buffers 0 to 14 and the accessory payout ring buffers 0 to 14, which will be described later.

The addresses "F231 (H)" to "F24E (H)" are storage areas of the continuous accessory payout ring buffers 0 to 14. This corresponds to that shown in FIG. 29 (first embodiment) (the address is different from that in FIG. 29).
The addresses "F24F (H)" to "F26C (H)" are storage areas of the accessory payout ring buffers 0 to 14. This corresponds to that shown in FIG. 30 (first embodiment) (the address is different from that in FIG. 30).

The total number of games counters of the addresses "F26D (H)" to "F26F (H)" are counters that store the number of games (cumulative) and are composed of 3 bytes. As described in the first embodiment, since it is necessary to count "175000 (D)" games as the total number of games, it is composed of 3 bytes. The storage area of the total number of games counter corresponds to the storage areas of "F005 (H)" to "F007 (H)" shown in FIG. 27 (first embodiment).
In the 26th embodiment, the count is continued even if the number of games exceeds the “175000 (D)” game, and when the number of games reaches 3 bytes full (“FFFFFF (H)”), the count is stopped. Detailed control on this point will be described later.

The advantageous section game count counters of the addresses "F270 (H)" to "F272 (H)" count the number of games played in the advantageous section, and in FIG. 27 of the first embodiment, "F001 (H)" to "F001 (H)" to Corresponds to "F004 (H)". In the first embodiment, since the value obtained by multiplying the number of games in the advantageous section by "100 (D)" is stored, the storage area is set to 4 bytes. However, in the 26th embodiment, the same as the total number of games counter, Since "1" is added per game, it is set to 3 bytes.

The total payout (6000 times) counter of the addresses "F273 (H)" to "F275 (H)" is a counter that counts the total number of medals paid out during 6000 games. Even if 15 medals are paid out for each game in 6000 games, the total is 90,000, so it can be counted in 3 bytes (consecutive bonus payout (6000 times) counter and bonuses described later). The same applies to the payout (6000 times) counter.)
This counter corresponds to the counters of "F02F (H)" to "F031 (H)" in FIG. 28 (first embodiment).

Similarly, the continuous bonus payout (6000 times) counter of the addresses "F276 (H)" to "F278 (H)" is a counter that counts the number of payouts during continuous bonus operation between 6000 games.
This counter corresponds to the counters of "F06E (H)" to "F070 (H)" in FIG. 29 (first embodiment).
In the first embodiment, the value obtained by multiplying the number of payouts by "100 (D)" is stored, but in the 26th embodiment, the number of payouts itself is stored (added). That is, when the number of payouts is one, "1" is added.
Furthermore, similarly, the bonus payout (6000 times) counter of the addresses "F279 (H)" to "F27B (H)" is a counter that counts the number of payouts during the bonus operation between 6000 games.
This counter corresponds to the counters of "F0AE (H)" to "F0B0 (H)" in FIG. 30 (first embodiment).
Similar to the above, in the first embodiment, the value obtained by multiplying the payout number by "100 (D)" is stored, but in the 26th embodiment, the payout number itself is stored (added).

In the above total payout (6000 times) counter, continuous bonus payout (6000 times) counter, and bonus payout (6000 times) counter, when there is a payout when the continuous bonus is not working and when the bonus is not working, , Only the total payout (6000 times) counter is updated (added). In addition, when there is a payout when the continuous bonus is not operating and when the bonus is activated, the total payout (6000 times) counter and the bonus payout (6000 times) counter are updated, and the continuous bonus payout (6000 times) counter is updated. Is not updated.
Furthermore, when there is a payout during continuous bonus operation, the total payout (6000 times) counter, the bonus payout (6000 times) counter, and the continuous bonus payout (6000 times) counter are all updated.

The values of the total payout (6000 times) counter, the continuous bonus payout (6000 times) counter, and the bonus payout (6000 times) counter are updated every 400 games.
The specific control will be described with reference to the flowchart described later, but the outline of the control is as follows.
First, when medals are paid out from the first game to the 6000th game, the total payout (6000 times) is made according to the continuous accessory operation / non-operation and the accessory operation / non-operation, respectively. ) It is stored (added) in the counter, the continuous bonus payout (6000 times) counter, and the bonus payout (6000 times) counter.
At the end of the 6000th game, the continuous bonus ratio (6000 times) and the bonus ratio (6000 times), which will be described later, are calculated. After this calculation, the total payout number (6000) is the total number of payouts during the 400 games from the game before the "400 x 15-1" game (5999 games) to before the "400 x 15-400" game (5600 games). It is subtracted from each of the counter value (times), the continuous bonus payout (6000 times) counter value, and the bonus payout (6000 times) counter value.

For example, in the 6000th game, the total payout ring buffer 0 (F213 (H) to F214 (H)) value is subtracted from the total payout (6000 times) counter value. Then, the total payout ring buffer 0 (F213 (H) to F214 (H)) values are cleared. Further, the number of payouts from the 6001st game to the 6400th game is added to the total payout ring buffer 0 and the total payout (6000 times) counter.
Similarly, when the 6000th game is reached, the continuous bonus payout ring buffer 0 (F231 (H) to F232 (H)) value is subtracted from the continuous bonus payout (6000 times) counter value. Then, the value of the continuous accessory payout ring buffer 0 is cleared. Further, the number of payouts during the operation of the continuous bonuses from the 6001st game to the 6400th game is added to the continuous bonus payout ring buffer 0 and the continuous bonus payout (6000 times) counter.
Further, similarly, when the 6000th game is reached, the value of the bonus payout ring buffer 0 (F24F (H) to F250 (H)) is subtracted from the bonus payout (6000 times) counter value. Then, the value of the accessory payout ring buffer 0 is cleared. Further, the number of payouts during the operation of the bonuses from the 6001st game to the 6400th game is added to the bonus payout ring buffer 0 and the bonus payout (6000 times) counter.

More specifically, for example, the total payout ring buffer stores the number of payouts during the following number of games.
Total payout ring buffer 0: "1" game ~ "400" game Total payout ring buffer 1: "401" game ~ "800" game Total payout ring buffer 2: "801" game ~ "1200" game Total payout ring buffer 3: "1201" game ~ "1600" game Total payout ring buffer 4: "1601" game ~ "2000" game Total payout ring buffer 5: "2001" game ~ "2400" Game item Total payout ring buffer 6: "2401" Game item ~ "2800" Game item Total payout ring buffer 7: "2801" Game item ~ "3200" Game item Total payout ring buffer 8: "3201" Game item ~ "3600" Total payout ring buffer 9: "3601" Game ~ "4000" Game Total payout ring buffer 10: "4001" Game ~ "4400" Game Total payout ring buffer 11: "4401" Game ~ " 4800 "Games Total Payout Ring Buffer 12:" 4801 "Games ~" 5200 "Games Total Payout Ring Buffer 13:" 5201 "Games ~" 5600 "Games Total Payout Ring Buffer 14:" 5601 "Games ~ "6000" game total payout (6000 times) Counter: "1" game ~ "6000" game

Then, assuming that the 6000th game is completed, the total number of payout ring buffers 0 to 14 is stored in the number of payouts for each number of games.
Further, the value of the total payout (6000 times) counter and the total of the values stored in the total payout ring buffers 0 to 14 match.
Here, assuming that the value stored in the total payout (6000 times) counter at this time is Σ1 and the value stored in the total payout ring buffer 0 is Z1.
Total payout (6000 times) Counter = Σ1-Z1
Perform the operation of.
again,
Total payout ring buffer 0 = 0 (clear)
Perform the operation of.
That is, the value "Z1" of the total payout ring buffer 0 that stores the number of payouts during the 400 games from before the 5999 (400 x 15-1) game to the 5600 (400 x 15-400) game is the total payout ( 6000 times) The process of subtracting from the value "Σ1" stored in the counter is executed.
Next, a process of clearing the value "Z1" of the total payout ring buffer 0 that stores the number of payouts during the 400 games from before the 5999 (400 x 15-1) game to the 5600 (400 x 15-400) game. To execute.
After calculating in this way, the 6001st game is started. If there is a payout between the 6001st game and the 6400th game (here, it is assumed that the accessory did not operate between the 6001th game and the 6400th game), it is added to the total payout ring buffer 0, and the payout is added to the total payout ring buffer 0. Add to the total payout (6000 times) counter.

Next, assuming that the 6400th game is completed, the total payout ring buffer stores the number of payouts during the following number of games.
Total payout ring buffer 0: "6001" game ~ "6400" game Total payout ring buffer 1: "401" game ~ "800" game:
Total payout ring buffer 14: "5601" game to "6000" game Total payout (6000 times) Counter: "401" game to "6000" game, and "6001" game to "6400" game and In the same manner as above, assuming that the value stored in the total payout (6000 times) counter at this time is Σ2 and the value stored in the total payout ring buffer 1 is Z2.
Total payout (6000 times) Counter = Σ2-Z2
And.
and,
Total payout ring buffer 1 = 0
And.
After calculating in this way, the 6401th game is started. If there is a payout between the 6401th game and the 6800th game (here, it is assumed that the accessory did not operate between the 6401th game and the 6800th game), it is added to the total payout ring buffer 1 and added to the total payout ring buffer 1. Add to the total payout (6000 times) counter. The above process is repeated.

Further, although the total payout ring buffer and the total payout (6000 times) counter have been described above, the same processing as described above is performed during the operation of the accessory and the operation of the continuous accessory.
Specifically, when the accessory is activated, the total payout ring buffers 0 to 14 are replaced with the accessory payout ring buffers 0 to 14, and the total payout (6000 times) counter is replaced with the accessory payout (6000 times) counter. Execute the process. When the accessory is activated, as described above, any one of the total payout ring buffers 0 to 14 and the total payout (6000 times) counter are also updated.
Similarly, when the continuous bonus is activated, the total payout ring buffers 0 to 14 are replaced with the continuous bonus payout ring buffers 0 to 14, and the total payout (6000 times) counter is replaced with the continuous bonus payout (6000 times) counter. Execute the processing. When the continuous accessory is activated, any of the total payout ring buffers 0 to 14, the accessory payout ring buffers 0 to 14, the total payout (6000 times) counter, and the accessory payout (6000 times) counter. It will also be updated.

The total payout (cumulative) counter of the addresses "F27C (H)" to "F27E (H)" is a counter that counts the cumulative number of payouts, and counts the total number of payouts between at least "175000 (D)" games. ..
This counter corresponds to the counters of "F032 (H)" to "F034 (H)" in FIG. 28 (first embodiment).
Similarly, the continuous bonus payout (cumulative) counters of the addresses "F27F (H)" to "F281 (H)" are counters that count the cumulative number of payouts when the continuous bonus is activated. At least, the number of payouts during continuous accessory operation between "175000 (D)" games is counted.
This counter corresponds to the counters of "F071 (H)" to "F074 (H)" in FIG. 29 (first embodiment).
Furthermore, similarly, the accessory payout (cumulative) counters of the addresses "F282 (H)" to "F284 (H)" are counters that count the cumulative number of payouts when the accessory is activated, and at least as described above. The number of payouts during the operation of the accessory during the "175000 (D)" game is counted.
This counter corresponds to the counters of "F0B1 (H)" to "F0B4 (H)" in FIG. 30 (first embodiment).
The above-mentioned three types of payout (6000 times) counters subtract the number of payouts from before 5999 games to before 5600 games for every 400 games, but these three types of payout (cumulative) counters subtract the value. There is nothing to do.

In the first embodiment, since the value obtained by multiplying the number of payouts by "100 (D)" is stored, the cumulative storage capacity is composed of 4 bytes, but in the 26th embodiment, the number of payouts itself Is stored (added), so it is composed of 3 bytes.
For example, in 175,000 games, assuming that 15 cards are paid out for each game, it becomes "175000 x 15 = 2625000", which is smaller than the value that can be stored in 3 bytes. Therefore, it can be stored with a storage capacity of 3 bytes.

The advantageous section ratio data of the address “F285 (H)” is a storage area for storing the advantageous section ratio indicating the ratio of the number of games played in the advantageous section to the total number of games played.
This storage area corresponds to the storage area (advantageous section ratio) of "F008 (H)" in FIG. 27 (first embodiment).
The continuous bonus ratio (6000 times) data of the address "F286 (H)" is a storage area for storing the payout number ratio at the time of continuous bonus operation with respect to the total payout number during the 6000 games.
This storage area corresponds to the storage area of "F075 (H)" in FIG. 29 (first embodiment).
The bonus ratio (6000 times) data of the address “F287 (H)” is a storage area for storing the payout number ratio at the time of the bonus operation with respect to the total payout number during the 6000 games.
This storage area corresponds to the storage area of "F0B5 (H)" in FIG. 30 (first embodiment).

Further, the continuous bonus ratio (cumulative) data of the address "F288 (H)" is a storage area for storing the payout number ratio at the time of continuous bonus operation with respect to the total payout number in the total number of games.
This storage area corresponds to the storage area of "F076 (H)" in FIG. 29 (first embodiment).
The bonus ratio (cumulative) data of the address "F289 (H)" is a storage area for storing the payout number ratio at the time of the bonus operation with respect to the total payout number in the total number of games.
This storage area corresponds to the storage area of "F0B6 (H)" in FIG. 30 (first embodiment).

Next, the calculation method of the ratio and the outline of the correction of the ratio will be described (specific processing will be described in the flowchart described later).
In the following example, the advantageous section ratio is given and it will be described using a decimal number. The following ratio calculation method is adopted in all of the five types of ratios shown in FIG. 181.
First, it is assumed that the total number of games is "50,000" and the number of games in the advantageous section is "13000".
In this case, if division is used, the advantageous section ratio can be calculated as "13000/50000 = 0.26 (26%)". Further, in the ratio calculation of the 26th embodiment, the part after the decimal point is rounded down. Therefore, for example, even if it is "18.9%", it is set to "18%".
On the other hand, the one-chip microprocessor (FIG. 124) mounted on the present embodiment cannot directly divide a large value. Therefore, an operation is performed in which division is replaced with subtraction.

Here, let it be "Y (divisor) / X (divisor)".
(1) The number of advantageous section games, which is the division number Y, is multiplied by 10 (10 × Y). Therefore, it becomes "13000 x 10 = 130000". The process of multiplying by 10 is executed by the calculated value set (S_VALUE_SET) described later.
(2) Subtract "50,000", which is a divisor X, from "130,000".
130,000-50000 = 80,000 (first subtraction)
Here, when the calculation result is larger than the divisor X, the divisor X is subtracted from the calculation result again, and the process is repeated until the calculation result is "0" or more and less than the divisor X. Then, the number of repetitions is set to "R1".
That is,
0 ≦ (10 × YX × R1) <X
Calculate "R1" that satisfies.
In this example
130,000-50000 = 80,000 (first subtraction)
80,000-50000 = 30,000 (second subtraction)
At this point, it becomes "0" or more and less than the divisor X.
Then, the number of repetitions of the subtraction here is in the tens place of the ratio. If the tens digit of the ratio is "R1", then "R1 = 2".

(3) Next, the remainder in the subtraction of "R1" is set as "Y'". That is,
10 x Y-X x R1 = Y'
And.
Then, this remainder "Y'" is multiplied by 10 (10 x Y'). Therefore, it becomes "30000 x 10 = 300,000".
(4) Subtract "50,000", which is a divisor X, from "300,000".
300,000-50000 = 250,000 (first subtraction)
Here, similarly to the above, when the calculation result is larger than the divisor X, the divisor X is subtracted from the calculation result again, and the process is repeated until the calculation result is "0" or more and less than the divisor X. Then, the number of repetitions is set to "R2".
That is,
0 ≦ (10 × Y'−X × R2) <X
Calculate "R2" that satisfies.
In this example
300,000-50000 = 250,000 (first subtraction)
250,000-50000 = 200,000 (second subtraction)
:
50,000-50000 = 0 (6th subtraction)
At this point, it becomes "0" or more and less than the divisor X.
Then, the number of repetitions of the subtraction here is the first place of the ratio. If the first digit of the ratio is "R2", then "R2 = 6".
(5) Therefore, the ratio becomes "10 x R1 + R2" and becomes "26".

Further, when "10 x Y-X x R1 = Y'" is set as described above, it is determined whether or not "Y'= 0", and when it is determined that "Y'= 0", , It is also possible to set "0" as the ratio of the ones place and omit the calculation for the ratio of the ones place. In this case, the specific ratio is such that the tens digit is "R1" and the ones digit is "0".

Further, when there is a relationship of "Y (divided number) = X (divisor)" (for example, when the total number of games and the number of games in the advantageous section match), "R1 = 10 (D)" is calculated by the above calculation. And "R2 = 0", that is, the ratio is calculated as "100%". However, as shown in FIG. 125 (20th embodiment), since the ratio segment is composed of two digits, only two digits can be displayed as the ratio. Therefore, when the result of calculating the ratio is "100 (D)", the ratio is changed to the correction value "99" and stored. As a result, "99" is displayed in the ratio segment.
As will be described later, when the ratio is "60" or "70" or more, it is determined that the ratio is not within the range of the design value. , There is no big difference in the judgment of the design value.
If "100 (D)" is to be displayed as the ratio, overflow will occur in the third digit and the displayed content will be "00". Then, when "00" is displayed, it is not possible to determine whether the ratio is "0%" or "100%". From this viewpoint as well, when the calculated ratio is "100 (D)", it is displayed as "99" instead of "00".
However, when the ratio segment is composed of three LEDs and the result of calculating the ratio is "100 (D)", it is of course possible to display "100" on the ratio segment. ..

By calculating the tens digit and the ones digit by subtraction as described above, the maximum number of subtractions is 20.
On the other hand, as shown in the first embodiment, for example, when the number of games in the advantageous section is multiplied by "100" and the total number of games is continuously subtracted from the number of games in the advantageous section multiplied by "100", the maximum number is reached. It is necessary to perform subtraction 100 times.
Therefore, in the calculation method of the 26th embodiment, the time for calculating the ratio can be significantly shortened.

Further, the ratio is not limited to the advantageous section ratio, and the other four ratios also have a storage area of 1 byte. Here, when storing the ratio, the upper 4 bits of the 1-byte storage area are used as the storage area in the tens place of the ratio, and the lower 4 bits are used as the storage area in the 1st place of the ratio.
When the ratio is calculated as "26 (D)" as in the above example, the tens digit "2" becomes "10" in binary, and the ones digit "6" becomes "110 (B)" in binary. ) ”. Therefore, "0010/0110 (B)" is stored in the address "F285 (H)" that stores the advantageous section ratio. Note that "/" indicates the boundary between the upper 4 bits and the lower 4 bits. With this storage, the tens digit value of the ratio can be immediately obtained from the upper 4 bits, and the 1st digit value of the ratio can be immediately obtained from the lower 4 bits. Note that "26 (D)" is "00011010 (B)" in binary, but in order to obtain the tens digit of the ratio based on this value, it is necessary to perform a predetermined operation. On the other hand, if the upper 4 bits are stored as the tens digit and the lower 4 bits are stored as the 1st digit as described above, the upper 4 bits "10 (B)" are stored during the interrupt processing for displaying the ratio of the upper 4 bits. As an offset value, segment data can be obtained immediately as shown in FIG. 127.

In FIG. 183, the calculation result buffer of the address “F28A (H)” is a storage area for temporarily storing the calculation result during the ratio calculation process (S_CAL_SET) described later.
The count upper limit flag of the address "F28B (H)" is a total number of games counter (addresses "F26D (H)" to "F26F (H)") or a total payout number (cumulative) counter (address "F27C (H)" to This flag is turned on when the storage capacity of "F27E (H)") is the upper limit value (when it is 3 bytes full, that is, when it is "FFFFFF (H)"). Of the 1-byte (8-bit) data, the "D0" bit is assigned to the upper limit flag of the number of games played, and the "D1" bit is assigned to the upper limit flag of the number of payouts. The "D2" to "D7" bits are unused in the 26th embodiment. For example, when the total number of games counter has reached the count upper limit value, the value of the count upper limit flag is "00000001 (B)".

In the payout number upper limit buffer of the address "F28C (H)", when the number of payouts in the game is added to the total payout (cumulative) counter, if it exceeds 3 bytes full, the added value becomes 3 bytes full. A storage area that stores the value of.
For example, when the total payout (cumulative) counter value before payout in the game is "FFFFFE (H)" and the number of payouts in the game is "8 (H)", the counter value is "8 (H)". ) ”Will cause overflow. Therefore, the value for becoming 3 bytes full is calculated so as not to cause the total payout (cumulative) counter value to overflow, and the calculation result is stored in the payout number upper limit buffer.
In the above example, since "FFFFFE (H)" + "1 (H)" = "FFFFFF (H)", "1 (H)" is stored in the payout number upper limit buffer.

The specific method for calculating the upper limit buffer value for the number of payouts is as follows.
(1) In the above example, "8 (H)" is added to "FFFFFE (H)". As a result, overflow occurs (zero flag = "1").
(2) When an overflow occurs (when the zero flag = "1"), "2 (H)" is subtracted from the number of payouts "8 (H)" in the game to obtain "6 (H)". This value becomes the value after overflow (FFFFFE (H) + 8 (H) = 6 (H)).
(3) Add "1 (H)" to "6 (H)" to obtain "7 (H)".
(4) Subtract "7 (H)" obtained in (3) from the number of payouts "8 (H)" in the game. As a result, it becomes "1 (H)". This "1 (H)" is the upper limit buffer value for the number of payouts.
Therefore, "FFFFFE (H)" + "1 (H)" = "FFFFFF (H)"
Will be.
If the number of payouts in the game does not exceed 3 bytes full even if it is added to the total payout (cumulative) counter, the number of payouts in the game is stored in the payout number upper limit buffer. For example, in the case where the payout number does not exceed 3 bytes full, when the payout number in the game is "8 (H)", "8 (H)" is stored in the payout number upper limit buffer.

The blinking request flag of the address "F28D (H)" is a flag for identifying a target that satisfies the blinking display condition when displaying the identification segment and the ratio segment.
FIG. 184 is a diagram showing blinking display conditions of the identification segment and the ratio segment.
As shown in FIG. 184, in the identification segment, blinking is displayed depending on whether the total number of games played is less than "6000" or less than "175000". Specifically, regarding the advantageous section ratio, the continuous bonus ratio (cumulative), and the bonus ratio (cumulative), when the total number of games (value stored in the total number of games counter) is less than "175000", , Control to blink the identification segment. Regarding the continuous bonus ratio (6000 times) and the bonus ratio (6000 times), when the total number of games (value stored in the total number of games counter) is less than "6000", the identification segment is used. Control to blink.

The continuous accessory ratio (6000 times) and the identification segment of the accessory ratio (6000 times) are blinking and displayed. These ratios are originally ratios between 6000 times, but games with less than 6000 times. When the ratio is calculated by the number of times, it blinks to indicate that.
Similarly, the identification segment of the advantageous section ratio, the continuous character ratio (cumulative), and the character ratio (cumulative) is blinked, and these ratios are originally (to reduce the variation) between 175,000 games. However, when the ratio is calculated based on the number of games played in less than 175,000 games, a blinking display is displayed to indicate that.

Furthermore, the advantageous section ratio and the accessory ratio (both 6000 times and cumulative total) are blinked when the displayed value is "70" or more. Further, the continuous accessory ratio (both 6000 times and cumulative total) is blinked when the displayed value is "60" or more.
The slot machine of the present embodiment is designed so that the advantageous section ratio and the accessory ratio are less than "70"%, and the continuous accessory ratio is less than "60"%. This is to notify by a blinking display when the measured value is not within the range of the design value.

The description returns to FIG. 183. As shown in FIG. 183, in the blinking request flag, the D0 bit corresponds to the advantageous section ratio blinking flag, the D1 bit corresponds to the continuous accessory ratio (6000 times) blinking flag, ..., And the D6 bit corresponds to the 175000 times blinking flag. There is.
For example, when the calculated advantageous section ratio is “70” or more, the D0 bit of the blinking request flag becomes “1”. When the calculated continuous accessory ratio (6000 times) is "70" or more, the D1 bit of the blinking request flag becomes "1". Furthermore, when the total number of games counter value is less than "6000", the D5 bit becomes "1", and when the total number of games counter value is less than "175000", the D6 bit becomes "1".
For example, when the total number of games is less than "175000" (however, it is assumed that it is "6000" or more) and the advantageous section ratio is "70"% or more, the value of the blinking request flag is " 0010001 (B) ”, and when the display order is“ 1 ”in FIG. 181, both the identification segment and the ratio segment are blinking targets.

The ratio display number of the address “F28E (H)” is a storage area for storing the ratio number displayed in the interrupt process. Here, the "display number" indicates the display order of FIG. 181. For example, when the ratio to be displayed in the interrupt processing is an advantageous section ratio, "1 (H)" is stored in this ratio display number. Will be done.
The blinking switching flag of the address "F28F (H)" is a flag for determining whether the identification segment or the ratio segment is turned on or off when the identification segment or the ratio segment is blinking and displayed during the interrupt processing.
In the present embodiment, when the blinking display is displayed, it is set to repeat turning on and off about every 0.3 seconds. Then, the blinking switching flag is set to "0" (value indicating lighting) for about 0.3 seconds while the light is on, and the blinking switching flag is "1" (value indicating lighting) for about 0.3 seconds while the light is off. Is set to be.

The display switching time of the address "F290 (H)" is a counter that counts about 5 seconds, which is the time for displaying one ratio, and is a counter that updates "1" each time interrupt processing is performed.
In the present embodiment, the advantageous section ratio display (about 5 seconds) → the character continuous ratio (6000 times) display (about 5 seconds) → ... → the character ratio (cumulative) (about 5 seconds) → the advantageous section ratio display (Approximately 5 seconds) → ... Continues to be displayed repeatedly. Therefore, the display switching time is stored in order to determine whether or not about 5 seconds have passed, that is, whether or not the switching time of the ratio display content has been reached.
As described above, the blinking switching time of the address "F292 (H)" is a counter that counts about 0.3 seconds when the identification segment and the ratio segment are blinked and displayed, and each time interrupt processing is performed once. It is a counter that updates "1" to.

Here, the display switching time and the blinking switching time will be described.
When the display switching time is 5.0 seconds and the blinking switching time is 0.3 seconds, the blinking cycle is 0.6 seconds. However, even if "0.6" is multiplied by a natural number, it does not become "5.0". For example, suppose that the display of any ratio is started, the count for 5.0 seconds is started, and the count for 0.3 seconds is started. In this case, the elapsed time when the blinking cycle (0.6 seconds) is 8 times is 4.8 seconds. Therefore, the next time the lighting shifts, the lighting reaches 5.0 seconds after 0.2 seconds have elapsed, so that the display switching time is satisfied and the display is switched to the next ratio display. Therefore, the final lighting time is 0.2 seconds. In this way, when the display switching time is not reached when the blinking cycle is multiplied by a natural number, the display switching time may be turned on or off for a moment just before the display switching time is reached.
Therefore, in the present embodiment, the display switching time is set by multiplying the blinking cycle by a natural number.
As a precondition, it is assumed that a deviation of ± 10% or less is allowed in the display switching time of 5.0 seconds. Similarly, it is assumed that a deviation of ± 10% or less is allowed in the blinking cycle of 0.6 seconds.

Further, in the present embodiment, the display switching time and the blinking display time are counted using the number of interrupts. Further, the interrupt time is "2.235" ms as described in the first embodiment.
In the above, when the cycle of the display switching time is T, the blinking switching time is S (therefore, the blinking cycle is "2 × S"), and the natural number is "n",
T = 2 × n × S
Should hold.
At this time,
T = 2.235ms × 2144 = 4791.84ms
S = 2.235ms x 134 = 299.49ms
If so, all of them are within the range of ± 10%.
Also, 134 × 16 = 2144
And "n" satisfies that it is a natural number.

From the above, "2144" is set as the initial value for the display switching time, "1" is subtracted for each interrupt, and when it is "0", it is determined that the display switching time has been reached. When it is determined that the display switching time is "0", the initial value "2144" is set at the time of the interrupt processing. As a result, the display switching time circulates from "0" to "2144".
Similarly, for the blinking switching time, "134" is set as the initial value, "1" is subtracted for each interrupt, and when it is "0", the blinking switching time (switching from lighting to extinguishing). It is determined that the time (or the time to switch from turning off to turning on) has been reached. When it is determined that the blinking switching time is "0", the initial value "134" is set at the time of the interrupt processing. As a result, the display switching time circulates from "0" to "134".
Further, from the above, since "n = 16", the display switching time is reached when the blinking cycle becomes 8 cycles (2 × n).
Furthermore, when any of the ratio displays is started and the ratio display satisfies the blinking condition, the lighting is started.
More specifically, for example, when the display is started from the advantageous section ratio of the ratio display number "1" and at least one of the identification segment or the ratio segment of the advantageous section ratio satisfies the blinking display, the flow is as follows.

(1) The display of the advantageous section ratio is started and the lighting is started (at this point, the blinking switching flag is "0" (lighting)). Further, at the start of displaying the advantageous section ratio, the counter value of the display switching time is the initial value "2144", and the count value of the blinking switching time is the initial value "134".
(2) When it is determined that the count value of the blinking switching time is "0", the initial value "134" is set as the blinking switching time during the interrupt processing. Also, the blinking switching flag is updated from "0" (lit) to "1" (off).

(3) After that, when it is determined that the count value of the blinking switching time is "0", the initial value "134" is set as the blinking switching time at the time of the interrupt processing. In addition, the blinking switching flag is updated from "1" (lights off) to "0" (lights up).
(4) When it is determined that the count value of the display switching time is "0", the initial value "2144" is set as the display switching time at the time of the interrupt processing. Further, the initial value "134" is set in the count value of the blinking switching time, and the blinking switching flag is updated from "1" (off) to "0" (lit). Further, the ratio display number is updated from "1" to "2".
(5) In the next interrupt process, the display of the continuous accessory ratio (6000 times) of the ratio display number "2" is started. If it has an identification segment or a ratio segment that satisfies the blinking display condition, it starts from lighting.

Subsequently, the information processing by the main control board 50 (main CPU 55) in the 26th embodiment will be described based on the flowchart.
The flowchart in the 26th embodiment has the following contents.
Figure 185: Program start (M_PRG_START)
FIG. 186: Setting change process (M_RANK_SET)
Figure 187: Power recovery process (M_POWER_ON)
Figure 188: Main processing (M_MAIN)
FIG. 189: (a) update the number of payouts, (b) wait for interrupt (C_INTR_WAIT)
Figure 190: Interrupt processing (I_INTR)
Figure 191: Ratio set processing (S_RATE_SET)
Figure 192: Count upper limit check (S_LIMIT_CHK)
Figure 193: Game count (S_GAME_CNT)
Figure 194: Count up (S_CNT_UP)
Figure 195: Advantageous section game count (S_ATGAME_CNT)
Figure 196: Counting the number of payouts (S_PAYOUT_CNT)
Figure 197: Payout number set (S_PAYOUT_SET)
Figure 198: Ring buffer set (S_RINGADR_SET)
Fig. 199: Counting the number of payouts of accessories (S_BNSPAY_CNT)
Figure 200: Counting the number of continuous accessories paid out (S_RBPAY_CNT)
FIG. 202: Ratio calculation process (S_CAL_SET)
Figure 203: Calculated value set (S_VALUE_SET)
Figure 204: Ratio calculation execution (S_CAL_EXE)
Figure 205: Ring buffer number update (S_RINGNO_SET)
Figure 206: Ratio display preparation (S_DSP_READY)
FIG. 207: Blinking request flag generation (S_LED_FLASH)
Figure 209: Ratio display timer update (S_RATE_TIME)
FIG. 210: Ratio display processing (S_LED_OUT)
Further, in the following description, "data (value) stored in the register" is abbreviated as "register value".

FIG. 185 is a flowchart showing a process (M_PRG_START) when starting a program by the main control board 50.
In FIG. 185, when the program is started in step S2101, the main control board 50 initializes the registers in the next step S2102. Specific processing includes, for example, setting the communication speed of the serial communication circuit provided in the main CPU 55, setting the type of interrupt (for example, setting it as a masqueradable interrupt), and the parity bit assigned to the control command to be transmitted. (For example, setting to even parity). In other words, the initial values required for the slot machine 10 to operate normally are set in various registers.

Next, the process proceeds to step S2103, and the main control board 50 determines whether or not the power cutoff processed flag is a normal value. In the present embodiment, when the power is turned off, the power off execution processing flag is stored. This power-off execution processing flag is a flag for determining whether or not the previous power-off was normally performed when the power was turned on. Then, when it is determined that the power off execution processing flag is a normal value, the process proceeds to step S2104, and when it is determined that the power off execution processing flag is not a normal value, the process proceeds to step S2106.

In step S2104, the checksum of the RWM 53 is calculated. Specifically, the checksum is calculated in the same range as the checksum of the RWM 53 (for example, the work area used in the program, the unused area, and the stack area) that was executed when the power was cut off. Here, in step S2104, the 1-byte data stored in the RWM 53 is added.
In step S2105, it is determined whether or not the range of RWM53 for calculating the checksum is completed. Specifically, the next address is specified from the address of the RWM53 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. When it is determined that the checksum calculation has not been completed, the process returns to step S2104 to continue the process. On the other hand, when it is determined that the range of RWM53 for calculating the checksum is completed, the process proceeds to step S2106.

Further, in the subsequent processing as well, when the data stored in the plurality of ranges (addresses) of the RWM53 is initialized, the same processing is executed in the range of the designated RWM53 in the present embodiment.
When it is determined in step S2103 that the power off execution processing flag is not a normal value, an abnormal value is set as the power off / return data without executing the checksum calculation of the RWM53.

In step S2106, the main control board 50 stores the power supply cutoff / recovery data in a predetermined register (for example, the B register). Here, when it is determined that the power-off execution processing 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 execution processing flag is an abnormal value (when "No" in step S2103), or when it is determined that there is an abnormality during the checksum calculation (entire range) of RWM53 in step S2104, the power is turned off. An abnormal value is stored as return data.

In the next step S2107, the level data of a predetermined input port is stored in a predetermined register (for example, A register). Next, the process proceeds to step S2108, and it is determined whether or not the designated switch is on based on the level data of the predetermined input port. Here, the "designated switch" is, in the present embodiment, 3 of the signal of the door switch 15, the signal of the setting door switch (when the setting door switch is provided), and the signal of the setting key switch 12 among the predetermined input ports. It is one.

Then, the signal of the door switch 15 is on (the front cover (housing) is opened), the signal of the setting door switch is on (the setting door is opened), and the setting key switch 12 Allows setting changes only when the signal of is on (when the setting key is inserted). When all three designated switches are on, it is possible to shift to the setting change process of step S2112, but when at least one designated switch is not turned on, it is not permitted to shift to the setting change process of step S2112. ..
That is, even when the signal of the door switch 15 is off (the front cover is closed) or the signal of the setting door switch is off (the setting door is closed), the setting key switch 12 Since the signal cannot be turned on and there is a high possibility of fraud, the transition to the setting change process is not permitted.

Therefore, when it is determined in step S2108 that all the designated switches are on, the process proceeds to step S2109, and when it is determined that the switches are not on, the process proceeds to step S2111.
In step S2109, the main control board 50 determines whether or not the power supply cutoff / recovery data is abnormal. This power supply cutoff / recovery data is the data stored in the register in step S2106.

Then, when it is determined that the power off / returning data is abnormal, the process proceeds to the setting change process (M_RANK_SET) in step S2112, and when it is determined that the data is not abnormal, the process proceeds to step S2110. In step S2110, it is determined whether or not the setting change impossible flag is on. Here, the setting non-changeable flag is one of the data stored in the RWM 53, and is a flag that is disabled during the combination lottery process (step S2180) to the game end check process (step S2196), which will be described later. be. Then, when the setting change impossibility flag is on, the process proceeds to step S2111, and when it is not on, the process proceeds to the setting change process (M_RANK_SET) in step S2112.
In the present embodiment, the setting change impossible flag is provided, but if the setting can be changed at all times, the setting change impossible flag may not be provided. In that case, the process corresponding to step S2110 becomes unnecessary.
Further, in the 27th embodiment (2) (FIG. 216) described later, a setting change flag that is turned on when the setting can be changed is provided, but such a flag may be used.

In step S2111, the main control board 50 determines whether or not the power supply cutoff / recovery data is a normal value. This process is equivalent to step S2109. Then, when it is determined that the power supply cutoff / recovery data is a normal value, the process proceeds to step S2113 to perform the power supply recovery process (M_POWER_ON). On the other hand, when it is determined that the power off / returning data is not a normal value, an "E1" error occurs, and the process proceeds to step S2114 to perform unrecoverable error processing 1 (SS_ERROR_STOP1; FIG. 136).

FIG. 186 is a flowchart showing the setting change process (M_RANK_SET) in step S2112.
First, in step S2121, a "predetermined range" is stored in a register as an initialization range within the used area of the RWM53 ("F000 (H)" to "F1FF (H)" in FIG. 124). Here, the "predetermined range" is an initialization range when it is determined that the power off processing has been normally executed, and the set value data (address "F000 (H)"), the gaming state (for example, the RT state), and so on. The initialization range in which the flags related to the winning combination lottery (address "F010 (H)", etc.) are not initialized is defined as the "predetermined range".

Next, the process proceeds to step S2122, and the main control board 50 determines whether or not the power supply cutoff / recovery data (value stored in step S2106) is a normal value. When it is determined that the power-off / recovery data is a normal value, the process proceeds to step S2124, and the storage of the “predetermined range” in step S2121 is maintained. On the other hand, when it is determined in step S2122 that the power off / returning data is not a normal value, the process proceeds to step S2123.
In step S2123, the main control board 50 stores a “specific range” in a register as an initialization range within the used area of the RWM 53. Here, the "specific range" is an initialization range when it is determined that the power off is not normal, and the entire range in the used area including the set value data (address "F000 (H)") is set as the initialization range. Set.

Then, the process proceeds to step S2124, and initialization of the predetermined range set in step S2121 or the specific range set in step S2123 (within the used area of RWM53) is started. In the next step S2125, it is determined whether or not the initialization started in step S2124 is completed. When it is determined that the initialization is completed, the process proceeds to step S2126.

In step S2126, the AF register (A register and F register (flag register)) is saved. It should be noted that the AF register is originally saved here because the F (flag) register is to be saved, but the AF register is saved for the convenience of the instruction. Then, the process proceeds to step S2127, and a predetermined range is stored as the initialization range outside the used area of the RWM53 (after “F200 (H)” in FIG. 124). Here, the "predetermined range" is an initialization range when it is determined that the power off processing has been executed normally, for example, after the address "F28E (H)" or after "F293 (H)" (initialization). The range varies depending on the specifications, etc., and is not constant).

In the next step S2128, similarly to step S2122, it is determined whether or not the power supply cutoff / recovery data (value stored in step S2106) is a normal value. When it is determined that the power-off / recovery data is a normal value, the process proceeds to step S2130, and the storage of the “predetermined range” in step S2127 is maintained. On the other hand, when it is determined in step S2128 that the power off / returning data is not a normal value, the process proceeds to step S2129.
In step S2129, the main control board 50 stores a "specific range" in the register as an initialization range outside the used area of the RWM 53. Here, the "specific range" is an initialization range when it is determined that the power off is not normal, and the entire range outside the used area after the address "F200 (H)" is set as the initialization range. Therefore, in this case, the ring buffer and the like are also initialized.
Then, the process proceeds to step S2130, and initialization of the predetermined range set in step S2127 or the specific range set in step S2129 (outside the used area of RWM53) is started.

In the next step S2131, it is determined whether or not the initialization started in step S2130 is completed. When it is determined that the initialization is completed, the process proceeds to step S2132.
In step S2132, the AF register saved in step S2126 is restored. In the next step S2133, the start setting of interrupt processing is performed. Here, various registers corresponding to the interrupt processing specified in step S2102 are set. Since the timer interrupt process is used as the interrupt process in the present embodiment, the process of setting the timer interrupt cycle (“2.235 ms” in the present embodiment) corresponds to the process. Then, interrupt processing is executed after the processing of step S2133. In other words, it is configured so that interrupt processing is not executed before "interrupt activation".
In the next step S2134, the output request set at the start of setting change is performed. This process is a process of setting (storing) a control command to be transmitted to the sub control board 80 in a register in order to notify the sub control board 80 side that the setting change process is to be started.

The "output request set" is also executed in the process described below, and means a process of setting a control command to be transmitted to the sub-control board 80 as in step S2134. .. Further, the control command here does not mean only the command to be actually transmitted, but also means the command that is the source of the command to be actually transmitted.
Next, the process proceeds to step S2135, and 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 (RWM53).

Next, the process proceeds to step S2136, and the main control board 50 stores in a BC register (a pair register composed of a B register consisting of 8-bit 1-byte data and a C register) as a register for setting the standby time. In the present embodiment, the number of interrupts "224" (about 500 ms) is set as the waiting time at the start of setting change. Next, the process proceeds to step S2137, and the 2-byte time waiting process (wait process) for starting the setting change is executed. In the present embodiment, it 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 standby is also called delay processing or standby processing because the main processing is not advanced. During this waiting time (during 2-byte time waiting processing), the main processing is prevented from proceeding, but the interrupt processing is executed.

In this way, the 2-byte time waiting process (wait process) is executed in step S2137 because the initialization process of the RWM 53 on the main control board 50 side is completed in a relatively short time, whereas the sub control board 80 side is executed. Since it takes time to initialize the RWM83, the main control board 50 is executing the waiting process for 2 bytes. In particular, on the main control board 50 side, it is not possible to know whether or not the initialization process has been completed on the sub control board 80 side.

Therefore, when the initialization process is still in progress on the sub control board 80 side, the initialization has already been completed on the main control board 50 side, and the process is further advanced to proceed with the control process of the main control board 50 and the sub control board. It is possible to prevent the progress of the control process of 80 from becoming out of synchronization.
Further, after executing the output request set and the control command set 1 at the start of setting change, the sub-control board 80 starts the initialization of the RWM83, but a sufficient time is set as the wait time for the initialization of the RWM83 to be completed. do. As a result, after the initialization process of the RWM 83 is completed on the sub control board 80 side, the process proceeds to the process after step S2138 on the main control board 50 side.

The control command at the start of setting change set in steps S2134 and S2135 is transmitted to the sub-control board 80 even during the 2-byte time waiting process in step S2137. However, while the 2-byte time wait process is being executed in step S2137, the process does not proceed to the process after step S2138 (the main process does not proceed).

After the completion of the 2-byte time waiting process in step S2137, the process proceeds to step S2138 to control (light) the LED display during the setting change. As a result, when the interrupt process is executed after the process, the LEDs (set value display LED 73 and acquired number display LED 78) displayed during the setting change can be turned on. In the present embodiment, the current set value is displayed on the set value display LED 73 based on the set value data, and the value of the display data is updated in order to display "88" on the acquired number display LED 78 (RWM 53). (Process for storing data for displaying "88" in the acquired number data) is executed.
Since the display data to be displayed on the acquired number display LED 78 is initialized in step S2124, it is "0" before the update.

Next, the process proceeds to step S2139, and interrupt wait processing (C_INTR_WAIT) is executed. This process is a process of waiting until one interrupt time (2.235 ms) elapses. The reason for providing this process will be described later. The details of this process will be described later (FIG. 189 (b)). Then, after the lapse of one interrupt time, the process proceeds to step S2140.
In step S2140, it is determined whether or not the operation of the setting switch 13 is detected. Here, it is determined whether or not the setting key switch 13 is turned on by determining the rising data of the input port including the setting switch 13. When it is determined that the operation of the setting switch 13 has been detected, the process proceeds to step S2141, and when it is determined that the operation of the setting switch 13 has not been detected, the process proceeds to step S2142.
In step S2141, the set value data is updated. Specifically, the set value data (address "F000 (H)") of the RWM 53 is stored (updated). Further, when the interrupt process is executed after the set value data is updated, the updated value is displayed on the set value display LED 73.
The relationship between the operation of the setting switch 13 and the set value is the same as that described in the 25th embodiment.

In the next step S2142, it is determined whether or not the operation of the start switch 41 is detected. In the present 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 S2143, and when it is determined that the start switch 41 has not been operated, the process returns to step S2139.

In the above processing, step S2139 (waiting for interrupt) is provided to clear the rising data of the setting switch 13.
For example, if the process of step S2139 is not provided, if it is determined in step S2140 that the rising data of the setting switch 13 is on, the setting value data is updated in step S2141, and the start switch 41 is turned on in the next step S2142. If it is determined that this is not the case, the process proceeds to step S2140, and it is determined whether or not the rising data of the setting switch 13 is on.

If the interrupt processing is executed even once after it is determined to be ON in step S2140, the rising data of the setting switch 13 is turned off. However, until the interrupt processing is executed, it continues to be determined in step S2140 that the rising data of the setting switch 13 is on. As a result, the set value data continues to rise by "2" or more just by operating the setting switch 13 once. Therefore, in step S2139, interrupt waiting processing is executed.

In step S2143, it is determined whether or not the setting key switch 12 has been turned off. If it is determined that the setting key switch 12 has been turned off, the process proceeds to step S2144, and LED display control (turning off) is performed after the setting change is completed. Specifically, first, the set value display LED 73 is turned off. Here, the LED display request flag described in the twentieth embodiment or the like is changed to a normal value. As a result, the set value display LED 73 (digit 5) does not turn on (turns off) even if interrupt processing is subsequently executed. Secondly, the storage number display LED 76 and the acquisition number display LED 78 are normally displayed. Here, in order to display "00" on the stored number display LED 76 and the acquired number display LED 78, a process of updating the stored number data and the acquired number data values of the RWM 53 is executed.
As a result, when the interrupt process is executed after the process, "00" is displayed on the stored number display LED 76 and the acquired number display LED 78. Instead of displaying "00", the stored number display LED 76 and the acquired number display LED 78 may be controlled to be turned off.

Next, the process proceeds to step S2145, and the output request set at the end of the setting change is performed in the same manner as in step S2134. This process is a control command that terminates the setting change process and notifies the sub-control board 80 side of the determined setting value (specifically, the setting value data stored in the address "F000 (H)"). Is the process of setting. Next, the process proceeds to step S2146, and the main control board 50 executes the control command set 1 in the same manner as in step S2135. Then, the process proceeds to step S2147, and the process proceeds to the main process (M_MAIN).

FIG. 187 is a flowchart showing the power recovery process (M_POWER_ON) in step S2113 in FIG. 185.
First, in step S2151, the stack pointer (SP register) is restored. Here, the stack pointer is an area (stack area) of the RWM 53 that stores data at the time of power failure (for example, register value, instruction processing of main processing before interrupt processing, etc.) when power failure occurs. Of these, it refers to the area (address) to be stacked next.
In the next step S2152, the set value data is read, and whether the range of the set value data is within the normal range (whether it is within the range of the set value 1 to the set value 6), in other words, to "F000 (H)". It is determined whether or not the stored value is within the range of "0 (H)" to "5 (H)". If it is determined that the set value data is in the normal range, the process proceeds to step S2153. If it is determined that the set value data is not in the normal range, an "E6" error occurs, the process proceeds to step S2164, and the unrecoverable error processing 2 (SS_ERROR_STOP2) The transition to FIG. 137).

Proceeding to step S2153, the initialization range of the unused area in the used area of the RWM53 is set in the register. Then, in the next step S2154, the initialization of the RWM53 in the range set in step S2153 is executed. Here, it is conceivable that the value is stored in the RWM 53 due to noise or the like even in the unused area. If a value is stored in the unused area, it may lead to fraudulent acts, so the unused area should be initialized when the power is turned on (usually once a day). There is.
In the next step S2155, it is determined whether or not the initialization of the RWM 53 (unused area in the used area) has been completed, and if it is determined that the initialization has been completed, the process proceeds to step S2156.
In step S2156, the AF register is saved. This process is the same as the process of step S2126 described above. In the next step S2157, the initialization range of the unused area outside the used area of the RWM53 is set in the register. Then, in the next step S2158, the initialization of the RWM53 in the range set in step S2157 is executed.
In the next step S2159, it is determined whether or not the initialization of the RWM 53 (unused area outside the used area) has been completed, and if it is determined that the initialization has been completed, the process proceeds to step S2160. In step S2160, the AF register is restored. This process is the same as the process of step S2132 described above.

In the next step S2161, the predetermined input port is read. This process is a process for updating each data (level data, rising data, falling data) of the input port before the power is turned off to the latest data.
Next, the process proceeds to step S2162 to activate an interrupt. This process is, for example, a process for setting the timer interrupt cycle, and is the same as step S2133 described above.
Next, the process proceeds to step S2163, and the power off processing completed flag is cleared, that is, set to "0". Then, the process according to this flowchart is completed.

In the power recovery process described above, the interrupt process is activated (step S2162) after the input port is read (step S2161). The reason is as follows.
In the present embodiment, the setting key is inserted during the game standby so that the set value can be confirmed. Here, when the falling signal of the setting key switch 12 becomes "1", it is determined that the confirmation of the set value is completed.
However, for example, it is assumed that the power is cut off during the setting confirmation, and the setting key switch 12 is turned off (the setting key is removed) and the power is turned on during the power off.

In this case, the fall signal of the setting key switch 12 becomes "1" based on the fact that the setting key switch 12 is turned off by the interrupt processing after the power is turned off and on, so that the fall of the setting key switch is detected. NS.
As a result, the state at the time of power off and recovery and the state before the power off are different. Specifically, the fall signal of the setting key switch 12 is "0" in the state before the power is turned off, whereas the fall signal of the setting key switch 12 is "1" when the power is turned off and restored.
Therefore, in order to avoid a different state before and after the power is turned off, the value of the RWM53 of the predetermined input port is updated to the latest state when the power is turned off and restored. Therefore, after executing the predetermined input port reading process, the interrupt process is started.

In the above program start processing, setting change processing, and power recovery processing,
(1) In the program start process of FIG. 185, if it is determined as "No" in step S2103 (when the power off processing completed flag is an abnormal value), or when there is an abnormality at the checksum of step S2104, step S2106 An abnormal value is stored as recovery data after the power is turned off. In this case, since it is determined as "Yes" in step S2109, the process proceeds to the setting change process (FIG. 186) in step S2112.
Then, in the setting change process of FIG. 186, since it is determined as "No" in steps S2122 and S2128, the initialization of the entire range inside and outside the used area of the RWM53, that is, in FIGS. 182 and 183, " All data after "F000 (H)" and after "F200 (H)" are initialized.
In FIG. 183, addresses up to "F293 (H)" are displayed as addresses outside the used area of RWM53, but in reality, addresses up to "F3FF (H)" are provided (see FIG. 124), and RWM53 abnormalities and the like are provided. , When an unrecoverable error occurs, all of the addresses "F000 (H)" to "F3FF (H)" are initialized.

(2) In the program start process, when the power off processing flag is determined to be a normal value and the checksum is also performed normally, and the setting change process is performed, steps S2122 and step S2122 in FIG. 186 are performed. Since it is determined as "Yes" in S2128, the process proceeds to step S2124 and step S2130, respectively, and the designated range of RWM53 (inside the used area and outside the used area) is initialized. When the setting change mode is normally started, at least the address "F28E (H)" outside the used area is initialized. In particular, in the present embodiment, the addresses "F28A (H)" and later (including "F28A (H)") outside the used area are initialized.
Therefore, for example, if the power is turned off while the accessory ratio (6000 times) corresponding to the ratio display number "3" is displayed before the setting change, and the setting change mode is normally entered, the subsequent setting change mode is performed. In the ratio display, the advantageous section ratio (first ratio) corresponding to the ratio display number "1" is started, and the display switching time and the blinking switching time are also started from the initial values.
However, the present invention is not limited to this, and when the mode is normally shifted to the setting change mode, the ratio display number may not be RWM-initialized, and the display switching time and the blinking switching time may be RWM-initialized. Furthermore, when the setting change mode is normally entered, the RWM initialization may not be performed for any of the ratio display number, the display switching time, and the blinking switching time.
In other words, the information related to the error system and the stack pointer temporary storage buffer 2 stored in the storage area of the RWM outside the used area are initialized, but the information related to the lighting control of the management information display LED 74 is not initialized. It may have been done.

(3) In the program start process, if the power off processing flag is determined to be a normal value and the checksum is also performed normally, and the setting change process is not performed, the power return process in step S2113 ( Shift to FIG. 187). In this case, if the set value is normal in step S2152 in FIG. 187, the initialization of the RWM 53 (inside the used area and outside the used area) at the time of normal power-on is executed. As described above, this initialization is a process of initializing the unused area of the RWM53. Therefore, unlike when the setting is changed, for example, when the power is turned off when the accessory ratio (6000 times) corresponding to the ratio display number "3" is displayed and the power is turned on again, the power is turned on. In the ratio display after turning on, the accessory ratio (6000 times) corresponding to the ratio display number "3" is started, and the display switching time and the blinking switching time are also restarted from the time before the power is turned off.

Not limited to this, the RWM may be initialized including the ratio display number as in the setting change process. Alternatively, although the RWM is not initialized for the ratio display number, the RWM may be initialized for the display switching time and the blinking switching time.
Furthermore, it is also possible not to perform the process of initializing the unused area of the RWM 53 when the power is simply turned on.
As described above, when the ratio display number is initialized, the ratio display after the initialization starts from the advantageous section ratio of the ratio display number "1". Further, when the display switching time is initialized, in the ratio display after the initialization, the ratio to be displayed first is displayed for 5.0 seconds. Furthermore, when the blinking switching time is initialized, when the blinking display is performed in the ratio display after the initialization, it starts from lighting. As a result, information can be displayed on the management information display LED 74 without delay. When the blinking switching time is initialized, it can be arbitrarily set whether to start from lighting or extinguishing (in the 26th embodiment, it starts from lighting). Is set to).

FIG. 188 is a flowchart showing the main process (M_MAIN) (step S2147 in FIG. 186) in the present embodiment. Then, during this main process, interrupt processing (FIG. 190), which will be described later, is performed every 2.235 ms.
In FIG. 188, in step S2171, the stack pointer is set. As described above, the stack pointer refers to the area of the RWM 53 that stores the data at the time of the power failure (for example, the register value, the instruction processing of the main processing before the interrupt processing, etc.) when the power failure occurs. The stack pointer set is a process of setting a register value to an initial value in the area of the RWM53.

In the next step S2172, the game start set process is performed. This process is a process of generating, updating, saving, and the like of the operating state flag.
In the next step S2173, the bet medal is read. This process is a process of reading how many medals are bet at the present time.
In the next step S2174, the presence or absence of a bet medal is determined based on the number of bets read in step S2173.

If it is determined in step S2174 that there is a bet medal, the process proceeds to step S2176, and if it is determined that there is no bet medal, the process proceeds to step S2175 to perform the medal insertion waiting process, and then the process proceeds to step S2176. The medal insertion waiting process in step S2175 determines whether or not the setting key switch 12 is on, and if it is on, shifts to the setting confirmation mode and the like.
In step S2176, the inserted medals are managed. This process is a process of determining whether or not the medal has been maintained, determining whether or not the settlement switch 46 has been operated, and the like.
In the next step S2177, the soft random number is updated. This process is a process of updating (for example, adding "1" at a time) a processing random number for processing (calculation 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 (count value (variable) incremented at the time of interrupt) to the value before update may be executed.

In the next step S2178, the main control board 50 determines whether or not the start switch 41 has been operated. When it is determined that the start switch 41 has been operated, the process proceeds to step S2179, and when it is determined that the start switch 41 has not been operated, the process returns to step S2173. Even when the start switch 41 is operated, if the number of bets does not reach the specified number of the game, it is determined as "No" in step S2178.

In step S2179, the process at the time of accepting the start switch is executed. This process is a process of setting a setting non-changeable flag, setting an output request at the start of reel rotation, setting the number of outputs for outputting a medal insertion signal as an external signal to a hall computer or the like.
In step S2180, the winning combination lottery means 61 executes the winning combination lottery at the timing when the start switch 41 is operated, that is, when the operation signal of the start switch 41 is received. The random number value at the time of the winning combination lottery is acquired in step S2179. Then, in step S2180, a process of determining whether or not the acquired random number value is a random number value corresponding to any of the winning combinations is performed using the combination lottery table.

In the next step S2181, the reel rotation start preparation process is executed. This process is a process of determining whether or not the minimum game time (4.1 seconds) has elapsed.
Next, the process proceeds to step S2182, and the reel control means 65 starts the rotation of the reel 31. In the next step S2183, the 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 stop position of the reel 31 is determined based on the lottery result of the winning combination and the position of the reel 31. The reel 31 is controlled to be stopped at the determined position.

In the next step S2184, the reel control means 65 checks whether or not all the reels 31 have stopped, and proceeds to step S2185. In step S2185, 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 S2186, and if it is determined that all reels 31 have not stopped, the process returns to step S2183. ..

In step S2186, the display determination of the symbol is performed. Here, the winning determination means 66 determines whether or not the combination of symbols corresponding to the winning combination has stopped on the effective line.
In the next step S2187, it is determined whether or not a symbol display error has occurred. If it is determined that a display error has occurred, the process proceeds to step S2199, and if it is determined that no display error has occurred, step S2188 is performed. 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 defined in the stop position determination table. However, as a result of the symbol display determination, when a symbol (kicking symbol) that should not be originally displayed is displayed on the effective line, it is determined that it is abnormal (“E5” error), and the process proceeds to step S2199. Unrecoverable error processing 1 (FIG. 136) is executed.

When it is determined in step S2187 that no display error has occurred and the process proceeds to step S2188, the medal payout number update process is executed. Details of this process will be described later with reference to FIG. 189 (a).
In the next step S2189, the payout means 67 pays out medals corresponding to the winning combination. Next, the process proceeds to step S2190, and interrupt wait processing (C_INTR_WAIT) is performed. This process is the same as step S2139 of FIG. 186. Details of this process will be described later with reference to FIG. 189 (b). In the next step S2191, interrupt processing is disabled. By the processing of these steps S2190 and S2191, the interrupt is disabled immediately after the interrupt.

In the next step S2192, the AF register is saved. This process is the same as step S2156 of FIG. 187. Next, the process proceeds to step S2193, and the ratio setting process (S_RATE_SET) (FIG. 191 described later) is executed. This ratio set process is a process executed outside the used area (second program) described above.
The details of the ratio set process will be described with reference to FIG. 191. The ratio set process is a process of updating various counter values, calculating the ratio, and the like in order to display five types of ratios. Then, when the process proceeds to step S2194, the AF register saved in step S2192 is restored, and interrupt is enabled (restarted) in the next step S2195. In this way, when the ratio set processing is executed, the AF register is saved and the interrupt processing is prohibited before the execution.
Note that interrupt processing is prohibited during execution of ratio set processing because if interrupt processing is performed while a program outside the used area is being executed in the main processing, the program inside the used area and the program outside the used area are prohibited. This is because the processing becomes complicated due to the mixture of.

Next, the process proceeds to step S2196, and the game end check process is performed. In this process, the condition device (winning combination) flag is cleared. Then, the process proceeds to step S2197, and the output request set at the end of the game and the control command set 1 are performed in the next step S2198. These processes are the same as those in steps S2134 and S2135 of FIG. 186, and are processes for setting control command data for transmitting to the sub-control board 80 that one game has been completed.
Then, when the process of step S2198 is completed, the process returns to the main process (step S2147) again.

FIG. 189 (a) is a flowchart showing the medal payout number update process in step S2188 of FIG. 188.
First, in step S2211, the medal payout number data is acquired. Since the winning combination (combination of symbols) can be specified based on the display determination in step S2186 of FIG. 188, the number of medals to be paid out corresponding to the combination of symbols is read from a data table or the like.

In the next step S2212, the medal payout number data is saved. This process is a process of storing (storing) the medal payout number data acquired in step S2211 at the address “F040 (H)” (_NB_PAY_MEDAL) in the RWM53. Since the value of the medal payout number data is "0" at the time of processing in step S2211, a process of newly writing data is executed. For example, when a single winning combination is won, the data value is updated from "0" to "1". It is optional whether or not the process of step S2211 is performed when the winning combination having the medal payout is not won. For example, a method of skipping step S2211 and a method of executing the process of step S2211 and writing "0" can be mentioned.

In the next step S2213, the medal payout number data buffer is saved. This process is a process of storing (storing) the medal payout number data acquired in step S2211 at the address “F041 (H)” (_BF_PAY_MEDAL) in the RWM53. Since the value written in the previous game remains as the value of the medal payout number data buffer, the process of writing (overwriting) the medal payout number (“0” if there is no medal payout) in the game is executed. ..
Then, the process according to this flowchart is completed.

In the above-mentioned medal payout number update process of FIG. 189 (a), the value of the medal payout number data stored in step S2212 is subsequently obtained by the medal payout process of winning in step S2189 in FIG. 188 to pay out medals (one medal). Is subtracted by "1" each time one medal is added (or paid out from the hopper 35), and becomes "0" at the end of the medal payout. That is, in FIG. 188, in step S2189, when the medal payout number data is not "0", the medal payout process is continued, and when the medal payout number data becomes "0", the medal payout process is completed. to decide.
On the other hand, the value of the medal payout number data buffer stored in step S2213 is maintained (not changed) until the next game is updated, that is, until the process of step S2213 is performed in the next game.

Therefore, in FIG. 188, in the ratio setting process of step S2193, the calculation of the ratio based on the number of medals paid out in the game is executed, but after the process of step S2189, the medal payout number data is "0". , The number of medals paid out for the game cannot be read from the data on the number of medals paid out. Therefore, when only the medal payout number data is provided, it is necessary to execute the ratio setting process before the process of step S2188. On the other hand, if a medal payout number data buffer whose value is not subtracted even by medal payout is provided, the medal payout number data buffer in the game can be read even after the processing of step S2188. , The ratio setting process can be executed after the process of step S2188.

FIG. 189 (b) is a flowchart showing interrupt wait (C_INTR_WAIT) in step S2139 of FIG. 186 and step S2190 of FIG. 188.
First, in the interrupt counter value acquisition in step S2215, the interrupt counter value at the address “F001 (H)” is stored in the A register. Here, in the present embodiment, the interrupt counter value is stored as 16 bits in the two addresses "F001 (H)" and "F002 (H)", but in step S2215, the lower 8-bit address "F001 (" The value stored in "H)" is stored in the A register.

Next, the process proceeds to step S2216, and it is determined whether or not the interrupt counter value (the value of the lower 8 bits stored in the address “F001 (H)”) has changed. Specifically, the process of subtracting the "interrupt counter value stored in the address" F001 (H) "" from the "A register value" is executed, and the calculation result is "0" (zero flag = "1"). When there is, it is judged as "No". Then, when it is determined that the change has occurred, the process according to this flowchart is terminated, and when it is determined that the change has not occurred, the process of step S2216 is continued.

In the main process of FIG. 188, if the interrupt wait is executed in step S2190, the process proceeds to step S2191 after the interrupt is executed. Then, the next interrupt timing does not arrive until 2.235 ms has elapsed from that moment. Here, in the 26th embodiment, the processing time from the execution of the interrupt in step S2190 to the progress to step S2195 is set to be less than 2.235 ms. Therefore, after the interrupt is executed in step S2190, the next interrupt is executed in step S2195 or later.
With this setting, the interrupt timing after step S2195 does not change with respect to the interrupt timing up to step S2190.
On the other hand, if 2.235 ms elapses from the time when the interrupt is executed in step S2190 to before proceeding to step S2195, the interrupt timing arrives in a state where the interrupt is disabled. In this case, the interrupt is entered after the interrupt is enabled in step S2195. Therefore, the interrupt timing after step S2195 may change with respect to the interrupt timing up to step S2190.
Further, in the main process of FIG. 188, even when the process proceeds to step S2191 without executing the interrupt wait in step S2190, the interrupt timing up to now can arrive before the interrupt is enabled in step S2195. Therefore, similarly to the above, the interrupt timing after step S2195 may change with respect to the interrupt timing before step S2191.

FIG. 190 is a flowchart showing interrupt processing (I_INTR) of the 26th embodiment. FIG. 190 is a modification of FIG. 133 shown in the 20th embodiment.
In FIG. 190, the same steps as those in FIG. 133 are assigned the same step numbers, and the description thereof will be omitted. Further, different step numbers are assigned to processes different from those in FIG. 133, and different step numbers are underlined.
FIG. 190 is different from the flowchart of FIG. 133 in that the ratio display preparation (S_DSP_READY) in step S2221 is provided. Others are the same as those in the 20th embodiment.
As shown in FIG. 190, in the 26th embodiment, after the external signal is output in step S1416, the process proceeds to step S2221 to execute the ratio display preparation process. This process is the process of FIG. 206, which will be described later, and is a process of generating a blinking request flag, updating the timer related to the ratio display, outputting segment data, and the like. The ratio display preparation process is a process executed outside the used area (second program), similarly to the ratio set process described above.

FIG. 191 is a flowchart showing the ratio setting process (S_RATE_SET) in step S2193 of FIG. 188.
First, in step S2231 saving the stack pointer, the stack pointer (SP register) stored in the stack area is stored in the stack pointer temporary storage buffer 2 (address "F293 (H)").
As described above, the ratio set process is a program that is executed outside the used area. Therefore, when a program outside the used area is being executed, the stack pointer is saved and inside the used area (first program). Returns the stack pointer when returning to.

The "stack area" refers to an area of RWM53 that can save (store) various registers and the return address of the program. The stack area holds data in a last-in, first-out structure.
Further, the "stack pointer" is one of the types of registers that hold data, and is also referred to as an SP register. The stack pointer is for holding the address of the recently referenced position in the stack area. When data is stored in the stack area, the value of the stack pointer is configured to increase by the amount of the data and decrease by the amount when the data is retrieved.

For example, when the stack pointer indicates "F200 (H)", the data is saved in "F1FF (H)" in the stack area.
In particular, in the process of step S2231, after executing the ratio set process, a "return address" indicating which program should be executed is stored in the stack area, and the stack pointer is temporarily stored in the stack pointer in order to acquire the return address. This is a process of storing in the storage buffer 2.

In the next step S2232, the stack pointer (outside the used area) is set. This process is a process of storing "F400 (H)" in the stack pointer (SP register).
It is the storage area of the RWM 53 outside the used area that can update the data stored in the RWM 53 by the processing by the program outside the used area.
In other words, the address is different between the stack area in which the register and the return address are saved by the processing by the program outside the used area and the stack area in which the register and the return address are saved by the processing by the program in the used area.
In the present embodiment, the stack area in the used area is set to the addresses "F1C0 (H)" to "F1FF (H)". Further, the stack area outside the used area is set to the addresses "F3EC (H)" to "F3FF (H)".

In the next step S2233, the register is saved. This process is a process of saving various registers to the stack area (outside the used area).
Next, the process proceeds to step S2234, and the upper address of the RWM53 is set in the Q register. This process is a process of storing "F2 (H)" in the Q register.
Since all the addresses of the RWM53 used by the ratio set processing are addresses starting with "F2 (H)", this processing can be performed, so that the RWM53 address and the like can be updated and the reading processing instruction can be simplified. Because.

In the next step S2235, the counter upper limit check (S_LIMIT_CHK) is performed. This process is a process shown in FIG. 192, which will be described later, and the count values of the total number of games counter (address “F26D (H)”) and the total payout (cumulative) counter (address “F27C (H)”) reach the upper limit. It is a process to check whether or not it is done (details will be described later).
After executing this process, the address (F28B (H)) of the RWM 53 that stores the total payout (cumulative) counter value or the count upper limit flag indicating whether or not the total number of games counter value has reached the upper limit value is It is stored in the HL register.

Next, the process proceeds to step S2236, and it is determined whether or not the game count upper limit flag is on. This determination is determined as "Yes" when the D0 bit of the data (count upper limit flag) stored in the address (F28B (H)) indicated by the HL register value is "1". When it is determined that the game number upper limit flag is on, the process proceeds to step S2239, and when it is determined that the game number upper limit flag is not on, the process proceeds to step S2237. That is, when it is determined that the game count upper limit flag is on, the counting process related to the number of games in steps S2237 and S2238 is not executed.
In step S2237, the number of games counted (S_GAME_CNT) (FIG. 193) is executed. In the next step S2238, the advantageous section game count (S_ATGAME_CNT) (FIG. 195) is executed. The details of the processing of these game counts and the advantageous section game counts will be described later, but in the game counts, the process of adding each game "1" is executed. Further, in the advantageous section game count, a process of adding each game "1" during the advantageous section is executed.

In the next step S2239, the payout number count (S_PAYOUT_CNT) (FIG. 196) is executed. Further, in the next step S2240, the bonus payout number count (S_BNSPAY_CNT) (FIG. 199) is executed, and in the next step S2241, the continuous bonus payout number count (S_RBPAY_CNT) (FIG. 200) is executed. Each of these processes is a process of updating the total number of payouts, the number of payouts when the bonus is activated, and the number of continuous bonus payouts, which will be described in detail later.

Next, the process proceeds to step S2242, and the 400 game counter is updated. Here, the following processing is executed.
(1) The address (F210 (H)) of the 400 game counter is stored in the HL register. Specifically, "10 (H)" is stored in the L register, and the data (F2 (H)) set in the Q register (described above) is stored in the H register.
(2) "1" is added to the data stored in the address (F210 (H)) indicated by the HL register value.
Note that this addition is an addition that circulates from "0" to "399 (D)". For example, when "399 (D)" is stored, adding "1" results in "0". .. As described above, the 400 game counter may be subtracted.

Next, the process proceeds to step S2243, and the ratio calculation process (S_CAL_SET) (FIG. 202) is executed. This process is a process of calculating the above-mentioned five ratios and storing them at a predetermined address of the RWM53. The details of this process will be described later.
Next, the process proceeds to step S2244, and ring buffer update (S_RINGNO_SET) (FIG. 205) is executed. This process is a process of determining whether or not 400 games have passed since the previous update of the ring buffer number, and updating the ring buffer number when it is determined that 400 games have passed. The details of this process will be described later.

Next, the process proceeds to step S2245 to restore the register. This process is a process of restoring various registers saved in step S2233.
In the next step S2246, the stack pointer is returned. This process is a process of storing the stack pointer saved in step S2231, that is, the data stored in the stack pointer temporary storage buffer 2 in the stack pointer (SP register). Then, the process according to this flowchart is completed.

FIG. 192 is a flowchart showing a count upper limit check (S_LIMIT_CHK) in step S2235 of FIG. 191.
First, in step S2251, data for the number of repetitions and the count upper limit flag are set. This process is a process of storing "2 (H)" in the B register and storing "0" in the C register. "2 (H)" is stored in the B register as the number of repetitions of steps S2253 to S2257 because the count upper limit check checks the upper limits of the two counters, the total number of games and the total payout (cumulative). This is to set "2".

In step S2252, the address of the RWM53 of the total payout (cumulative) counter is set. This process is a process of storing "F27C (H)", which is the address of the total payout (cumulative) counter, in the HL register.
As described above, the total payout (cumulative) counter is composed of 3 bytes, "F27C (H)" is the lower 1 byte (1st digit), and "F27D (H)" is the lower 2 bytes. The first byte (second digit) and "F27E (H)" store the data of the upper first byte (third digit). Then, in this step S2252, the address "F27C (H)" of the lower first byte is stored in the HL register.

Next, the process proceeds to step S2253, and the lower 2 bytes of the target counter are acquired. Here, the following processing is executed.
(1) The data stored in the address indicated by the HL register value is stored in the E register.
(2) The result of adding "1" to the HL register value is taken as the HL register value.
(3) The data stored in the address indicated by the HL register value is stored in the D register.
(4) The result of adding "1" to the HL register value is taken as the HL register value.
By these processes, the lower 2 bytes of the total payout (cumulative) counter (repetition count "1" times) or the total game count counter (repetition count "2" times) are stored in the DE register.
Further, according to (4) the calculation result, the address in which the data of the upper 1st byte of the total payout (cumulative) counter or the total number of games counter is stored is stored in the HL register.

In the next step S2254, the upper 1 byte of the target counter 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 next step S2255, the upper limit value check is performed. Here, the following processing is executed.
(1) "1" is added to the DE register value, and the result of the addition is taken as the DE register value. As described above, since the lower 2 bytes of data are stored in the DE register, if an overflow occurs when "1" is added, the carry flag = "1".
(2) The result of adding the value of the carry flag to the A register value is stored in the A register. When the digit overflow of the A register occurs as a result of this calculation, the carry flag = "1". When the carry flag is "0" in the calculation result of (1), there is no change in the A register value.

In the next step S2256, the count upper limit flag data is updated. This process is a process of rotating the data stored in the carry flag (CY) and the C register to the left. Specifically, the value of the carry flag becomes the value of the D0 bit, and the values of the D0 to D6 bits up to that point become the values of the D1 to D7 bits, respectively.
An example is as follows.
Example 1)
When the carry flag = "0" and the C register = "00000000 (B)",
C register = "00000000000 (B)"
Will be.
Example 2)
When the carry flag = "0" and the C register = "00000001 (B)",
C register = "00000010 (B)"
Will be.
Example 3)
When the carry flag = "1" and the C register = "00000000000 (B)",
C register = "00000001 (B)"
Will be.
Example 4)
When the carry flag = "1" and the C register = "00000001 (B)",
C register = "00000011 (B)"
Will be.

In the next step S2257, the address of the RWM53 of the total number of games counter corresponding to the “2” number of repetitions is set. This process is a process of storing in the HL register the address "F26D (H)" in which the data of the lowest digit among the addresses of the total number of games counter is stored.
Next, the process proceeds to step S2258, and it is determined whether or not the number of repetitions has been completed. This process subtracts the B register value by "1" and determines whether or not the B register value is "0". When it is "0", it is determined that the repetition has been completed.
In the first step S2251, since "2 (H)" is set as the B register value, the first time is "No" in step S2258, and the process returns to step S2253. By this process, the upper limit of the total payout (cumulative) counter is checked at the number of repetitions "1", and the upper limit of the total number of games counter is checked at the number of repetitions "2". In addition, the address of RWM53 of the total game count counter is set by step S2257 even in the second repetition count. However, since the number of repetitions "2" is "Yes" in the judgment of step S2258, the upper limit of the total number of games counter is not checked again.

If it is determined in step S2258 that the number of repetitions has been completed, the process proceeds to step S2259. In step S2259, the count upper limit flag is saved. Here, the following processing is executed.
(1) The address (F28B (H)) of the count upper limit flag is stored in the HL register.
(2) The data stored in the C register is stored in the address indicated by the HL register value.
By this process, the data of the count upper limit flag is updated.
When the D0th bit of the count upper limit flag is "1", it indicates that the total number of games counter has reached the upper limit value.
When the D1 bit of the count upper limit flag is "1", it indicates that the total payout (cumulative) counter has reached the upper limit value.

FIG. 193 is a flowchart showing the game count (S_GAME_CNT) in step S2237 in FIG. 191.
First, in step S2271, the address of the RWM53 of the game count counter is set. This process is a process of storing the address (F26D (H)) in which the total number of games counter is stored in the DE register.
In the next step S2272, the addition value "1" is set. This process is a process of storing "1" in the A register.

Next, the process proceeds to step S2273, and count-up (S_CNT_UP) is performed. This process is not limited to the game count according to this flowchart, but other count processes described later (advantageous section game count (S_ATGAME_CNT), payout number count (S_PAYOUT_CNT), payout number set (S_PAYOUT_SET), bonus payout count ( It is also used in S_BNSPAY_CNT) and continuous bonus payout number count (S_RBPAY_CNT)).
This count-up is a process of determining whether or not the upper limit of the count has been reached, and when it is determined that the upper limit has been reached, a process of generating an upper limit buffer or the like (FIG. 194 described later). By counting up in step S2273, the total number of games counter value is added by "1". Then, the process according to this flowchart is completed.

FIG. 194 is a flowchart showing the count-up (S_CNT_UP) of step S2273 and the like in FIG. 193.
This process is executed because the address of the RWM53 to be added is stored in the DE register, and the addition value "1", the medal payout number buffer, or the payout number upper limit buffer is stored in the A register. Under the circumstances.
First, in step S2281, the lower 2 bytes are added. Here, the following processing is executed.
(1) The data of the address indicated by the DE register value is stored in the C register.
(2) The data at the address indicated by the data obtained by adding "1" to the DE register value is stored in the B register.
Even if the process of (2) is executed, the DE register value is the same as that of (1).
Further, by the processing of (1) and (2), the lower 2 bytes of data are stored in the BC register.
(3) Add the A register value to the BC register value.
Here, the A register value differs depending on which module is called. When the digits overflow due to this addition process, the carry flag = "1".
(4) The BC register value is stored in the address indicated by the DE register value.

Next, the process proceeds to step S2282, and it is determined whether or not there is a carry. In this process, when the carry flag = "1" according to the calculation result of step S2281, it is determined that there is a carry. When it is determined that there is a carry, the process proceeds to step S2283, and when it is determined that there is no carry, the process according to this flowchart ends.
In step S2283, the upper 1-byte addition process is performed. This process is a process of adding "1" to the data of the upper byte when the digits overflow in the "addition of the lower 2 bytes" in step S2281. Here, the following processing is executed.
(1) The value obtained by adding "1" to the DE register value is stored in the DE register.
(2) The value obtained by adding "1" to the DE register value is stored in the DE register.
That is, the DE register value becomes "+2" by the above processes (1) and (2).
In other words, among the data composed of 3 bytes, the data indicating the address where the data of the upper byte is stored is stored in the DE register.
(3) "1" is added to the data of the address indicated by the data stored in the address indicated by the DE register value, and the data of the address is updated.
When an overflow occurs due to this addition, the upper 1-byte value becomes "0" (FF (H) + 1 (H) = 0 (H), zero flag = "1").

In the next step S2284, it is determined whether or not the count upper limit value has been exceeded. Here, when the zero flag = "1" in step S2283 (when the digit overflows), it is determined that the count upper limit value has been exceeded. When it is determined that the count upper limit value has been exceeded, the process proceeds to step S2285, and when it is determined that the count upper limit value has not been exceeded, the process according to this flowchart ends.

In the count-up during the game count in FIG. 193, it is not determined that the count upper limit value has been exceeded in step S2284.
In the count-up of the number of games count, "1" is added for each game until the full 3 bytes are reached. Then, since it is determined as "No" in step S2284 until the full 3 bytes are reached, the processing after step S2285 is not executed.
Then, when the total number of games counter value becomes 3 bytes full in the number of games count in the game, the game number upper limit flag is saved in the count upper limit check in step S2235 in the ratio set processing of the next game (FIG. 191). NS. Then, in the next step S2236, since it is determined that the game count upper limit flag is on, steps S2237 and S2238 are not executed.

In step S2285, the upper 1 byte is subtracted. This process is a process of updating the data at the address by subtracting "1" from the data stored at the address indicated by the DE register value.
That is, it is a process of performing "0"-"1" and storing "FF (H)".
In the next step S2286, the payout number upper limit buffer is generated.
Here, the "upper limit buffer for the number of payouts" is a storage area for storing the value to be added to the total payout (cumulative).
Hereinafter, description will be given using an example.
Example 1)
When the total payout (cumulative) is "0000010 (H)" and the eight-card winning combination is won (paid out), even if "8 (H)" is added to the total payout (cumulative), "8 (H)" is added. Since it does not become "FFFFFF (H)" (3 bytes full), "8 (H)" is stored in the payout number upper limit buffer.
Example 2)
When the total payout (cumulative) is "FFFFFE (H)" and the eight-card winning combination is won (paid out), adding "8 (H)" to the total payout (cumulative) will result in "FFFFFF (cumulative)". H) ”is exceeded. Specifically, an overflow occurs, resulting in "000006 (H)".
In such a case, "1 (H)" is stored in the payout number upper limit buffer so that the value after addition becomes "FFFFFF (H)".

To generate the upper limit buffer for the number of payouts, the following processing is executed.
(1) The value obtained by subtracting "1" from the DE register value is stored in the DE register.
(2) The value obtained by subtracting "1" from the DE register value is stored in the DE register.
By the processing of (1) and (2), the address of the lowest byte of the data composed of 3 bytes is stored in the DE register.
(3) Add "1" to the C register value.
The process of step S2286 is performed when it is determined in step S2284 that the count upper limit value is exceeded, that is, when the data composed of 3 bytes exceeds "FFFFFF (H)". At this time, the value overflowing from "FF (H)" is stored in the C register by the arithmetic processing in step S2281. Specific examples are as follows.
Example 1)
When the A register value (for example, "08 (H)") is added when the C register value is "FE (H)", the C register value becomes "06 (H)". Then, since "1 (H)" is added to the C register value by the processing, the C register value becomes "07 (H)".
Example 2)
When the A register value (for example, "08 (H)") is added when the C register value is "F9 (H)", the C register value becomes "01 (H)". Then, since "1 (H)" is added to the C register value by the processing, the C register value becomes "02 (H)".

(4) The C register value is subtracted from the A register value, and the subtraction result is stored in the A register. As a result, the A register value becomes the data stored in the payout number upper limit buffer.
Specific examples are as follows.
Example 1)
When the A register value is "08 (H)" and the C register value is "07 (H)", "01 (H)" is stored in the A register.
Example 2)
When the A register value is "08 (H)" and the C register value is "02 (H)", "06 (H)" is stored in the A register.

In the next step S2287, the lower 2 byte upper limit value is saved. Here, the following processing is executed.
(1) “FFFF (H)” is stored in the BC register.
(2) The BC register value is stored in the address indicated by the DE register.
By these processes, the data of RWM53 composed of 3 bytes becomes "FFFFFF (H)".
Then, the process according to this flowchart is completed.

FIG. 195 is a flowchart showing the advantageous section game count (S_ATGAME_CNT) in step S2238 in FIG. 191.
First, in step S2291, it is determined whether or not the section is in an advantageous section. Here, when the address (F020 (H)) of the game section flag is stored in the DE register and the bit (D0) corresponding to the advantageous section is determined to be "1" among the data stored in the address. , Judge that it is in an advantageous section. When it is determined that the section is in the advantageous section, the process proceeds to step S2292, and when it is determined that the section is not in the advantageous section, the process according to this flowchart is terminated.

In addition to the above, a method using an advantageous section counter (F024 (H)) can be considered as a method for determining whether or not the section is in the advantageous section.
As described above, the advantageous section counter is composed of 2 bytes (“F024 (H)” and “F025 (H)”) and stores data of “0” to “1500 (D)”.
Here, the advantageous section counter is a counter that is updated at least after the processing of the advantageous section game count, and can be either an addition method or a subtraction method.
At this time, when the advantageous section counter is not "0", it can be determined that the advantageous section is in progress.
In the addition method, the advantageous section counter is updated from "0" to "1" before the start switch 41 is operated in the next game of the game in which the advantageous section is won or the game in which the advantageous section is won. In addition, for each game in the advantageous section, "1" is added. When the end condition of the advantageous section is satisfied, it is updated to "0" at the end of the game (initialization process).

In the subtractive method, the advantageous section counter is updated from "0" to "1500" before the start switch 41 is operated in the next game of the game in which the advantageous section is won or the game in which the advantageous section is won. Further, for the games in the advantageous section, "1" is subtracted for each game. When the end condition of the advantageous section is satisfied, it is updated to "0" at the end of the game (initialization process).
Further, as described in the first embodiment, it can be determined from the lighting state of the advantageous section display LED 77 whether or not it is in the advantageous section, so that the lighting “1” / extinguishing “0” of the advantageous section display LED 77 is indicated. It is also possible to judge from the value of the storage area for storing data.

In step S2292, the address of the RWM53 of the advantageous section game count counter is set. In this process, the address "F270" that stores the data of the lowest digit of the advantageous section game count counter (F270 (H)) is stored in the DE register.
In the next step S2293, the above-mentioned count-up (S_CNT_UP) is performed.
When the count-up is executed, the addition value "1" set by the game count (S_GAME_CNT) is stored in the A register. By counting up in step S2293, the advantageous section game count counter value is added by "1". Then, the process according to this flowchart is completed.

FIG. 196 is a flowchart showing the payout number count (S_PAYOUT_CNT) in step S2239 in FIG. 191.
At the time when this flowchart is executed, the address (F28B (H)) of the count upper limit flag is stored in the HL register.
First, in step S2301, it is determined whether or not the payout number upper limit flag is on. This process determines that the payout number upper limit flag is on when the D1 bit of the data stored in the address (F28B (H)) indicated by the HL register value is "1".
When it is determined that the payout number upper limit flag is on, the process proceeds to step S2305, and when it is determined that the payout number upper limit flag is not on, the process proceeds to step S2302.

In step S2302, the address of the RWM53 of the total payout (cumulative) counter is set. This process is a process of storing the address (F27C (H)) that stores the data of the lowest digit among the addresses of the total payout (cumulative) counter in the DE register.
In the next step S2303, the payout number set (S_PAYOUT_SET) is executed. This process is the process of FIG. 197, which will be described later, and is a process of acquiring the number of payouts in the game and adding it to the total payout (cumulative) counter. By this process, the number of payouts or the upper limit buffer value of the number of payouts is added to the total payout (cumulative) counter value.
The A register value may fluctuate due to the count-up (S_CNT_UP) in the payout number set.
In the next step S2304, the payout number upper limit buffer is set. This process is a process of storing the A register value in the payout number upper limit buffer (F28C (H)). Here, in the process of step S2303, if the number of payouts in the game does not exceed the upper limit of the total payout (3 bytes full) even if the number of payouts in the game is added to the total payout (cumulative) counter, the number of payouts in the game is paid out. It is set in the maximum number of sheets buffer. On the other hand, if the total payout (cumulative) counter is added to the total payout (cumulative) counter and the total payout limit is exceeded, the additional value for the total payout (cumulative) counter value to be 3 bytes full is added to the payout number upper limit buffer. set.

Next, the process proceeds to step S2305, and the address of the RWM53 of the total payout ring buffer is set. This process is a process of storing in the DE register the address (F213 (H)) that stores the lower digit data among the addresses of the RWM53 of the total payout ring buffer 0.
In the next step S2306, the ring buffer set (S_RINGNO_SET) is executed. This process is the process of FIG. 198, which will be described later, and is a process of acquiring the ring buffer number and the like.

Then, the process proceeds to step S2307, and the address of the RWM53 of the total payout (6000 times) counter is set. This process is a process of storing the address (F273 (H)) that stores the lower digit data among the addresses of the total payout (6000 times) counter in the DE register. Next, the process proceeds to step S2308, and the above-mentioned count-up (S_CNT_UP) is executed. By the process of step S2308, the A register value is added to the total payout (6000 times) counter value. The A register value here is the value set in the payout number set (step S2333 of FIG. 198) in the ring buffer set of step S2306 (FIG. 198 to be described later) (medal payout of the address "F041 (H)"). The number buffer value. For example, when a small winning combination is won in the game, the number of payouts corresponding to the winning of the small winning combination).
Then, the process according to this flowchart is completed.

As is clear from FIG. 196, when the upper limit flag of the number of payouts is on, the total payout (cumulative) counter is not updated, but the total payout (6000 times) counter is updated.
Similarly, in FIG. 199, which will be described later, when the upper limit flag of the number of payouts is on, the bonus payout (cumulative) counter is not updated, but the bonus payout (6000 times) counter is updated.
Similarly, in FIG. 200, which will be described later, when the upper limit flag of the number of payouts is on, the continuous bonus payout (cumulative) counter is not updated, but the continuous bonus payout (6000 times) counter is updated. ..

FIG. 197 is a flowchart showing the payout number set (S_PAYOUT_CNT) of step S2303 and the like in FIG. 196.
First, in step S2321, the value of the medal payout number buffer is acquired. This process is a process of storing the data stored in the medal payout number buffer (F041 (H)) in the A register.
Then, the process proceeds to step S2322, count-up (S_CNT_UP) is executed, and then the process according to this flowchart ends.
Therefore, during the payout number counting in FIG. 196, when the payout number set is performed in step S2303, the total payout (cumulative) counter value is updated.

FIG. 198 is a flowchart showing the ring buffer set (S_RINGNO_SET) in step S2306 and the like in FIG. 196.
At the time of executing this flowchart, the address of the total payout ring buffer 0 (F213 (H)), the address of the continuous bonus payout ring buffer 0 (F231 (H)), or the address of the bonus payout ring buffer 0 is stored in the DE register. Any of (F24F (H)) is stored.
First, in step S2331, the ring buffer number is acquired. This process is a process of acquiring data from the address (F212 (H)) in which the ring buffer number is stored and storing it in the A register.

Next, the process proceeds to step S2332, and the address of the RWM53 of the corresponding ring buffer is set. Here, the following processing is executed.
(1) The A register value and the A register value are added, and the added result is stored in the A register. That is, it is a process of doubling the ring buffer number. The reason for doubling is that each ring buffer is composed of 2 bytes.
(2) The A register value is added to the DE register value, and the added result is stored in the DE register. By this process, the address of the corresponding ring buffer is stored in the DE register.
Therefore, the address of the ring buffer 0 is set first, and the ring buffer number is used like an offset value to obtain the address of the corresponding ring buffer.

For example, when the data stored in the DE register is "F213 (H)" and the data stored in the ring buffer number is "8 (H)",
F213 (H) +8 (H) +8 (H) = F223 (H)
Then, the address (F223 (H)) of the RWM 53 corresponding to the total payout ring buffer 8 is stored in the DE register.
Next, the process proceeds to step S2333 to set the number of payouts (S_PAYOUT_SET). This process corresponds to the process of FIG. 197 described above. With this payout number set, the payout number in the game is added to the corresponding ring buffer set in step S2332. Then, the process according to this flowchart is completed.

FIG. 199 is a flowchart showing the number of additional parts paid out (S_BNSPAY_CNT) in step S2240 in FIG. 191.
The address (F28B (H)) of the count upper limit flag is stored in the HL register when this process is executed.
First, in step S2341, it is determined whether or not the accessory is in operation. Here, the following processing is executed.
(1) The data of the operating state flag (F010 (H)) is stored in the A register.
(2) The A register value and "00001000 (B)" are ANDed, and when it is "0", it is determined that the accessory is not in operation. In the present embodiment, only the RB is provided as the accessory. Therefore, when the RB is operating (D3 bit is "1"), it is determined that the accessory is operating, and otherwise, the accessory is not operating. to decide.
When it is determined in step S2341 that the accessory is operating, the process proceeds to step S2342, and when it is determined that the accessory is not operating, it is not necessary to count (update) the number of payouts when the accessory is operating. Ends the processing by.

In step S2342, it is determined whether or not the payout number upper limit flag is on. This process determines whether or not the D1 bit of the data stored in the address indicated by the HL register value (F28B (H)), that is, the address of the count upper limit flag is "0", and must be "0". When it is determined, it is determined that the payout number upper limit flag is on.
When it is determined in step S2342 that the payout number upper limit flag is on, the process proceeds to step S2346, and when it is determined that the payout number upper limit flag is not on, the process proceeds to step S2343.
As described above, when it is determined in step S2342 that the payout number upper limit flag is not turned on, the process proceeds to step S2343 and subsequent steps, the accessory payout (cumulative) counter value is updated, and step S2346 and subsequent steps described later are performed. Proceeding to the process, the corresponding accessory payout ring buffer value is updated. On the other hand, when it is determined in step S2342 that the payout number upper limit flag is on, the bonus payout (cumulative) counter value is not updated, but the process proceeds to step S2346 and subsequent steps to proceed to the corresponding bonus payout ring. The buffer value is updated.

In step S2343, the address of the RWM53 of the accessory payout (cumulative) counter is set. In this process, among the addresses of the accessory payout (cumulative) counter, the address "F282 (H)" in which the least significant digit data is stored is stored in the DE register.
In the next step S2344, the payout number upper limit buffer is set. This process is a process of storing the data stored in the payout number upper limit buffer (F28C (H)) in the A register.
Next, the process proceeds to step S2345, and count-up (S_CNT_UP) is executed. Here, the process shown in FIG. 194 is executed. By this process, the accessory payout (cumulative) counter value is updated.
In the next step S2346, the address of the RWM53 of the accessory payout ring buffer is set. This process is a process of storing the address (F24F (H)) of the accessory payout ring buffer 0 in the DE register.
Next, the process proceeds to step S2347, and the ring buffer set (S_RINGADR_SET) is performed. Here, the process shown in FIG. 198 is executed.
As a result, the value stored in the medal payout number buffer (F041 (H)) is added to the corresponding accessory payout ring buffer.

The A register value after the ring buffer set is completed is the value of the medal payout number buffer (F041 (H)).
The reason is that even if the count-up is executed, the carry is not carried out by the "lower 2 byte addition" process in step S2281 in FIG. 194.
Specifically, since the address of one RWM53 in the ring buffer can store 2 bytes (0 to 65535) of data, even if 15 cards are paid out in all 400 games, "15 x 400 = 6000". This is because it does not exceed 2 bytes.

In the next step S2348, the address of the RWM53 of the accessory payout (6000 times) counter is set. Here, the address of the lowest digit (F279 (H)) of the addresses of the accessory payout (6000 times) counter is stored in the DE register.
Then, the process proceeds to step S2349, and the count-up (S_CNT_UP) is executed. The A register value when the count-up is executed is the value of the medal payout number buffer (F041 (H)) as described in step S2347. By this count-up, the counter value for paying out the accessory (6000 times) is updated. Then, the process according to this flowchart is completed.

FIG. 200 is a flowchart showing the continuous accessory payout number count (S_RBPAY_CNT) in step S2241 in FIG. 191.
The address (F28B (H)) of the count upper limit flag is stored in the HL register when this process is executed.
The process of FIG. 199 described above is a process for the accessory, whereas the process of FIG. 200 is a process for the continuous accessory, which is similar.
First, in step S2361, it is determined whether or not the RB is in operation. Here, the following processing is executed.
(1) The data of the operating state flag (F010 (H)) is stored in the A register.
(2) The A register value and "00000100 (B)" are ANDed, and when it is "0", it is determined that the RB is not operating.

As described in step S2341 above, since the D3 bit of the operating state flag indicates the RB state, whether or not the continuous accessory is operating by determining whether or not the bit is “1”. Can be judged.
Further, the "continuous payout number" refers to the "payout number during the RB operation" in the present embodiment, and includes the RB operation during the type 1 BB game.
When it is determined that the RB is operating, the process proceeds to step S2362, and when it is determined that the RB is not operating, the process according to this flowchart ends.

In step S2362, it is determined whether or not the payout number upper limit flag is on. Here, it is determined whether or not the D1 bit of the data stored in the address indicated by the HL register value (F28B (H)), that is, the address of the count upper limit flag is "0", and it is determined that it is not "0". If so, it is determined that the payout number upper limit flag is on.
When it is determined in step S2362 that the payout number upper limit flag is on, the process proceeds to step S2366, and when it is determined that the payout number upper limit flag is not on, the process proceeds to step S2363.
As described above, when it is determined in step S2362 that the payout number upper limit flag is not turned on, the process proceeds to step S2363 and subsequent steps, the continuous bonus payout (cumulative) counter value is updated, and step S2366 and subsequent steps described later are performed. Proceeds to the process of, and the corresponding continuous accessory payout ring buffer value is updated. On the other hand, when it is determined in step S2362 that the payout number upper limit flag is on, the continuous bonus payout (cumulative) counter value is not updated, but the process proceeds to step S2366 and subsequent steps to indicate the corresponding continuous bonus. The payout ring buffer value is updated.

In step S2363, the address of the RWM53 of the continuous accessory payout (cumulative) counter is set. Here, the address "F27F (H)" that stores the lowest data among the addresses of the continuous accessory payout (cumulative) counter is stored in the DE register.
In the next step S2364, the payout number upper limit buffer is set. Here, the data stored in the payout number upper limit buffer (F28C (H)) is stored in the A register. The A register value (upper limit buffer value for the number of payouts) is the value of the number of payouts itself and the value corrected so that the total payout (cumulative) counter value does not exceed 3 bytes full as described above. Have a case.
In the next step S2365, the count-up (S_CNT_UP) (process of FIG. 194) is performed. By this process, the continuous bonus payout (cumulative) counter value is updated.
In the next step S2366, the address of the RWM53 of the continuous accessory payout ring buffer is set. Here, the address (F231 (H)) of the continuous accessory payout ring buffer 0 is stored in the DE register.

Next, the process proceeds to step S2637, and the ring buffer set (S_RINGADR_SET) is performed. As a result, the value stored in the medal payout number buffer (F041 (H)) is added to the corresponding continuous accessory payout ring buffer.
The A register value after the execution of step S2637 is a value stored in the medal payout number buffer (F041 (H)).
The reason is similar to the above description, but to explain again, even if the count-up process is executed, the carry does not occur due to the process of "lower 2 bytes addition" in step S2281 in FIG. 194. be. This is because the address of one RWM53 of the ring buffer can store 2 bytes of data, so even if 15 cards are paid out in all 400 games, it becomes "15 x 400 = 6000" and does not exceed 2 bytes. ..

In the next step S2368, the address of the RWM53 of the continuous accessory payout (6000 times) counter is set. Here, among the addresses of the continuous accessory payout (6000 times) counter, the address "F276 (H)" of the lowest digit is stored in the DE register. Then, the process proceeds to step S2369, and the count-up (S_CNT_UP) is executed. The A register value when this count-up is executed becomes the data of the medal payout number buffer (F041 (H)) as described in step S2349. By this count-up, the continuous bonus payout (6000 times) counter value is updated. Then, the process according to this flowchart is completed.

Next, in FIG. 191 the ratio calculation process (S_CAL_SET) in step S2243 will be described. This ratio calculation process is a process for calculating the five ratios (ratio that should be displayed according to the rules) shown in FIG. 181.
In this embodiment, the advantageous section ratio is calculated for each game.
Regarding other ratios, every 400 games, that is, the addition to the ring buffer (total payout ring buffer, continuous bonus payout ring buffer, and bonus payout ring buffer) is exactly the 400th game, and is added in this game. When the ring buffer number to be played is "N" and the ring buffer number to be added from the next game is "N + 1" (however, when N = 14, "N + 1" = 0), the continuous bonus ratio (6000) (Times), bonus ratio (6000 times), continuous bonus ratio (cumulative), and bonus ratio (cumulative) are calculated.

First, the address table of the RWM 53 and the storage area of the ROM 54 used in the ratio calculation process will be described.
In FIG. 201, FIG. 201A is a diagram showing a ratio calculation RWM address table (TBL_ADR_CAL) stored in the ROM 54. Further, (B) is a diagram showing a specific storage area (address and data) of the ROM 54.
As shown in FIG. 201 (A), the address table includes five tables starting with "DEFW". The five address tables are address tables for the advantageous section ratio, the continuous bonus ratio (6000 times), the bonus ratio (6000 times), the continuous bonus ratio (cumulative), and the bonus ratio (cumulative), respectively.
In addition, each address table has a first group, a second group, and a third group.
The first group is a storage area for storing divisor data, the second group is a storage area for storing divisor data, and the third group is a storage area for storing ratio data.
Here, the relationship between the divisor, the divisor, and the ratio will be described again.
The "divided number" means a number to be divided when calculating the ratio, and the "divided number" means the number to be divided when calculating the ratio. That is,
Divide / divisor = ratio.

Then, for each of the five address tables, the data of the first group to the third group are stored as shown in FIG. 201 (B).
As shown in FIG. 6B, the start address is “230B (H)”, and the addresses “230B (H)” to “2310 (H)” are storage areas for data having an advantageous section ratio. Further, the addresses "2311 (H)" to "2316 (H)" are storage areas for data having a continuous accessory ratio (6000 times), and ..., Addresses "2323 (H)" to "2328 (H)". ) ”Is a storage area for data of the accessory ratio (cumulative).
Further, in each of these five storage areas, in order from the beginning, the storage areas of the first group (division) (for example, "230B (H)" and "230C (H)" in the advantageous section ratio), the second group (division). ) Storage area (for example, "230D (H)" and "230E (H)" in the advantageous section ratio), and the storage area of the third group (ratio) (for example, "230F (H)" in the advantageous section ratio) and It is divided into "2310 (H)").

Since the address of the RWM53 is represented by 2 bytes (for example, "F270 (H)") and the address of the ROM 54 can store only 1 byte of data, the two addresses of the ROM 54 are used to use the RWM53. It remembers one address of.
For example, as for the address of the first group (division number) of the advantageous section ratio, the data (F2 (H)) stored in "230C (H)" is ranked higher, and the data (70) stored in "230B (H)" is ranked higher. It can be expressed as "F270 (H)" in which (H)) is lower.
In RWM53, the data outside the used area is an address starting with "F2 (H)". Therefore, as shown in FIG. 201 (B), all the data corresponding to the upper part of the address is "F2 (H)".

FIG. 202 is a flowchart showing the ratio calculation process (S_CAL_SET) in step S2243 of FIG. 191.
First, in step S2381, the number of calculations is set. This process is a process of storing "5" in the B register. Here, the number "5" is for executing five ratio calculation processes, and is subtracted by "1" each time the process corresponding to one ratio calculation process is completed.
Further, after step S2381, although not shown in this flowchart, the BC register value is saved in the stack area in order to protect the B register value.

In the next step S2382, the calculation number is acquired. This process is a process of storing the B register value in the A register. That is, the calculation number = the number of calculations.
Here, the relationship between the calculation number (number of calculations) and the corresponding ratio is as follows.
Calculation number "5": Character ratio (cumulative)
Calculation number "4": Continuous character ratio (cumulative)
Calculation number "3": Character ratio (6000 times)
Calculation number "2": Continuous accessory ratio (6000 times)
Calculation number "1": Advantageous section ratio

Next, the process proceeds to step S2383, and it is determined whether or not the acquired calculation number is the advantageous section ratio calculation number. In this process, "1" is subtracted from the A register value (calculation number), and when the calculation result is "0", it is determined that it is an advantageous section ratio calculation number.
If it is determined in step S2383 that the number is the advantageous section ratio calculation number, the process proceeds to step S2385, and if it is determined that the number is not the advantageous section ratio calculation number, the process proceeds to step S2384.
In step S2384, it is determined whether or not 400 games have passed. Here, the following processing is executed.
(1) The DE register stores 2 bytes of data stored in the 400 game counter (F210 (H)).
(2) When the DE register value is "0", it is determined that 400 games have passed.
In step S2384, when it is determined that 400 games have passed, the process proceeds to step S2385, and when it is determined that 400 games have not passed, the process proceeds to step S2407. That is, only when it is determined that 400 games have passed (once in 400 games), four ratios other than the advantageous section ratio are calculated.

In step S2385, the ratio calculation RWM address table is set. Here, the following processing is executed.
(1) Store the B register value in the A register.
(2) The address obtained by subtracting "6 (H)" from the start address (230B (H)) of the above-mentioned ratio calculation RWM address table (TBL_ADR_CAL) of the ROM 54 is stored in the HL register. That is, "2305 (H)" is stored in the HL register. Since this address serves as a reference address for subsequent program processing (arithmetic processing), it is also referred to as a reference address.
(3) The value obtained by multiplying the A register value by 6 is stored in the A register.
Here, any one of "5 (H)", "4 (H)", "3 (H)", "2 (H)", and "1 (H)" is stored in the A register. This operation is performed in the state. therefore,
"5 (H)" 6 times → 1E (H)
"4 (H)" 6 times → 18 (H)
"3 (H)" 6 times → 12 (H)
"2 (H)" 6 times → C (H)
"1 (H)" is multiplied by 6 → 6 (H)
Will be.

(4) The A register value is added to the HL register value, and the addition result is stored in the HL register. Here, the first HL register value is "2305 (H)". Therefore, the A register value obtained in (3) is added to "2305 (H)" and stored in the HL register. By this process, the address of the ROM 54 in which the address of the first group is stored is stored in the HL register.
In particular,
When 6 (H) is added → 230B (H)
When C (H) is added → 2311 (H)
When adding 12 (H) → 2317 (H)
When 18 (H) is added → 231D (H)
When 1E (H) is added → 2323 (H)
Will be.

Next, the process proceeds to step S2386, and the division number RWM address is set. This process is a process of storing the corresponding RWM address of the first group in the DE register from the HL register value. Further, the HL register value is updated to the address of the ROM 54 in which the address of the second group is stored after this processing.
Specifically, in step S2386, the following processing is performed.
(1) The data stored in the address indicated by the HL register value is stored in the E register.
(2) "1" is added to the HL register value, and the added result is stored in the HL register.
(3) The data (F2 (H)) stored in the address indicated by the HL register value is stored in the D register.
By this process, the following data (address) is stored in the DE register.
When "6 (H)" is added in step S2385 → F270 (H)
When "C (H)" is added in step S2385 → F276 (H)
When "12 (H)" is added in step S2385 → F27C (H)
When "18 (H)" is added in step S2385 → F282 (H)
When "1E (H)" is added in step S2385 → F288 (H)
(4) "1" is added to the HL register value, and the added result is stored in the HL register.
Here, the address of the ROM 54 in which the address of the second group is stored is stored in the HL register. For this reason,
When "230B (H)" before addition → "230D (H)" is stored in the HL register.
When "2311 (H)" before addition → "2313 (H)" is stored in the HL register.
When "2317 (H)" before addition → "2319 (H)" is stored in the HL register.
When "231D (H)" before addition → "231F (H)" is stored in the HL register.
When "2323 (H)" is before addition → "2325 (H)" is stored in the HL register.
Further, although not shown in this flowchart, a process of saving the HL register value to the stack area is executed in order to protect the HL register.

In the next step S2387, the lower 2 bytes of the division are acquired. Here, the process of storing the data stored in the address indicated by the DE register value in the C register and storing the data stored in the address obtained by adding "1" to the DE register value is executed in the B register. As a result, the lower 2 bytes of data are stored in the BC register.
In the next step S2388, the upper 1 byte of the dividend is acquired. Here, the following processing is executed.
(1) "1" is added to the DE register value, and the added result is stored in the DE register.
(2) "1" is added to the DE register value, and the added result is stored in the DE register.
That is, the process of setting the DE register value to "+2" is executed.
As a result, the DE register value becomes
F270 (H) → F272 (H)
F276 (H) → F278 (H)
F27C (H) → F27E (H)
F282 (H) → F284 (H)
F288 (H) → F28A (H)
Will be.
In other words, the address indicating the upper digit of each 3-byte data is stored.
(3) The data stored in the address indicated by the DE register value is stored in the A register.
From the above, about the division number
The first digit of 3-byte data is stored in the C register,
The second digit of the 3-byte data is stored in the B register,
The third digit of the 3-byte data is stored in the A register.

In the next step S2389, the calculated value set (S_VALUE_SET) (FIG. 203, which will be described later) is performed. In this process, in order to calculate the ratio, a process of multiplying the divisor by 10 is executed, and a process of acquiring the divisor is executed.
When calculating the ratio, when the divisor (denominator value) is "0", the divisor (denominator value) is "0" when the calculated value set is completed so that the subsequent calculation process is not executed. When "", the zero flag = "1".
In the next step S2390, it is determined whether or not the divisor is present. Here, as described above, when the zero flag = "1" in step S2389, it is determined that there is no divisor. If it is determined that there is no divisor, the process proceeds to step S2401, and if it is determined that there is a divisor, the process proceeds to step S2391.
If the process proceeds to step S2391 (ratio calculation execution) without determining whether or not the divisor is present, an infinite loop will occur.

In step S2391, the ratio calculation execution (S_CAL_EXE) (FIG. 204 described later) is executed. In this process, an operation is performed using each register set in the calculated value set in step S2389, and a value in the tens digit of the ratio is calculated based on the operation result.
Further, when it is determined from this calculation result that carry cannot be carried out (the upper two bytes of the number to be divided are "0"), the zero flag = "1".
In the next step S2392, it is determined whether or not the carry cannot be carried down, that is, whether or not the zero flag = "1" is set by the calculation in step S2391. When the zero flag = "1", it is judged that the carry cannot be carried down. Then, when it is determined that the carry-down is not possible, the process proceeds to step S2397, and when it is determined that the carry-down is not possible (zero flag ≠ “1”), the process proceeds to step Sstep S2393.

In step S2393, an operation of adding a lower divisor to a lower divisor is executed. Here, the DE register value is added to the BC register value, and the added result is stored in the BC register. When the digits overflow by this addition process, the carry flag = "1".
This process is a process (also referred to as a correction process) for restoring the amount that has been excessively subtracted in the lower digit calculation by executing the ratio calculation. For example, in the process of subtracting the DE register value from the BC register value by executing the ratio calculation.
BC register value: 10 (H)
DE register value: 20 (H)
When, the BC register value becomes "F0 (H)" by the processing.
When the ratio calculation process is completed in this state,
BC register value (F0 (H)) + DE register value (20 (H)) = BC register value (10 (H))
By doing so, the BC register value can be restored.

In the next step S2394, it is determined whether or not there is a carry in the calculation of step S2393. In this process, when the carry flag = "1" as a result of adding the DE register value to the BC register value, it is determined that there is a carry. When it is determined that there is a carry, the process proceeds to step S2395, and when it is determined that there is no carry, the process proceeds to step S2396.
In step S2395, "1" is added to the upper 2 bytes of the dividend. This process is a process of adding "1" to the HL register value.

Next, the process proceeds to step S2396, and the upper divisor is added to the upper divisor. This process is a process of adding the A register value to the HL register value and storing the added result in the HL register. This process is a process (also referred to as a correction process) for restoring the amount excessively subtracted in the upper digit operation by executing the ratio calculation (C_CAL_EXE). Then, the process proceeds to step S2398.
On the other hand, when it is determined in step S2392 that the carry cannot be carried down and the process proceeds to step S2397, the lower divisor is added to the lower divisor. This process is a process of adding the DE register value to the BC register value and storing the added result in the BC register. This process is a process (also referred to as a correction process) for restoring the amount excessively subtracted in the lower digit operation by executing the ratio calculation (C_CAL_EXE). Then, the process proceeds to step S2398.

In step S2398, the calculation result buffer is converted into a high-order digit. Here, the following processing is executed.
(1) The L register value is stored in the A register.
(2) The address (F28A (H)) of the calculation result buffer is stored in the HL register.
(3) The upper 4 bits and the lower 4 bits of the data stored in the address indicated by the HL register value are exchanged. By this process, the value executed in the ratio calculation process is stored in the upper 4 bits. That is, the D0 bit and the D4 bit, the D1 bit and the D5 bit, the D2 bit and the D6 bit, and the D3 bit and the D7 bit are exchanged in the calculation result buffer.
Specifically, when the data stored in the address (F28A (H)) indicated by the HL register value before the calculation in (3) is "000000101 (B)", the upper 4 bits and the lower 4 bits are set. When replaced, the HL register value becomes "01010000 (B)".

This process is a process of storing the value stored in the calculation result buffer (so-called tens digit value of the ratio) in the upper 4 bits (D4 to D7 bits) in step S2391 of the ratio calculation process. The tens digit value is in the range of "00000000000 (B)" to "0000001010 (B)" when expressed in binary (the same applies to the ones digit value). Therefore, the value is within the range of 4 bits. Then, step S2400 (calculation of the ratio of the ones digit) is executed while the value of the tens digit of the ratio obtained by the process of step S2391 is not cleared and is stored in the calculation result buffer. Then, in step S2400, the value of the tens digit of the calculated ratio is added to the value stored in the calculation result buffer (the value of the tens digit of the ratio). As a result, the calculation result buffer value has a value in which the upper 4 bits indicate the ratio of the tens digit and the lower 4 bits indicate the ratio of the 1s digit. Further, by adopting the above method, the same processing can be performed in the tens digit ratio calculation (step S2391) and the ones digit ratio calculation (step S2400).

Further, here, although not shown in the flowchart, the following processing is executed.
(1) The process for restoring the HL register value stored in the stack area is executed.
(2) Further, in order to protect the HL register value again, a process of saving the HL register value in the stack area is executed.

Next, the process proceeds to step S2399, the calculated value set (S_VALUE_SET) is executed in the same manner as in step S2389, and in the next step S2400, the ratio calculation execution (S_CAL_EXE) is executed in the same manner as in step S2391. By the processing of these steps S2399 and S2400, the first digit of the ratio is calculated. The first digit of the ratio is stored in the lower 4 bits of the address (F28A (H)) of the calculation result buffer.
In the next step S2401, the calculation result buffer is acquired. Here, the following processing is executed.
(1) The address (F28A (H)) of the calculation result buffer is stored in the HL register.
(2) The data stored in the address (F28A (H)) indicated by the HL register value is stored in the A register.
In the next step S2402, the calculation result buffer is initialized. This process stores "0" at the address (F28A (H)) indicated by the HL register value.
Further, here, although not shown in the flowchart, a process for restoring the HL register value stored in the stack area is executed.

In the next step S2403, the ratio data RWM address is set. Here, the following processing is executed.
(1) Add "1" to the HL register value.
(2) Add "1" to the HL register value.
(3) The data of the address indicated by the HL register value is stored in the HL register.
By this process, the address of the ROM 54 in which the address of the third group is stored is stored in the HL register.
Next, the process proceeds to step S2404, and it is determined whether or not the calculated ratio is "100%". In this process, "A0 (H)" is subtracted from the A register value, and when there is a carry flag (carry flag = "1"), it is determined that the ratio is not "100%". When it is determined that the ratio is "100%", the process proceeds to step S2405, and when it is determined that the ratio is not "100%", the process proceeds to step S2406. In other words, when the value of the A register is "A0 (H)", it indicates that the calculation result (ratio) is 100%.

In step S2405, "99%" is set as the ratio. This process is a process of updating (storing) the value of the A register from "A0 (H)" to "99 (H)".
When the advantageous section is won, the advantageous section will start from the next game, so the advantageous section ratio will not actually reach 100%. On the other hand, the other four ratios may be 100%. However, if the (same) program of FIG. 202 is used, including the calculation of the advantageous interval ratio, the ratio set processing program can be unified.
Next, the process proceeds to step S2406, and the ratio data is saved. This process is a process of storing the A register value at the address indicated by the HL register value. As described above, one of the addresses of the third group is stored in the HL register value at this time. Specifically, when calculating the advantageous section ratio, the HL register is "F285 (H)", and when calculating the continuous accessory ratio (6000 times), the HL register is "F286 (H)". When calculating the bonus ratio (6000 times), the HL register is "F287 (H)", and when calculating the continuous bonus ratio (cumulative), the HL register is "F288 (H)". When calculating the ratio (cumulative), "F289 (H)" is stored in the HL register. In other words, the ratio data is stored in the target RWM address by the processing.
Further, here, although not shown in the flowchart, a process for restoring the BC register value stored in the stack area is executed.

In the next step S2407, it is determined whether or not the number of calculations has been completed. Here, the following processing is executed.
When the BC register value stored in the stack area is restored, the BC register value becomes the value saved after step S2381.
(1) Subtract the B register value by "1".
(2) When it is determined that the B register value is not "0", it is determined that the number of calculations has not been completed.
When it is determined that the number of calculations has been completed, the process according to this flowchart is terminated, and when it is determined that the number of calculations has not been completed, the process returns to step S2382.
By the above processing, the advantageous section ratio is calculated when the advantageous section is in progress. In addition, although it is not in the advantageous section, when 400 games have passed, four ratios of continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), and bonus ratio (cumulative) are calculated. (Steps S2382 to S2407 are repeated four times).

FIG. 203 is a flowchart showing a calculated value set (S_VALUE_SET) executed in step S2389 and step S2399 in FIG. 202.
In this calculated value set, although not shown in this flowchart, first, in order to protect the data (ratio calculation RWM address table) stored in the current HL register, the data is saved in the stack area.
In addition, although the following explanation overlaps with the above explanation, it will be explained again.
Divided number: Number divided in division (so-called numerator value)
Divine: Number to divide in division (so-called denominator value)
Division 1 byte: 1st digit (lowest digit) (C register)
Division 2nd byte: 2nd digit (B register)
Division 3 bytes: 3rd digit (most significant digit) (A register)
Point to.
Further, in this calculated value set, a process of multiplying the divisor to be calculated by 10 and a process of setting the divisor are performed.
Here, as a specific example, it will be described below assuming that "FE (H)" is stored in the C register, "40 (H)" is stored in the B register, and "01 (H)" is stored in the A register. In addition, this numerical value is expressed in decimal notation,
254 (D) +16384 (D) +65536 (D) = 82174 (D)
Corresponds to.

In step S2411, a process of multiplying the third byte of the division by 10 is performed. Here, the data of the third byte of the division is stored in the A register before the main processing. Therefore, the following processing is executed.
(1) The A register value is multiplied by 10 and the result of multiplying by 10 is stored in the HL register.
(2) The HL register value and the DE register value are exchanged.
As a result, the data obtained by multiplying the data of the third byte of the division by 10 is stored in the DE register.
In the above example, "000A (H)", which is 10 times "01 (H)", is stored in the DE register.
More specifically, "00 (H)" is stored in the D register and "0A (H)" is stored in the E register.
In the next step S2412, a process of multiplying the second byte of the dividend by 10 is performed. Here, the data of the second byte of the division is stored in the B register before the main processing. Therefore, the following processing is executed.
(1) Store the B register value in the A register.
(2) The A register value is multiplied by 10 and the result of multiplying by 10 is stored in the HL register.
In the above example, "0280 (H)" which is 10 times "40 (H)" is stored in the HL register.
More specifically, "02 (H)" is stored in the H register and "80 (H)" is stored in the L register.

In the next step S2413, a process of multiplying the first byte of the division by 10 is performed. Here, the data of the first byte of the division is stored in the C register before the main processing. Therefore, the following processing is executed.
(1) The C register value is stored in the A register.
(2) The HL register value and the BC register value are exchanged.
Here, by the process of step S2412, the data obtained by multiplying the data of the second byte of the division by 10 is stored in the HL register. As a result, the data obtained by multiplying the data of the second byte of the division by 10 is stored in the BC register.
In the above example, "0280 (H)" is stored in the BC register.
More specifically, "02 (H)" is stored in the B register and "80 (H)" is stored in the C register.
(3) The A register value is multiplied by 10 and the result of multiplying by 10 is stored in the HL register.
Here, the A register value before this processing is the data of the first byte of the division number. Therefore, by this processing, the data obtained by multiplying the data of the first byte of the division by 10 is stored in the HL register.
In the above example, "09EC (H)" obtained by multiplying "FE (H)" by 10 is stored in the HL register.
More specifically, "09 (H)" is stored in the H register and "EC (H)" is stored in the L register.

The process proceeds to the next step S2414, and the carry value of the first byte is added. Here, the following processing is executed.
(1) The H register value is stored in the A register.
(2) An operation of adding the BC register value and the A register value is performed, and the operation result is stored in the BC register.
In the above example, the operation of adding "0280 (H)" and "09 (H)" is performed. Therefore, "0289 (H)" is stored in the BC register.
More specifically, "02 (H)" is stored in the B register and "89 (H)" is stored in the C register.
In the next step S2415, the carry value of the second byte is added. Here, the following processing is executed.
(1) Store the B register value in the A register.
(2) An operation of adding the DE register value and the A register value is performed, and the operation result is stored in the DE register.
In the above example, the operation of adding "000A (H)" and "02 (H)" is performed. Therefore, "000C (H)" is stored in the DE register.
More specifically, "00 (H)" is stored in the D register and "0C (H)" is stored in the E register.

Next, the process proceeds to step S2416, and the lower digit adjustment is performed. Here, the following processing is executed.
(1) Store the C register value in the B register.
(2) Store the L register value in the C register.
In the above example, "89 (H)" is stored in the B register and "EC (H)" is stored in the C register.
By these processes, the data after multiplying the dividend by 10 becomes a maximum of 4 bytes of data. Then, the data of the lower 2 bytes multiplied by 10 is stored in the BC register, and the data of the upper 2 bytes multiplied by 10 is stored in the DE register.
In the above example, "89EC (H)" is stored in the BC register and "000C (H)" is stored in the DE register.
When this value is expressed in decimal,
35308 (D) +786432 (D) = 821740 (D)
Will be.
Therefore, the number of "82174 (D)" illustrated first is 10 times.
Further, although not shown in the flowchart, the HL register stored in the stack area is restored here.

Next, the process proceeds to step S2417, and the divisor RWM address is set. This process stores the data stored in the address indicated by the data stored in the address indicated by the HL register value in the HL register.
Here, the address of the ROM 54 in which the address of the second group is stored is stored in the HL register. By this processing, the start address of the RWM address of the second group is stored in the HL register.
Next, the process proceeds to step S2418 to acquire the upper 1 byte of the divisor. This process is a process of storing the data stored in the address indicated by the data obtained by adding "2" to the data stored in the address indicated by the HL register value in the A register.

In the next step S2419, the lower 2 bytes of the divisor are acquired. Here, the following processing is executed.
(1) The data stored in the address indicated by the HL register value is stored in the L register.
(2) The data stored in the address indicated by the data obtained by adding "1" to the HL register value is stored in the H register.
(3) The HL register value and the DE register value are exchanged.
As a result, the upper 1 byte of the divisor is stored in the A register, and the lower 2 bytes of the divisor are stored in the DE register.
Further, the value originally stored in the DE register (the upper 2 bytes after multiplying the division by 10) is stored in the HL register.

In the next step S2420, it is determined whether or not the lower two bytes of the divisor are "0". Here, it is determined whether or not the DE register value is "0", and when the DE register value is "0", it is determined that the lower two bytes of the divisor are "0". When it is determined that the lower 2 bytes of the divisor are not "0", this flowchart ends. On the other hand, when it is determined that the lower two bytes of the divisor are "0", the process proceeds to step S2421.
In step S2421, the upper 1 byte of the divisor is checked. In this process, the A register value and the A register value are OR-operated, and when the operation result is "0", the zero flag = "1" is set.
With the above calculated value set (S_VALUE_SET)
The lower 2 bytes of the value obtained by multiplying the division number by 10 are stored in the BC register.
The upper 2 bytes of the value obtained by multiplying the division number by 10 are stored in the HL register.
The upper 1 byte of the divisor is stored in the A register.
The lower 2 bytes of the divisor will be stored in the DE register.
When it is determined that the divisor is "0", the zero flag = "1".

FIG. 204 is a flowchart showing the ratio calculation execution (S_CAL_EXE) executed in step S2391 and step S2400 in FIG. 202. When this ratio calculation is executed, the calculated value set (S_VALUE_SET) described above is performed before that, and as described above,
BC register: Lower 2 bytes of the value obtained by multiplying the division by 10 HL register: Upper 2 bytes of the value obtained by multiplying the division by 10 A register: Upper 1 byte of the divisor DE register: Executed with the lower 2 bytes of the divisor stored NS.
Further, in this ratio calculation execution, as described above, the divisor (X) is subtracted from the divisor (10 × Y) multiplied by 10, and when the divisor can be subtracted from the calculation result, the divisor is subtracted again. By repeating that
0 ≦ (10 × YX × R) <X
Calculate "R" that satisfies.
Then, "R (number of repetitions of subtraction (ratio in the digit))" is stored in the calculation result buffer.

First, in step S2431, the lower divisor is subtracted from the lower divisor. This process is a process of subtracting the DE register value from the BC register value and storing the subtraction result in the BC register. When a carry occurs due to the subtraction result, the carry flag = "1".
In the next step S2432, it is determined whether or not there is a carry by the subtraction in step S2431. When the carry flag = "1", it is judged that there is a carry flag. If it is determined that there is a carry, the process proceeds to step S2433, and if it is determined that there is no carry, the process proceeds to step S2435.

In step S2433, it is determined whether or not the upper two bytes of the dividend are "0". Here, by determining whether or not the HL register value is "0", it is determined whether or not the upper two bytes of the division number are "0". When it is determined that the upper 2 bytes of the division number are "0", the process according to this flowchart is terminated. At this time, after storing the zero flag = "1", the process ends. On the other hand, when it is determined that the upper two bytes of the dividend are not "0", the process proceeds to step S2434.
In step S2434, "1" is subtracted from the upper 2 bytes of the dividend. This process is a process of subtracting "1" from the HL register value.
Next, the process proceeds to step S2435, and the upper divisor is subtracted from the upper divisor. This process is a process of subtracting the A register value from the HL register value and storing the subtracted result in the HL register. When there is a carry flag due to this subtraction result, the carry flag = "1".

Then, the process proceeds to step S2436, and it is determined whether or not the calculation is completed. When the carry flag = "1" in step S2435, it is determined that the calculation is finished, and the process according to this flowchart is finished. On the other hand, when it is determined that the calculation is not completed (when the carry flag ≠ "1"), the process proceeds to step S2437.
In step S2437, "1" is added to the calculation result buffer. This process is a process of adding "1" to the calculation result buffer (address "F28A (H)"). Then, the process returns to step S2431.

FIG. 205 is a flowchart showing the ring buffer update (S_RINGNO_SET) in step S2244 of FIG. 191.
First, in step S2441, it is determined whether or not 400 games have passed since the last 400 games have passed. Here, the following processing is executed.
(1) The data stored in the 400 game counter (address "F210 (H)") is stored in the HL register.
(2) When the HL register value is "0" (when the second zero flag = "1"), it is determined that 400 games have passed.
When it is determined that 400 games have passed, the process proceeds to step S2442, and when it is determined that 400 games have not passed, the process according to this flowchart ends. Therefore, the ring buffer update process is executed once every 400 games.

In step S2442, the number of ring buffers is set. This process is a process of storing "3" in the B register. This "3" indicates that the number of ring buffers to be updated is three (total payout ring buffer, continuous bonus payout ring buffer, bonus payout ring buffer).
In the next step S2443, the ring buffer number is updated. Here, the following processing is executed.
(1) The address in which the ring buffer number is stored, that is, "F212 (H)" is stored in the HL register.
(2) Add "1" to the data stored in the address indicated by the HL register value.
This addition is an addition (ICPLD) that circulates from "0" to "14 (D)". For example, when "14 (D)" is stored, adding "1" gives "0". ".

Further, after the processing, although not shown in this flowchart, the following stack area is saved.
(1) In order to protect the current B register value (number of ring buffers), the BC register value is saved in the stack area.
(2) In order to protect the current HL register value (ring buffer number), the HL register value is saved in the stack area.

In the next step S2444, the number of ring buffers is set. This process is a process of storing the B register value in the A register.
Next, the process proceeds to step S2445 to generate an offset of the corresponding ring buffer. Here, the following processing is executed.
(1) The A register value is multiplied by "30 (D)", and the result of the multiplication is stored in the A register.
(2) The A register value and the data stored in the address indicated by the HL register value are added, and the added result is stored in the A register.
(3) The A register value and the data stored in the address indicated by the HL register value are added, and the added result is stored in the A register.
By these operations, an offset value for calculating the RWM address of the ring buffer can be obtained.
The multiplication number "30" in (1) above indicates "the number of ring buffers (15) x the number of bytes per ring buffer (2)". Further, as shown in FIGS. 182 and 183, the addresses of the total payout ring buffers 0 to 14, the continuous accessory payout ring buffers 0 to 14, and the bonus payout ring buffers 0 to 14 are continuously provided. ..
As a result, the offset values corresponding to the total payout ring buffer, the continuous bonus payout ring buffer, and the bonus payout ring buffer can be obtained by the same processing by the above operations (1) to (3).

Specific examples are as follows.
Example 1) When the ring buffer number is "0" and the number of ring buffers is "3", if it is expressed in decimal,
Processing of (1): 3 × 30 = 90 (A register)
Processing of (2): 0 (ring buffer number) + 90 (A register) = 90 (A register)
Processing of (3): 0 (ring buffer number) + 90 (A register) = 90 (A register)
Example 2) When the ring buffer number is "1" and the number of ring buffers is "2", if it is expressed in decimal,
Processing of (1): 2 × 30 = 60 (A register)
Process (2): 1 (ring buffer number) + 60 (A register) = 61 (A register)
Process (3): 1 (ring buffer number) + 61 (A register) = 62 (A register)
Example 3) When the ring buffer number is "10" and the number of ring buffers is "1", if it is expressed in decimal,
Processing of (1): 1 × 30 = 30 (A register)
Processing of (2): 10 (ring buffer number) + 30 (A register) = 40 (A register)
Processing of (3): 10 (ring buffer number) + 40 (A register) = 50 (A register)
Will be.

Next, the process proceeds to step S2446, and the RWM address of the corresponding ring buffer is set. Here, the following processing is executed.
(1) “F1F5 (H)” is stored in the DE register.
(2) The A register value is added to the DE register value, and the added result is stored in the DE register.
Specific examples of the above processing are as follows.
Example 1) When "90 (D) (5A (H))" is stored in the A register F1F5 (H) + 5A (H) = F24F (H)
As a result, the start address of the accessory payout ring buffer 0 can be obtained.
Example 2) When "62 (D) (3E (H))" is stored in the A register F1F5 (H) + 3E (H) = F233 (H)
As a result, the start address of the continuous accessory payout ring buffer 1 can be obtained.
Example 3) When "50 (D) (32 (H))" is stored in the A register F1F5 (H) +32 (H) = F227 (H)
As a result, the start address of the total payout ring buffer 10 is obtained.
That is, the address "F1F5 (H)" becomes the reference address, and the value obtained in step S2445 becomes the offset value.

In the next step S2447, the RWM address of the payout (6000 times) counter is set. This process is performed by the total payout (6000 times) counter (F273 (H)), the continuous bonus payout (6000 times) counter (F276 (H)), or the bonus payout (6000 times) counter (F279 (H)). This is a process for calculating one of the addresses. Here, the following processing is executed.
(1) “F270 (H)” is stored in the HL register.
(2) Store the B register in the A register.
Here, the number of ring buffers (any of "1" to "3") is stored in the B register.
(3) The data obtained by multiplying the A register value by 3 is stored in the A register.
(4) The A register value is added to the HL register value, and the added result is stored in the HL register.

In the next step S2448, the lower 2 bytes of the payout counter are acquired. Here, the following processing is executed.
(1) The data stored in the address indicated by the HL register value is stored in the C register.
(2) The data stored in the address indicated by the data obtained by adding "1" to the HL register value is stored in the B register.
In the next step S2449, the upper 1 byte of the payout counter is acquired. This process is a process of storing the data stored in the address indicated by the data obtained by adding "2" to the HL register value in the A register.
By the above processes (1) and (2), the lower 2 bytes of data are stored in the BC register and the upper 1 byte of data is stored in the A register.

Next, the process proceeds to step S2450, and the corresponding ring buffer is subtracted from the lower 2 bytes of the payout counter. Here, the following processing is executed.
(1) The DE register value and the HL register value are exchanged. By this process
DE register: Corresponding payout (6000 times) Counter RWM address start address HL register: Corresponding ring buffer start address is stored.
(2) From the BC register value (lower 2-byte data of the payout (6000 times) counter), the data stored in the address indicated by the HL register value and the address obtained by adding "1" to the HL register value is subtracted. When a carry occurs as a result of subtraction, the carry flag = "1".

Next, the process proceeds to step S2451 to determine whether or not there is a carry. When the carry flag = "1" in the process of step S2450, it is determined that there is a carry flag.
When it is determined that there is a carry, the process proceeds to step S2452, and when it is determined that there is no carry, the process proceeds to step S2453.
In step S2452, "1" is subtracted from the high-order byte of the payout counter. This process is a process of subtracting the A register value by "1".

In the next step S2453, the corresponding ring buffer is cleared. This process clears the data stored in the address indicated by the HL register value and the data stored in the address obtained by adding "1" to the HL register value.
That is, in step S2453, the information stored in the address indicated by the DE register value and the next address is cleared, and the information related to the next game and thereafter is set to be memorable. Further, before clearing these information, the total payout (6000 times) counter (F273 (H)) and the continuous accessory payout (6000 times) counter are performed according to steps S2448 to S2452 based on the information before clearing. (F276 (H)) or the information of the accessory payout (6000 times) counter (F279 (H)) is updated.
In this way, when calculating the total payout (6000 times) counter value, the continuous bonus payout (6000 times) counter value, and the bonus payout (6000 times) counter value, all 15 ring buffer values are added. It is only necessary to subtract the corresponding ring buffer value from the counter value 6000 times so far, instead of performing the calculation. Therefore, the processing time for calculating the counter value 6000 times can be shortened, and the program can be simplified.
Then, the process proceeds to step S2454, and the payout (6000 times) counter is saved. Here, the following processing is executed.
(1) The DE register value and the HL register value are exchanged. By this process, the start address of the corresponding ring buffer is stored in the DE register, and the start address of the RWM address of the corresponding payout (6000 times) counter is stored in the HL register.
(2) The C register value is stored in the address indicated by the HL register value.
(3) The B register value is stored in the address indicated by the value obtained by adding "1" to the HL register value.
(4) The A register value is stored in the address indicated by the value obtained by adding "2" to the HL register value.
Then, after this process, although not shown in this flowchart, the following process is executed in order to restore the value saved in the stack area.
(1) Perform processing for restoring the HL register value stored in the stack area.
(2) Performs a process for restoring the BC register value stored in the stack area.

Next, the process proceeds to step S2455, and it is determined whether or not the number of ring buffers has been completed. Here, the following processing is executed.
(1) Subtract the B register value by "1".
(2) When the B register value is "0", it is determined that the number of ring buffers has been completed.
When it is determined that the ring buffer numbers corresponding to the number of ring buffers have been updated, the processing according to this flowchart is terminated. On the other hand, when it is determined that the number of ring buffers has not been completed, the process returns to step S2444.
The above explanation is the processing during the main processing (M_MAIN).

FIG. 206 is a flowchart showing the ratio display preparation (S_DSP_READY) in step S2221 of FIG. 190 (interrupt processing).
First, in step S2461 to save the stack pointer, the stack pointer (SP register) stored in the stack area is stored in the stack pointer temporary storage buffer 2 (address "F293 (H)").
As described above, the ratio display preparation is a program to be executed outside the used area. Therefore, when the program outside the used area is being executed, the stack pointer used in the first program is saved. The stack pointer is returned when it returns to the used area (first program).

In the next step S2462, the stack pointer (outside the used area) is set. This process is a process of storing "F400 (H)" in the stack pointer (SP register).
In the next step S2463, the register is saved. This process is a process of saving various registers to the stack area (outside the used area).
Next, the process proceeds to step S2464, and the blinking request flag generation (S_LED_FLASH) is executed. This process is a process shown in FIG. 207, which will be described later, and is a process for updating the blinking request flag (address “F28D (H)”).

In the next step S2465, the ratio display timer is updated (S_RATE_TIME). This process is the process shown in FIG. 209, which will be described later, and is a blinking switching flag (address "F28F (H)"), a display switching time (address "F290"), and a blinking switching time (address "F292 (H)"). Is the process of updating.
In the next step S2466, the ratio display process (S_LED_OUT) is performed. This process is the process shown in FIG. 210, which will be described later, and is a process for actually displaying (turning on or off) the ratio in the interrupt process. In the 20th embodiment and the like, the ratio display process when blinking is not considered has already been described (FIG. 135, etc.).

Next, the process proceeds to step S2467 to restore the register. This process is a process of restoring various registers saved in step S2463.
In the next step S2468, the stack pointer is returned. This process is a process of storing the stack pointer saved in step S2461, that is, the data stored in the stack pointer temporary storage buffer 2 in the stack pointer (SP register). In other words, the process causes the stap pointer to indicate an address in the used area. Then, the process according to this flowchart is completed.

FIG. 207 is a flowchart showing blinking request flag generation (S_LED_FLASH) in step S2464 of FIG. 206.
First, in step S2481, the number of repetitions and the initial value are set. This process is a process of storing "5 (H)" in the B register and "0" in the C register.
Here, the number of repetitions "5" is a value for determining whether or not the ratio segment of 5 items blinks (see FIG. 184).
In the next step S2482, the address of the blinking / non-applicable item determination value table is set. This process is a process of storing the start address of the blinking / non-applicable item determination value table (TBL_SEG_FLASH) in the DE register.
FIG. 208 is a diagram showing a blinking / non-applicable item determination value table (TBL_SEG_FLASH). In this table, predetermined values are set for each of the five item ratios. For example, when the advantageous section ratio is "70", it means that the display is blinked when the advantageous section ratio is "70" or more (see FIG. 184).
Further, as shown in FIG. 208, the start address of this table is "2500 (H)". Therefore, "2500 (H)" is stored in the DE register.

In addition, "non-applicable item" means that it does not have the ability to display the corresponding ratio. For example, when the gaming machine is not equipped with an advantageous section, the advantageous section ratio is not displayed. In this way, when there is a non-applicable item, "---" is displayed in the ratio segment of the advantageous section ratio.
In this embodiment, since the advantageous section and the continuous accessory are provided, the ratio of all five items is displayed, but when there is a non-applicable item, the address of the ROM 54 corresponding to the non-applicable item in this table is displayed. Memorizes "DE (H)".
For example, when the gaming machine does not have an advantageous section, "DE (H)" is stored in the address "2504 (H)" instead of "70 (H)" in FIG. 208.
In this way, regardless of the gaming machine that does not have an advantageous section (for example, so-called A type or so-called A + ART), lighting control of management information is performed by simply modifying a part of the data in this table. The control process that enables this is built in. Therefore, it is easy to divert the control program to other products.
As will be described later, the value corresponding to the non-applicable item is not limited to "DE (H)".

In the next step S2483, the RWM address of the ratio data is set. This process is a process of storing the address (F289 (H)) in which the accessory ratio (cumulative) data is stored in the HL register.
Next, the process proceeds to step S2484, and the blinking or non-applicable item determination value is acquired. Here, the following processing is executed.
(1) The data of the address indicated by the DE register value is stored in the A register.
(2) The A register value is subtracted by "1".
In the next step S2485, it is determined whether or not the item value is not applicable. In this process, "DD (H)" is subtracted from the A register value, and when the calculation result is "0" (zero flag = "1"), it is determined that the item value is not applicable.
That is, when it is a non-applicable item, as described above, since "DE (H)" is stored in the blinking / non-applicable item determination value table, "1" is subtracted from "DE (H)". After that, when "DD (H)" is further subtracted, it becomes "0", and the zero flag = "1".
When a predetermined value other than "DE (H)" is stored as a value corresponding to the non-applicable item, for example, "predetermined value -1- (predetermined value -1)" is calculated, and the calculation result is "0". When (zero flag = "1"), it is judged that the item value is not applicable.
Further, the "predetermined value" may be a value exceeding "70 (H)" in the case of the advantageous section, the bonus ratio (cumulative), and the bonus ratio (6000 times), and the continuous bonus ratio (cumulative), In the case of the continuous accessory ratio (6000 times), the value may exceed "60 (H)".
If it is determined that the value is not a non-applicable item, the process proceeds to step S2487, and if it is determined that the value is not a non-applicable item value, the process proceeds to step S2486.

In step S2486, the ratio 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 next step S2487, the ratio data or the non-applicable item value is saved. This process is a process of storing the A register value at the address indicated by the HL register value. Note that this process has the following meanings.
When there is a non-applicable item, the RWM in which the ratio data is stored does not store the data before the storage process. For example, when the advantageous section is not provided, "00 (H)" is stored in the advantageous section ratio data (address "F285 (H)"). Although the details will be described later, when the ratio is displayed on the management information display LED 74, the ratio is displayed based on the information stored in the address. At that time, if "00 (H)" is stored in the advantageous section ratio data, "00" is displayed in the ratio segment of the management information display LED 74 when displaying the advantageous section ratio. In order to prevent this, the value of the A register acquired in step S2485 (“DD (H)” in this embodiment) is stored as the ratio data, so that “−−” is displayed. Specifically, when the offset value is "D (H)", the display data is "-" as shown in FIG. 127.
It should be noted that the program processing is set so that the gaming machine having the non-applicable item and the gaming machine not having the non-applicable item can be used in common.
In the next step S2488, the blinking determination is performed. This process is a process of subtracting the data of the address indicated by the DE register value from the A register value. If there is a carry flag as a result of the calculation, the carry flag = "1".
Although the details will be described later, when the carry flag = "1", it means that the light does not blink when the item is displayed, and when the carry flag = "0", it means that the light is turned on. It means that the light is turned on in a blinking manner when the item is displayed.
Next, the process proceeds to step S2489 to generate a blinking request flag. This process performs arithmetic processing for rotating the carry flag and the C register value to the left.
Specifically, assuming that the carry flag value is "CY" and the C register value is "D7, D6, D5, D4, D3, D2, D1, D0".
"CY", C register value "D7, D6, D5, D4, D3, D2, D1, D0"
of,
"D7", C register value "D6, D5, D4, D3, D2, D1, D0, CY"
Perform the operation.
For example, when the C register value is the initial value "00000000000 (B)" as shown in step S2481 and the carry flag = "1" in step S2488,
"1", C register value "00000000000 (B)"
of,
"0", C register value "00000001 (B)"
Perform the operation. Therefore, the C register value is "00000001 (B)". This C register value finally becomes the blinking request flag.
In other words, the process of step S2488 registers information for determining whether or not to blink the ratio segment of the item by the calculation based on the ratio data and the specific value stored in the blinking / non-applicable item determination value table. It is a process of storing in (storage area).

In the next step S2490, the RWM address of the next ratio data is set. This process is a process of subtracting "1" from the HL register value. For example, the HL register value in the first blinking determination is "F289 (H)" (role ratio (cumulative) data) as described above. Here, when "1" is subtracted, the HL register value becomes "F288 (H)" (continuous accessory ratio (cumulative) data), which is the target of the second blinking determination.
In the next step S2491, the address of the next blinking / non-applicable item determination value table is set. This process is a process of adding "1" to the DE register value. For example, when "2500 (H)" is first stored as the DE register value, it becomes "2501 (H)" by this processing.
Here, as shown in FIG. 208, the addresses are in the order of the bonus ratio (cumulative), the continuous bonus ratio (cumulative), the bonus ratio (6000 times), the continuous bonus ratio (6000 times), and the advantageous section ratio. Blinking / non-corresponding item determination values are stored in "2500 (H)" to "2504 (H)".
As a result, the initial value of the address (DE register value) of the blinking / non-applicable item judgment value table is set to "2500 (H)", and "1" is added at the time of the next blinking / non-applicable item determination (step). Since the target address can be specified by S2484 to S2492), the process can be simplified.

Next, the process proceeds to step S2492, and it is determined whether or not the repetition is completed. Here, the following processing is executed.
(1) Subtract the B register value by "1".
(2) When the B register value is not "0", it is determined that the repetition has not been completed.
Here, since the B register value is set to "5" in the first step S2481, the number of repetitions is "5". When it is determined that the repetition is completed, the process proceeds to step S2493, and when it is determined that the repetition is not completed, the process returns to step S2484.
As described above, the blinking determination of 5 items is performed.

When the blinking determination of the five items is completed and the process proceeds to step S2493, the total number of games counter value is acquired. Here, the following processing is executed.
(1) The value of the lower two bytes of the total number of games counter (address "F26D (H)") is stored in the HL register.
(2) The value of the upper 1 byte of the total number of games counter (address "F26D (H)") is stored in the A register.
As described above, the total number of games counter is composed of 3 bytes, and "F26D (H)" is a storage area for storing the first digit, and the value is stored in the L register.
Further, "F26E (H)" is a storage area for storing the second digit, and the value thereof is stored in the H register.
Furthermore, "F26F (H)" is a storage area for storing the third digit, and the value is stored in the A register.

In the next step S2494, it is determined whether or not the upper 1 byte of the total number of games counter is "0". This process determines whether or not the A register value stored in step S2493 is "0". If it is determined to be "0", the process proceeds to step S2495, and if it is determined that the value is not "0", the process proceeds to step S2494.
In step S2495, it is determined whether or not 6000 games have passed. This process subtracts "6000 (D)" from the HL register value (data of the lower 2 bytes of the total number of games counter). When there is a carry flag as a result of the calculation, the carry flag = "1". Then, when the carry flag = "1", it is determined that 6000 games have not passed, and the process proceeds to step S2497.
On the other hand, when it is determined that 6000 games have passed, the process proceeds to step S2494.

In step S2494, the blinking request flag data is updated. This process is a process of setting the D5 bit of the C register to "1". Here, the C register value is set to a value corresponding to the blinking request flag of the address "F28D (H)" (however, at this point, the bits are in an inverted state). Therefore, when 6000 games have passed, the process of setting the D5 bit to "1" is executed.
In the next step S2497, it is determined whether or not the upper 1 byte of the total number of games counter is "2" or more. Here, the process of subtracting "3" from the A register value is performed. If there is no carry flag in this subtraction, the carry flag ≠ "1". Then, when the carry flag ≠ "1", it is determined that the upper 1 byte of the total number of games counter is "2" or more.

In this way, in order to determine whether or not the game has reached 175,000 games, first, the upper 1 byte and "3" are compared. Here, since "175000 (D)" is "2AB98 (H)" in hexadecimal, it is inevitable that the A register value exceeds "2" (A register value is "3" or more). Therefore, it can be seen that the value of the total number of games counter exceeds "175000 (D)".
In step S2497, when the carry flag ≠ "1", it is determined that the upper 1 byte of the total number of games counter exceeds "2", and the process proceeds to step S2500. When the carry flag = "1", the total It is determined that the upper 1 byte of the game count counter does not exceed "2", and the process proceeds to step S2498.

In step S2498, it is determined whether or not the value of the total number of games counter is "2". This process subtracts "2" from the A register value, and when it is determined that it is not "0", it is determined that the value of the total number of games counter is not "2". When it is determined that the total number of games counter value is not "2", the process proceeds to step S2501, and when it is determined that the total number of games counter value is "2", the process proceeds to step S2499.
In step S2499, it is determined whether or not 175,000 games have passed. In this process, "AB98 (H)" is subtracted from the HL register value, and as a result of the calculation, when there is a carry flag, the carry flag = "1". Then, when the carry flag = "1", it is determined that 175,000 games have not passed.
When it is determined in step S2499 that 175,000 games have passed, the process proceeds to step S2500, and when it is determined that 175,000 games have not passed, the process proceeds to step S2501.

In step S2500, the blinking request flag data is updated. This process sets the D6 bit of the C register to "1". The D6 bit of the C register corresponds to the D6 bit (175000 game blinking flag) of the blinking request flag of the address "F28D (H)". Then, the process proceeds to step S2501.
In step S2501, a blinking request flag is generated. Here, the following processing is executed.
(1) “01111111 (B)” is stored in the A register.
(2) An exclusive OR operation (XOR) is performed between the A register value and the C register value, and the operation result is stored in the A register.

Before the execution of the process of step S2501, as described above, "0" is stored in the blinking item (bit) among the data stored in the C register. For example, when 175,000 games have passed, the D6 bit is "1" as described above. In other words, when 175,000 games have not passed, it is "0".
Therefore, by inverting the bit of the C register value, a blinking request flag is generated so that the blinking item (bit) becomes "1".
In the next step S2502, the blinking request flag generated in step S2501 is saved. Here, the following processing is executed.
(1) The address of the blinking request flag (“F28D (H)”) is stored in the HL register.
(2) The A register value is stored in the address indicated by the HL register value (“F28D (H)”).
As a result, the blinking item becomes "1", and the non-blinking item becomes "0". In this way, the information corresponding to each bit is represented by "1" or "0", and the blinking request flag for seven items including whether or not to blink is stored in the address "F28D (H)". ..

FIG. 209 is a flowchart showing the ratio display timer update (S_RATE_TIME) in step S2465 in FIG. 206.
First, in step S2511, the display switching time is updated. Here, the following processing is executed.
(1) The address (the start address "F290 (H)") that stores the display switching time is stored in the HL register.
(2) The data stored in the address indicated by the HL register value is subtracted by "1", and the subtracted result is stored in the address.
This process executes a cyclic subtraction process that circulates between "0" and "2144 (D)" when expressed in decimal as the display switching time.
Therefore, if the process is performed when the display switching time is "0", "2144 (D)" (860 (H)) is stored as the display switching time.
Further, when the process is performed when the value is "0" and "2144 (D)" (860 (H)) is stored as the display switching time, the carry flag = "1".
Since interrupt processing is executed every 2.235 ms, the number changes from “0” to “2144 (D)” every about 4792 ms, and the carry flag = “1”.
As a result, the ratio display content is switched about every 5 seconds.

In the next step S2512, it is determined whether or not the display switching time has elapsed. This determination determines whether or not the carry flag = "1" in the process of step S2511, and when the carry flag = "1", it is determined that the display switching time has elapsed.
When it is determined that the display switching time has elapsed, the process proceeds to step S2513, and when it is determined that the display switching time has not elapsed, the process proceeds to step S2518.
In step S2513, the blinking switching time is saved. In this process, "134 (D) (86 (H))" is stored in the address (blinking switching time) indicated by the data obtained by adding "2" to the HL register value (that is, "F292 (H)").
That is, when it is determined that the display switching time has elapsed, the blinking switching time is saved. As the blinking switching time, the time of "2.235 x 134 = 299.49 (ms)" is stored.

Next, the process proceeds to step S2514 to turn off the blinking switching flag. Here, the following processing is executed.
(1) The address of the blinking switching flag (“F28F (H)”) is stored in the HL register.
(2) “0” is stored in the address indicated by the HL register value.
As described above, when the data stored in the blinking switching flag is "0", it means lighting, and when it is "1", it means turning off.
That is, when the display switching time has elapsed, the blinking switching flag becomes "0" (lights up).

Next, the process proceeds to step S2515 to update the ratio display number. Here, the following processing is executed.
(1) The HL register value is subtracted by "1".
In other words, the address of the RWM53 (“F28E (H)”) corresponding to the ratio display number is stored in the HL register.
(2) Add "1" to the data stored in the address indicated by the HL register value.
In this process, a cyclic addition process is executed in which the ratio display number is circulated between "0" and "5". Therefore, if the process is performed when the ratio display number is "5", "0" is stored as the ratio display number. Further, if the processing is performed when the ratio display number is less than "5", the carry flag = "1".

In the next step S2516, it is determined whether or not the updated ratio display number is "0". Here, when the carry flag = "1", it is determined that the ratio display number is not "0". In other words, when the process of step S2515 is executed when the ratio display number is "5" and the ratio display number becomes "0", it is determined that the ratio display number is "0".
In step S2516, when it is determined that the updated ratio display number is "0", the process proceeds to step S2517, and when it is determined that it is not "0", the process according to this flowchart is terminated.
In step S2517, the ratio display number is corrected. This process is a process of adding "1" to the data stored in the address indicated by the HL register value. By this process, when "0" is stored in the ratio display number, it is updated to "1". As a result, the ratio display number circulates from "1" to "5". Then, the process according to this flowchart is completed.

When it is determined in step S2512 that the display switching time has not elapsed and the process proceeds to step S2518, the blinking switching time is updated. Here, the following processing is executed.
(1) The address (“F292 (H)”) of the blinking switching time is stored in the HL register.
(2) The data stored in the address indicated by the HL register value is subtracted by "1", and the subtracted result is stored in the address.
This process executes a cyclic subtraction process that circulates between "0" and "134 (D)" when expressed in decimal as the blinking switching time.
Therefore, if the process is performed when the blinking switching time is "0", "134 (D)" (86 (H)) is stored as the blinking switching time.
Further, when the process is performed when the value is "0" and "134 (D)" (86 (H)) is stored as the blinking switching time, the carry flag = "1".

Next, the process proceeds to step S2519, and it is determined whether or not the blinking switching time has elapsed. This determination determines whether or not the carry flag is "1", and when the carry flag ≠ "1", it is determined that the blinking switching time has not elapsed. When it is determined that the blinking switching time has elapsed, the process proceeds to step S2520, and when it is determined that the blinking switching time has not elapsed, the process according to this flowchart ends.
In step S2520, the blinking switching flag is updated. Here, the following processing is executed.
(1) The address of the blinking switching flag (“F28F (H)”) is stored in the HL register.
(2) The data stored in the address indicated by the HL register value is added by "1", and the added result is stored in the address.
In this process, the blinking switching flag is circulated between "0" and "1" to execute a circular addition process. Therefore, if this process is performed when the blinking switching flag is "1", "0" is stored as the blinking switching flag.
Then, the process according to this flowchart is completed.

FIG. 210 is a flowchart showing the ratio display process (S_LED_OUT) in step S2466 in FIG. 206.
In the twentieth to twenty-fourth embodiments, the ratio display process (S_LED_OUT) when blinking is not considered has been described (FIGS. 135, 141, 150, 159).
The 26th embodiment of FIG. 210 is a flowchart based on FIG. 135 of the 20th embodiment, and is different from the 20th embodiment (FIG. 135) by underlining under the step number in FIG. 210. I'm pulling. The processing of the step numbers that are not underlined is the same as that of the 20th embodiment (FIG. 135).

In FIG. 210, first, in step S1471, the LED display counter is acquired. This process is a process of acquiring the value of the LED display counter and storing it in the D register.
In the next step S1472, it is determined whether or not there is a ratio display request. Here, it is determined whether or not there is a display request for any of the digits 6 to 9. Specifically, the LED display counter value stored in the D register and "11111000 (B)" are ANDed. Then, when the AND calculation result is not "0", it is determined that there is no ratio display request, and the process according to this flowchart is terminated. On the other hand, when the AND calculation result is "0", it is determined that there is a ratio display request, and the process proceeds to step S1473.

In the next step S1473, it is determined whether or not the LED display counter value stored in the D register is "0". If it is determined to be "0", the process proceeds to step S1474, and if it is determined that the value is not "0", the process proceeds to step S1475.
In step S1474, a ratio (single digit) display request is set. Similar to that described in the twentieth embodiment, when the LED display counter is "0000000 (B)" (when the digit 9 signal is on), the digit 9 signal is assigned to the D3 bit, so that the D3 bit is assigned. Create the digit data "00001000 (B)" set to "1". In step S1474, this process is executed, and the digit data “00001000 (B)” is stored in the D register. Then, the process proceeds to step S1475.

In the next step S1475, the ratio display number (address "F28E (H)") is acquired. This process executes a process of acquiring the ratio display number, storing it in the A register, and further storing the A register value in the E register.
Here, the number of blinking bit inspections, which will be described later, is determined based on the ratio display number. For example, the following is an example.
Example 1)
Ratio display number is "1": Acquires the number of blinking bit inspections of the advantageous section ratio.
Example 2)
Ratio display number is "2": Acquires the number of blinking bit inspections of the continuous accessory ratio (6000 times).
Example 3)
Ratio display number is "5": Acquires the number of blinking bit inspections of the accessory ratio (total cumulative total).
Further, by executing the process of storing the A register value in the E register, the A register value and the E register value become the same value.

In the next step S2531, the address of the blinking bit inspection count table is set. In this process, the address obtained by subtracting "1" from the start address of the blinking bit check count table (TBL_FLASH_CHK) is stored in the HL register.
FIG. 211 is a diagram showing a blinking bit inspection number table (TBL_FLASH_CHK). As shown in FIG. 211, a predetermined value (for example, the value corresponding to the advantageous section ratio is “7 (H)”) is stored for each ratio.
The start address is "2510 (H)". Therefore, "250F (H)" is stored in the HL register.

The "number of blinking bit inspections" is a value indicating how many bits ahead of the D0th bit in the blinking request flag of the address "F28D (H)" to reach the bit to be inspected.
For example, in FIG. 211, "7 (H)" is stored in the advantageous section ratio, the continuous accessory ratio (cumulative), and the accessory ratio (cumulative), which is the D0 bit in the blinking request flag. It is a value for determining whether or not the value of the 7th D6 bit counted from the eye is "1". The D6 bit is a flag that becomes "1" when the total number of games has not reached 175,000, and when the D6 bit is "1", as shown in FIG. 184, an advantageous section. The identification segment of the ratio, the continuous accessory ratio (cumulative), and the accessory ratio (cumulative) is the target of blinking.
Further, in FIG. 211, "6 (H)" is stored in the continuous accessory ratio (6000 times) and the accessory ratio (6000 times), but this is from the D0th bit in the blinking request flag. It is a value for determining whether or not the value of the sixth D5 bit counted is "1". The D5 bit is a flag that becomes "1" when the total number of games has not reached 6000, and when the D5 bit is "1", as shown in FIG. 184, a continuous combination The identification segment of the object ratio (6000 times) and the accessory ratio (6000 times) is the object of blinking.

In the next step S2532, the number of identification segment blinking bit inspections is set. Here, the following processing is executed.
(1) The data obtained by adding the A register value to the HL register value is stored in the HL register.
(2) The data stored in the address indicated by the HL register value is stored in the B register.
For example, when the A register value (ratio display number stored in step S1475) is "3",
250F (H) + 3 (H) = 2512 (H) (= HL register value)
6 (H) (= B register value)
Will be.
In other words, "250F (H)" becomes the reference address, and the data stored in the ratio display number (address "F28E (H)") is used as the offset value to calculate the address of the blinking bit inspection table and store it in that address. It becomes possible to acquire the data that has been set.
In the above example, "6 (H)", which is information for determining whether or not to blink the identification segment when the accessory ratio (6000 times) stored in the address "2512 (H)" is acquired, is acquired. Will be done.
Next, the process proceeds to step S1476 to set the identification segment offset table. This process is a process of storing the start address of the identification segment offset table (“TBL_SEGID_DATA” in FIG. 127) in the HL register. Although not shown in FIG. 127, the start address is "2520 (H)" in the 26th embodiment, and a value (251F (H)) obtained by subtracting "1" from this address is stored in the HL register. ..

In the next step S1477, the identification segment offset value is acquired. This process is a process of reading from the identification segment offset table using the ratio display number stored in the A register in step S1475 as an offset value.
Specifically, the following processing is executed.
(1) The data obtained by adding the A register value to the HL register value is stored in the HL register.
(2) The data stored in the address indicated by the HL register value is stored in the A register.
As a result, for example, when the ratio display number is "1", "2520 (H)" obtained by adding "1 (H)" to "251F (H)" is stored in the HL register and stored in the address. The generated data "7A (H)" is stored in the A register. When the ratio display number is "2", "2521 (H)" obtained by adding "2 (H)" to "251F (H)" is stored in the HL register, and the data stored in the address is stored. "6B (H)" is stored in the A register.

In the next step S1478, it is determined whether or not there is a display request (display request for digit 6) of the ratio (1000 digits). Here, it is determined whether or not the D0 bit of the value (LED display counter value) stored in the D register is "1", and if it is "1", it is determined that there is a display request. If there is a display request for the ratio (1000 digits), the process proceeds to step S1482, and if there is no display request, the process proceeds to step S1479.

In step S1479, it is determined whether or not there is a display request (display request for digit 7) of the ratio (100 digits). Here, it is determined whether or not the D1 bit of the value stored in the D register is "1", and if it is "1", it is determined that there is a display request. If there is a display request for the ratio (100 digits), the process proceeds to step S1483, and if there is no display request, the process proceeds to step S2533.

In step S2533, the number of ratio segment blinking bit inspections is set. Here, the following processing is executed.
(1) Store the E register value in the A register.
(2) The A register value is stored in the B register.
Here, the ratio display number acquired in step S1475 is stored in the E register. Therefore, the same value is stored in the E register, the A register, and the B register.
Next, the process proceeds to step S1480. When the process proceeds to step S1480, there is no request for displaying the ratio (1000 digits) and the ratio (100 digits), that is, when there is no request for displaying the identification segment (when displaying the ratio segment). Therefore, in step S1480, the ratio data is acquired.
In this step S1480, the numerical value corresponding to the ratio display number stored in the E register is acquired. For example, when the E register value is "00000001 (B)" corresponding to the ratio display number "1", the advantageous section ratio data is acquired.

The acquisition of specific ratio data is as follows.
(1) In the HL register, a value (“F284 (H)”) obtained by subtracting “1” from the address (“F285 (H)”) of the RWM53 in which the advantageous section ratio data is stored is stored.
(2) The data obtained by adding the A register value to the HL register value is stored in the HL register.
(3) The data stored in the address indicated by the HL register value is stored in the A register.
That is, the RWM address in which the ratio data is stored is calculated (designated) with "F284 (H)" as the reference address and the ratio display number as the offset value, and the data stored in the RWM address is registered (storage area). Can be acquired (remembered).
By this processing, the advantageous section ratio data, the continuous bonus ratio data (6000 times), the bonus ratio data (6000 times), the continuous bonus ratio data (cumulative), and the bonus ratio data (cumulative) are stored in the A register. An offset value for displaying any ratio is stored. This offset value (A register value) is used when acquiring the ratio display segment data in step S1484.

Next, the process proceeds to step S1481 to determine whether or not there is a ratio (single digit) display request (digit 9 display request). This process is a process of determining whether or not the D3 bit of the value stored in the D register is "1". If there is a display request for the ratio (1 digit), the process proceeds to step S1483, and if there is no display request, the process proceeds to step S1482.
When there is no request for displaying the ratio (1 digit) in step S1481, it means that there is a request for displaying the ratio (10 digits).

Through the above processing, if there is a request to display the ratio (1000 digits) or the ratio (10 digits), the process proceeds to step S1482, and if there is a request to display the ratio (100 digits) or the ratio (1 digit), the process proceeds to step S1483. ..
In step S1482, the offset for the upper digit is set. This is to turn on the upper digit of the identification segment or the ratio segment when the process proceeds to step S1482. At this point, the identification segment offset value (step S1477) or the ratio data (step S1480) is stored in the A register. Then, here, the following processing is executed.
(1) The lower 4 bits and the upper 4 bits stored in the A register are exchanged.
For example, when the data before replacement is "0011/1001 (B)"("/" indicates the boundary between the upper 4 bits and the lower 4 bits), the lower 4 bits and the upper 4 bits are exchanged. And "1001/0011 (B)".
(2) The A register value and "000011111 (B)" are ANDed, and the calculation result is stored in the A register. Since the lower 4 bits of the A register are used as the offset value in this process, the upper 4 bits are masked (set to "0").
As described above, of the 1-byte data of the identification segment offset value and the 1-byte data of the offset value for displaying the ratio, the upper 4 bits correspond to the offset value of the upper digit, and the lower 4 bits correspond to the lower digit. It corresponds to the offset value. Therefore, by performing the above processing, an offset value for acquiring the segment data of the upper digit is generated.

In the next step S1483, the ratio display segment data table (TBL_SEGRATE_DATA) is set. This process is a process of storing the start address of the ratio display segment data table in the HL register in FIG. 127.
Although the address is not shown in FIG. 127, in the 26th embodiment, since the start address is “2530 (H)”, “2530 (H)” is stored in the HL register.

Next, the process proceeds to step S1484 to acquire segment output data. In this process, the A register value (offset value) is added to the HL register value (start address of the ratio display segment data table), and the data corresponding to the address of the ratio display segment data table after the addition is stored in the E register. It is a process.
Specifically, for example
HL register value = 2530 (H) (before addition; start address value of ratio display segment data table)
A register value = 5 (H)
When is
HL register value = 2535 (H) (after addition)
E register value = 01101101 (B) (“5” display data)
Will be.

Next, the process proceeds to step S1485, and it is determined whether or not the segment P is displayed. In the present embodiment, when the digits 6 to 9 are displayed, the segment P (dot) of the digit 7 is always displayed. Therefore, when there is a request to display the ratio (100 digits), it is determined that the segment P is displayed. .. On the other hand, when there is a display request for the ratio (1 digit), the ratio (10 digits), and the ratio (1000 digits), it is determined that there is no display request for the segment P.
Here, for example, it is determined whether or not the D1 bit of the value stored in the D register is "1", and if it is "1", it is determined that there is a display request for the segment P, and if it is not "1". Determines that there is no display request for segment P. Specifically, the following processing is executed.
(1) “00000010 (B)” is stored in the A register.
(2) The A register value and the D register value (LED display counter value stored in step S1471) are ANDed, and when the calculation result is not "0", it is determined that there is a display request for the segment P.

When it is determined that there is a display request for the segment P, the process proceeds to step S1486, and when it is determined that there is no display request, the process proceeds to step S2534.
In step S1486, the output data corresponding to the segment P is set. Since the segment P corresponds to the D7 bit of the 8-bit data, the segment data (E register value) acquired in step S1484 and "10000000 (B)" are OR-operated, and the operation result is stored in the E register. Remember.

In the next step S2534, the blinking request flag is acquired. This process is a process of storing the data of the blinking request flag (address "F28D (H)") in the A register.
Next, the process proceeds to step S2535, and the blinking bit inspection is performed. This process shifts the A register to the right by "1" and stores the result of the shift and overflow in the carry flag. That is, the value of the D0 bit before the "1" shift is stored in the carry flag. Therefore, if the value of the D0 bit before the "1" shift is "0", the carry flag = "0", and if the value of the D0 bit before the "1" shift is "1", the carry flag = "1". Become.

In the next step S2536, it is determined whether or not the inspection is completed. Here, the following processing is executed.
(1) Subtract "1" from the B register value.
(2) When it is determined that the B register value is "0", it is determined that the inspection has been completed.
When it is determined that the inspection has been completed, the process proceeds to step S2537, and when it is determined that the inspection has not been completed, the process returns to step S2535.
By the above processing, the value of the blinking request flag is shifted to the right by the number of times initially stored in the B register, and the result of the shift and overflow at that time is stored in the carry flag.

For example, when the value of the blinking request flag is "01000000 (B)" (the blinking flag of the D6 bit 175000 times is on) and the B register value is "7 (H)",
1st time: "01000000 (B)" → "0010000 (B)", carry flag = "0"
B register value = 7-1 = 6 (H)
Second time: "0010000 (B)" → "00010000 (B)", carry flag = "0"
B register value = 6-1 = 5 (H)
Third time: "00010000 (B)" → "00001000 (B)", carry flag = "0"
B register value = 5-1 = 4 (H)
4th time: "00001000 (B)" → "0000100 (B)", carry flag = "0"
B register value = 4-1 = 3 (H)
5th time: "00000100 (B)" → "00000010 (B)", carry flag = "0"
B register value = 3-1 = 2 (H)
6th time: "00000010 (B)" → "00000001 (B)", carry flag = "0"
B register value = 2-1 = 1 (H)
7th time: "00000001 (B)" → "0000000000 (B)", carry flag = "1"
B register value = 1-1 = 0 (H)
Will be.

In step S2537, it is determined whether or not the blinking request flag is on. In this process, it is determined whether or not the carry flag when it is determined that the inspection is completed in step S2536 is "1", and when it is "1", it is determined that the blinking request flag is on. When it is determined that the blinking request flag is on, the process proceeds to step S2538, and when it is determined that the blinking request flag is not on, the process proceeds to step S1487.

In step S2538, it is determined whether or not the blinking switching flag is on. Here, the following processing is executed.
(1) The data of the blinking switching flag (address "F28F (H)") is stored in the A register.
(2) When the A register value is "0" (second zero flag = "1"), it is determined that the blinking switching flag is not on.
When it is determined that the blinking switching flag is on, the process proceeds to step S2539, and when it is determined that the blinking switching flag is not on, the process proceeds to step S1487.
From steps S2537 and S2538,
a) If the blinking request flag is off (“No” in step S2537), the process does not proceed to step S2538, so that the blinking switching flag is not turned off even if it is on.
b) Even if the blinking request flag is on (“Yes” in step S2537), if the blinking switching flag is off (“No” in step S2538), the light is turned on.
c) If the blinking request flag is on (“Yes” in step S2537) and the blinking switching flag is on (“Yes” in step S2538), the process proceeds to step S2539 and the light is turned off.

In step S2539, the segment data is cleared. This process is a process of storing the B register value in the E register.
Here, the B register value is always "0" when it is determined in step S2536 that the inspection is completed. Therefore, this process is a process of setting "0" in the E register. That is, when the blinking request flag is on (“1”) and the blinking switching flag is on (“1”, that is, off), the interrupt process turns off the display to be turned on, so that the segment In order to set the data (E register value) to "000000 (B)", the process of step S2539 is executed. Then, the process proceeds to step S1487.

In step S1487, in order to output the digit signal and the segment signal, the segment signal is output from the output port 3 and the digit signal is output from the output port 4. Here, the following processing is executed.
(1) The DE register value and the HL register value are exchanged.
Here, the digit signal is stored in the D register. Further, a segment signal is stored in the E register. and,
Swap the data stored in the D register with the data stored in the H register,
The data stored in the E register and the data stored in the L register are exchanged.
This will
The digit signal is stored in the H register.
The segment signal is stored in the L register.
(2) The L register value is output to the output port 3, and the H register value is output to the output port 4.
As a result, the process according to this flowchart is completed, and the process proceeds to step S2467 of FIG. 206.

<27th Embodiment>
In the 26th embodiment, during the main process of FIG. 188, the ratio set process was executed in step S2193, and in this ratio set process (FIG. 191), the ratio calculation process was executed in step S2243.
On the other hand, in the 27th embodiment, one item is calculated with one interrupt for the ratio of five items and the update of the ring buffer number (six items in total). In the 27th embodiment, it is referred to as "ratio calculation" including the update of the ring buffer number.

Here, of course, it is also possible to execute the ratio calculation of 6 items at the time of one interrupt. However, since interrupt processing includes various processing (see FIG. 190), we want to minimize the time required for ratio calculation. Therefore, in the 27th embodiment, the ratio calculation of one item is executed by one interrupt process.

As the 27th embodiment, three examples (1) to (3) will be given. The processing corresponding to each embodiment is as follows.
a) 27th Embodiment (1)
Main processing (M_MAIN): Same ratio set processing as in the 26th embodiment (S_RATE_SET): FIG. 212
Ratio display preparation (S_DSP_READY): Fig. 213
Ratio calculation management (S_CAL_CTL): FIG. 214 (processing specific to the 27th embodiment)
Ratio calculation process (S_CAL_SET): Fig. 215
Ring buffer number update (S_RONGNO_SET): Same as the 26th embodiment (Fig. 205)
Ratio display processing (S_LED_OUT): Same as the 26th embodiment (FIG. 210)

b) 27th embodiment (2)
Main processing (M_MAIN): Fig. 216
Ratio set processing (S_RATE_SET): Fig. 217
Ratio display preparation (S_DSP_READY): Same as the 26th embodiment (Fig. 206)
Ratio calculation management (S_CAL_CTL): Same as 27th embodiment (1) (Fig. 214)
Ratio calculation process (S_CAL_SET): Same as 27th embodiment (1) (Fig. 215)
Ring buffer number update (S_RONGNO_SET): Same as the 26th embodiment (Fig. 205)
Ratio display processing (S_LED_OUT): Same as the 26th embodiment (FIG. 210)

b) 27th embodiment (3)
Setting change process (M_RANK_SET): Fig. 218
Power-on ratio calculation (S_CAL_PWON): Fig. 219
Main processing (M_MAIN): Fig. 220
Ratio set processing (S_RATE_SET): Same as 27th embodiment (2) (FIG. 217)
Ratio display preparation (S_DSP_READY): Same as the 26th embodiment (Fig. 206)
Ratio calculation management (S_CAL_CTL): Same as 27th embodiment (1) (Fig. 214)
Ratio calculation process (S_CAL_SET): Same as 27th embodiment (1) (Fig. 215)
Ring buffer number update (S_RONGNO_SET): Same as the 26th embodiment (Fig. 205)
Ratio display processing (S_LED_OUT): Same as the 26th embodiment (FIG. 210)

<27th Embodiment (1)>
In the 27th embodiment (1), the ratio calculation is executed during the interrupt processing.
FIG. 212 is a flowchart showing the ratio setting process (S_RATE_SET) of the 27th embodiment (1), and is a flowchart corresponding to FIG. 191 of the 26th embodiment.
In the 27th embodiment (1), during the main process (M_MAIN) of FIG. 188, step S2550 of FIG. 212 is executed instead of step S2193.
In the description of the 27th embodiment, the steps for executing the same processing as those of the 26th embodiment are designated by the same step numbers, and the description thereof will be omitted. Further, the steps different from the 26th embodiment are underlined under the step number.

As shown in FIG. 212, in the ratio set process, after updating the 400 game counter in step S2242, the process proceeds to step S2551 to execute the calculation number set. In the 27th embodiment, the RWM 53 is provided with a storage area called “number of calculations”. Then, in step S2551, "6" is set in the storage area of "number of calculations". The storage area of this "calculation count" is set so as to be outside the range that is cleared when the setting is changed. By doing so, when the power is turned off before the calculation of the six items described below is completed and the power is turned on while the setting key switch is turned on (setting change mode transition condition). Even when the RWM clear is executed (when is satisfied), it is possible to execute the calculation from the middle without executing the calculation from the beginning. In addition, "6" means 6 interrupt processes, which are advantageous section ratio, continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), and bonus ratio (cumulative). ), It means to execute the calculation of 6 items of ring buffer number update.
If the storage area of the "calculation count" is cleared at the time of transition to the setting mode, there is an inconvenience that some ratios are not calculated. For example, if the setting change mode is entered when the number of calculations is "4" and the number of calculations is cleared, the ratio after "3" will not be calculated (note that the relationship between the number of calculations and the ratio is not calculated. See below). Specifically, the latest ratio data is used for the bonus ratio (cumulative) and continuous bonus ratio (cumulative), but the bonus ratio (6000 times), continuous bonus ratio (6000 times), advantageous section ratio, And the ring buffer number will not be the latest ratio data.
Therefore, even when the mode is changed to the setting change mode, the storage area of the "calculation count" is not cleared.

In particular, in the present embodiment, the following ratio is calculated according to the number of calculations.
Number of calculations after update (when "1" is subtracted) "5": Character ratio (cumulative)
Number of calculations after update (when "1" is subtracted) "4": Continuous bonus ratio (cumulative)
Number of calculations after update (when "1" is subtracted) "3": Character ratio (6000 times)
Number of calculations after update (when "1" is subtracted) "2": Continuous bonus ratio (6000 times)
Number of calculations after update (when subtracting "1") "1": Advantageous interval ratio Number of calculations after update (when subtracting "1") "0": Number of calculations before updating ring buffer number "0": No calculation Further, in the ratio setting process of FIG. 212, unlike the 26th embodiment (FIG. 191), the ratio calculation process (S_CAL_SET) of step S2243 and the ring buffer number update (S_RINGNO_SET) of step S2244 are provided in FIG. No. This is because these processes are executed by interrupt processing.

FIG. 213 is a flowchart showing the ratio display preparation (S_DSP_READY) in the 27th embodiment (1), and is a flowchart corresponding to FIG. 206 of the 26th embodiment.
In the 27th embodiment (1), during the interrupt processing (I_INTR) of FIG. 190, step S2560 of FIG. 213 is executed instead of step S2221.
In the ratio display preparation of the 27th embodiment (1), the ratio calculation management (S_CAL_CTL) of step S2561 is performed between the register save in step S2463 and the blinking request flag generation (S_LED_FLASH) in step S2464 (FIG. 214 described later). To execute. Others are the same as those of the 26th embodiment (FIG. 206).

FIG. 214 is a flowchart showing the ratio calculation management (S_CAL_CTL) in step S2561 of FIG. 213.
First, in step S2571, the number of calculations is updated. This process is a process of subtracting "1" from the number of calculations of the RWM53 described above. Here, the following processing is executed.
(1) The address of the number of calculations is stored in the HL register.
(2) The value stored in the address indicated by the HL register value is stored in the A register.
(3) Subtract "1" from the A register value.
(4) The data stored in the A register is stored in the address indicated by the HL register value.

In the next step S2572, it is determined whether or not the number of calculations before the update of step S2571 is "0". For example, when the A register value in (2) above is "0", it is determined that the number of calculations before updating is "0". When it is determined that the number of calculations before the update is "0", the process according to this flowchart is executed, and when it is determined that the number of calculations is not "0", the process proceeds to step S2573.
In step S2573, it is determined whether or not the number of calculations after the update in step S2571 is "0". For example, when the A register value after the subtraction in (3) above is "0", it is determined that the number of calculations after the update is "0". When it is determined that the number of calculations after the update is "0", the process proceeds to step S2575 (ring buffer number update), and when it is determined that the number of calculations is not "0", the process proceeds to step S2574 (ratio calculation process).

In step S2574, the ratio calculation process (S_CAL_SET) (FIG. 215) is executed, and the process according to this flowchart is completed.
On the other hand, in step S2575, the ring buffer number update (S_RINGNO_SET; FIG. 205) is executed, and the process according to this flowchart is completed.
As described above, when the number of calculations before the update is not "0" and the number of calculations after the update is not "0", the calculation process of one ratio out of the five ratios shown in FIG. 181 is executed once. do. If the number of calculations before the update is not "0" and the number of calculations after the update is "0", the ring buffer number is updated.

FIG. 215 is a flowchart showing the ratio calculation process (S_CAL_SET) in step S2574 of FIG. 214. In FIG. 215, the step numbers are underlined as described above, which is different from the 26th embodiment (FIG. 202).
First, unlike the process of FIG. 202, the process of FIG. 215 does not perform the processes of step S2381, step S2382, and step S2407 in FIG. 202. This is because, as described above, the number of calculations in the ratio calculation process is one.
Further, after the ratio calculation RWM address table set in step S2385, the process proceeds to step S2581.

In step S2581, the count upper limit flag (address "F28B (H)") is acquired. Next, the process proceeds to step S2582, and it is inspected whether or not the ratio calculation should be executed. In the 27th embodiment, when it is determined by the count upper limit flag that the number of games has reached the count upper limit value, it is determined that the advantageous section ratio is not calculated. Further, when it is determined by the count upper limit flag that the number of payouts has reached the count upper limit value, it is determined that the bonus ratio (6000 times and cumulative total) and the continuous bonus ratio (6000 times and cumulative total) are not calculated.
In this respect, the 27th embodiment is different from the 26th embodiment (in the 26th embodiment, as shown in FIG. 202, the ratio is uniform without determining whether or not the upper limit of the count has been reached. The calculation was performed.).
Next, the process proceeds to step S2583, and it is determined whether or not to execute the ratio calculation process. For example, in the interrupt processing this time, when the advantageous section ratio is calculated, when the game count upper limit flag of the count upper limit flag is "0", it is determined that the calculation of the advantageous section ratio is executed. On the other hand, when the game count upper limit flag of the count upper limit flag is "1", it is determined that the calculation of the advantageous section ratio is not executed.

Further, for example, in the interrupt processing this time, when the bonus ratio (cumulative) is calculated, when the payout number upper limit flag of the count upper limit flag is "0", it is determined that the bonus ratio (cumulative) is calculated. .. On the other hand, when the payout upper limit flag of the count upper limit flag is "1", it is determined that the calculation of the accessory ratio (cumulative) is not executed.
When it is determined in step S2583 that the calculation is to be executed, the process proceeds to the process after step S2386, and when it is determined that the calculation is not executed, the process according to this flowchart is terminated.

<27th Embodiment (2)>
In the 27th embodiment (2), the ratio is calculated during the main processing, as in the 26th embodiment.
FIG. 216 is a flowchart showing the main process (M_MAIN) of the 27th embodiment (2), and is a flowchart corresponding to FIG. 188 of the 26th embodiment.
In the 27th embodiment (2), a setting change flag is provided as a flag stored in the RWM 53. The setting change flag means that the setting can be changed when it is on, and that the setting cannot be changed when it is off.
In FIG. 216, after the game start set in step S2172 is completed, the process proceeds to step S2591 to turn on the setting change flag. When the operation of the start switch 41 is detected in step S2178, the setting change flag is turned off in the next step S2592. As a result, the setting can be changed during the game standby (before the game starts (operation of the start switch 41)), and the setting cannot be changed after the game starts (after the start switch 41 is operated).

The reason for setting in this way is that in the 27th embodiment, the ratio calculation of one item is performed in one interrupt process. Specifically, since the ratio calculation (ratio set processing in step S2593) is performed after the medal is paid out during the main processing, the setting change processing is performed before all the calculations (6 times) are completed, and the RWM53 clear processing is performed. When it is done, when the ratio is displayed by the subsequent interrupt processing, the calculation is completed for one ratio, but the calculation is not completed for another ratio, and the ring buffer number is updated normally. In order to prevent abnormalities such as not being performed, a setting change prohibition section is provided.
In the example of FIG. 216, the setting changeable section is from after the game start set to before the operation of the start switch 41, and the setting non-changeable section is from after the operation of the start switch 41 to before the game start set of the next game. Therefore, even if the power is turned off while looping steps S219 to S2594, the process does not shift to the setting change process.

Further, since the calculation is executed 6 times after the medal is paid out, if the interrupt is permitted after the ratio setting process in step S2593 (step S2195), the process proceeds to step S2594 and whether or not the number of calculations is "0". If is not "0", the process returns to step S2190 and interrupt wait processing is executed. Then, when interrupt processing is performed after that, the ratio set processing (one ratio calculation) is executed again in step S2593. On the other hand, when it is determined in step S2594 that the value is "0", the process proceeds to step S2196 to execute the game end check process.

FIG. 217 is a flowchart showing the ratio setting process (S_RATE_SET) in the 27th embodiment (2), which is the process of step S2593 of FIG. 216.
In the 27th embodiment (1), the ratio calculation management (S_CAL_CTL) is not executed in the ratio set processing (S_RATE_SET; FIG. 212), and the ratio calculation is performed in step S2561 in the ratio display preparation (S_DSP_READY) of FIG. Management (S_CAL_CTL) was executed.
On the other hand, in the 27th embodiment (2), the ratio calculation management (S_CAL_CTL) is executed in the ratio set process (S_RATE_SET) of FIG. 217 (step S2603). Therefore, the ratio calculation management (S_CAL_CTL) is not executed in the ratio display preparation. The ratio display preparation of the 27th embodiment (2) is the same as that of the 26th embodiment (FIG. 206) as described above.

In FIG. 217, after the processing of step S2234, the process proceeds to step S2601 to determine whether or not the number of calculations is “0”. When it is determined that the number of calculations is not "0", the process proceeds to step S2603 (ratio calculation management). On the other hand, when it is determined that the number of calculations is "0", the process proceeds to step S2235 (count upper limit check).
Further, after the processing of step S2242, the process proceeds to step S2602 to set the number of calculations (“6”), which is the same as that of the 27th embodiment (1) (step S2551 in FIG. 212). Therefore, when it is determined in step S2601 that the number of calculations is "0", the number of calculations is set to "6" in step S2602.

<27th Embodiment (3)>
In the 27th embodiment (3), the ratio is calculated during the setting change process and the main process.
FIG. 218 is a flowchart showing the setting change process (M_RANK_SET) in the 27th embodiment (3), and is a flowchart corresponding to FIG. 186 of the 26th embodiment.
The setting change process of FIG. 218 is different from the 26th embodiment (FIG. 186) in that when the initialization (outside the used area) is completed in step S2131, the power-on ratio calculation (S_CAL_PWON) of step S2611 is executed. .. In this power-on ratio calculation, the ratio of 6 items is calculated. After that, the process proceeds to step S2133 to activate the interrupt. In the 27th embodiment (3), the ratio calculation is not performed in the interrupt processing.

FIG. 219 is a flowchart showing the power-on ratio calculation (S_CAL_PWON) in step S2611 of FIG. 218.
First, in step S2621, the stack pointer is saved. In this process, the stack pointer (SP register) stored in the stack area is stored in the stack pointer temporary storage buffer 2 (address "F293 (H)").
As described above, the ratio calculation is a program that is executed outside the used area. Therefore, when the program outside the used area is being executed, the stack pointer is saved and the stack pointer is stored in the used area (first program). Returns the stack pointer when it returns.
In the next step S2622, the stack pointer (outside the used area) is set. This process is a process of storing "F400 (H)" in the stack pointer (SP register).
In the next step S2623, the register is saved. This process is a process of saving various registers to the stack area (outside the used area).
Next, the process proceeds to step S2624, and the upper address of the RWM53 is set in the Q register. This process is a process of storing "F2 (H)" in the Q register.

In the next step S2625, the ratio calculation management (S_CAL_CTL) is executed. This ratio calculation management is the same process as in the 27th embodiment (1) (FIG. 214). Then, in the next step S2626, it is determined whether or not the number of calculations is "0". When it is determined that the number of calculations is "0", the process proceeds to step S2627, and when it is determined that the number of calculations is not "0", the process returns to step S2625 to execute the ratio calculation.
Then, when the ratio calculation of the six items is completed and the process proceeds to step S2627, the register is restored. This process is a process of restoring various registers saved in step S2623.
In the next step S2628, the stack pointer is returned. This process is a process of storing the stack pointer saved in step S2621, that is, the data stored in the stack pointer temporary storage buffer 2 in the stack pointer (SP register). Then, the process according to this flowchart is completed.

FIG. 220 is a flowchart showing the main process (M_MAIN) in the 27th embodiment (3) (in FIG. 218, the transition is made after the setting change process is completed), and is a flowchart corresponding to FIG. 188 of the 26th embodiment. ..
In the 27th embodiment (3), the ratio calculation (ratio set processing in step S2641) is executed during the main processing as in the 26th embodiment. This ratio set process is the same process as in the 27th embodiment (2) (FIG. 217). That is, the ratio calculation management (S_CAL_CTL) (FIG. 214) is executed until the number of calculations becomes "0".
Further, every time the ratio set process is executed, the process proceeds to step S2642, it is determined whether or not the number of calculations is "0", and when it is determined to be "0", the game end check process of step S2196 is performed. When the process proceeds and it is determined that the value is not "0", the process returns to step S2190 and the ratio setting process (step S2641) is executed again.
In the main process of the 27th embodiment (3), the ratio is calculated in both the setting change process and the main process, and the ratio is calculated before the interrupt process in the setting change process. Therefore, the 27th embodiment ( It is not necessary to provide a setting non-changeable period as in the main process (FIG. 216) of 2).

Although the 26th and 27th embodiments of the present invention have been described above, the 26th and 27th embodiments are not limited to the above-described embodiments, and various modifications such as the following are possible. ..
(1) In the 26th embodiment, as shown in FIGS. 188 and 191 each game, the count upper limit check (S_LIMIT_CHK) is performed. Therefore, the count upper limit flag is updated every game.
On the other hand, it is also possible to update the count upper limit flag only in the game in which the number of games or the number of payouts reaches the upper limit value.
In this case, in FIG. 192, the value of the count upper limit flag is first determined (before step S2251), and when the D0 and D1 bits are "1", the count upper limit check process is terminated. ..
In addition, it is determined whether or not the total number of games counter and the total payout (cumulative) counter are 3 bytes full without setting the count upper limit flag, and if it is 3 bytes full, it is determined that the count is the upper limit. Is also possible. Examples of this method include the following a) first method and b) second method.

a) First method Both the total number of games counter and the total payout (cumulative) counter are composed of 3 bytes. Here, the most significant byte is the Ath byte, and the lower 2 bytes are the Bth and Cth bytes (the least significant byte is the Cth byte).
Then, whether or not all the A, B, and C bytes are full (3 bytes full (“FFFFFF (H)”)) is calculated as follows.
First, the A-byte and the B-byte are ANDed. Next, "FF (H)" is subtracted from the result of the AND operation. As a result, when it becomes "0" (zero flag = "1"), the operation proceeds to the next operation. When the zero flag ≠ "1", it is determined that the operation is not full at that time, and the operation is terminated.
In the next operation, the Ath byte and the Cth byte are ANDed. Next, "FF (H)" is subtracted from the result of the AND operation. As a result, when it becomes "0" (zero flag = "1"), it is determined that it is 3 bytes full, and when the zero flag ≠ "1", it is determined that it is not 3 bytes full.

In the above calculation, if "FF (H)" and "FF (H)" are ANDed, the calculation result becomes "FF (H)", and the "FF (H)" to "FF (H)" This is because if is subtracted, the zero flag = "1".
Then, if the zero flag = "1" as the calculation result of the A-byte and the B-byte and the zero flag = "1" as the calculation result of the A-byte and the C-byte, the A-byte and the B-byte This is because both the and C bytes are "FF (H)".
The above applies not only to the total number of games counter but also to the total payout (cumulative) counter.

b) Second method Of the counter composed of 3 bytes, the lower 2 bytes, the Bth byte and the Cth byte, are stored in, for example, the HL register. Then, "1" is added to the HL register value. As a result of this addition, when the carry flag = "1", the operation proceeds to the next operation, and when the carry flag ≠ "1", the operation ends at this point. This is because the carry flag ≠ "1" means that the HL register value is not "FF".
When the carry flag = "1", the Ath byte, which is the upper 1 byte, is stored in the A register. Then, the carry flag = "1" is added to the A register. As a result, when the carry flag = "1", it is determined that the carry flag is 3 bytes full, and when the carry flag ≠ "1", it is determined that the carry flag is not 3 bytes full.
If the calculation is performed as described above, it is necessary to perform the calculation every time it is determined whether or not it is full of 3 bytes, but it is not necessary to have the count upper limit flag of the address "F28B (H)".

(2) In the above embodiment, the ratio display switching time "about 5.0 seconds" is set to the number of interrupts "2144 (D)", and the blinking switching time "about 0.3 seconds" is set to the number of interrupts "134". (D) ”was set. As a result, when the identification segment or the ratio segment is blinking and displayed, the ratio display content can be switched at the timing when the light is turned off.
However, the present invention is not limited to this, and the display switching time may be set to the number of interrupts closest to "about 5.0 seconds", and the blinking switching time may be set to the number of interrupts closest to "about 0.3 seconds". ..
For example, the number of interrupts for counting the display switching time may be set to "2237 (D)" (2237 × 2.235 ≈ 4999.695 ms).
The number of interrupts closest to "about 0.3 seconds" at the time of blinking switching is "134 (D)", which is the same as that of the 26th embodiment.

In the case of setting in this way, it is conceivable that the display switching time reaches "5.0" seconds immediately after the identification segment or the ratio segment is switched from off to on. Then, for example, when the display is switched to the next display immediately after switching from turning off to turning on, the display contents are switched after being turned on for a moment.
To prevent this from happening (make it look good, don't make you think it might be out of order), for example, when it's time to switch from on to off, and when it's time to switch from off to on. When it arrives, the remaining time of the display switching time is determined, and when the remaining time is, for example, "0.3" seconds or less, the blinking switching timer may not be updated.

As a specific example, for example, when the identification segment or the ratio segment is blinking and the remaining time of the display switching time is, for example, "0.3" seconds or less, the present time until the display switching time arrives. Maintain (extend) the lighting or extinguishing state of. Then, when the display switching time is reached, the display is switched to the next ratio display (at the time of this switching, the blinking switching time is reset). Here, when the off state is maintained and the display switching time becomes "0", the next ratio display may be started from the on state when blinking. On the other hand, when the lighting state is maintained and the display switching time becomes "0", the next ratio display may be started from the off state when blinking.

(3) Contrary to the above example, the display switching time may be changed based on the blinking switching time. For example, as in the 26th embodiment, the blinking cycle is set to "0.6" seconds (lighting "0.3 seconds", extinguishing "0.3" seconds).
Then, when switching from lighting to extinguishing and when switching from extinguishing to lighting, the remaining time of the display switching time is determined, and when the remaining display time is, for example, "0.2" seconds or less, the current display at that time. It is possible to end the ratio display and start the next ratio display (reset the display switching time).
Here, when the ratio display is switched and the next ratio display also satisfies the blinking condition, it may be started from either lighting or extinguishing. Further, when the previous ratio display ends with turning off, the next ratio display may start from lighting, and when the previous ratio display ends with lighting, the next ratio display may start from turning off.

(4) The clear (initialization) range when the RWM error after power-on occurs / does not occur, which is shown in the 26th embodiment, is an example and is not limited to this.
For example, first, when the power is turned on, the RWM53 addresses (for example, "F210 (H)" to "F289 (H)") related to calculation and display are cleared as the RWM clear range when it is not determined that the RWM is abnormal. The address of the RWM53 related to the timer or the like (for example, after "F28A (H)") may be set in the clear range without being set in the range. In this case, after clearing the RWM, the display will start from the advantageous section ratio. The display time of the advantageous section ratio is the initial set value (about 5 seconds).
Secondly, as the RWM clear range when the power is turned on and the RWM is not determined to be abnormal, the RWM53 addresses related to calculation, display, and timer (for example, "F210 (H)" to "F292 (H)"". ) May not be set in the clear range, and other RWM53 addresses (for example, after "F293 (H)") may be set in the clear range. In this case, after clearing the RWM, the display does not always start from the advantageous section ratio. Specifically, the display starts from the display item that was displayed when the power was turned off. Further, the display time of the display item is not always displayed for about 5 seconds. For example, when the power is turned off after "T" seconds have passed since the display of the accessory ratio (6000 times) was started, after the RWM is cleared, the display of the accessory ratio (6000 times) is started and the display is started. , The display time is "5-T" seconds.

(5) In the 26th embodiment, the medal payout number data (F040 (H)) and the medal payout number buffer (F041 (H)) are provided as the storage area of the RWM53. On the other hand, it is also possible to count the number of medals to be paid out using only the data on the number of medals to be paid out without providing the medal payout number buffer.
As described above, the medal payout number data is deducted by "1" each time the stored number one addition or the medal payout process is executed once.
Therefore, each time the addition of one stored number or the payout process of one medal is executed, "1" may be added to the storage area for storing the number of payouts for ratio calculation.

(6) In the 26th embodiment, in the ratio calculation process (S_CAL_SET), the divisions of the tens digit and the ones digit were each multiplied by 10 (calculated value set (S_CAL_SET)). However, the present invention is not limited to this, and it is also possible to obtain by a method of multiplying the value of the divisor by 100 and repeatedly subtracting the divisor until it becomes "0" or more and less than the divisor.
Specifically, in the calculation of "Y (divisor) / X (divisor)"
a) Calculate "100 x Y" by multiplying "Y" by 100.
b) Subtract "X" from "100 x Y", and when the value after subtraction is "X" or more, repeat subtracting "X" from the value after subtraction.
0 ≦ (100 × YX × R) <X
An example is a method of calculating an “R” (ratio) that satisfies the condition.

(7) In the ratio calculation process (S_CAL_SET), a method other than the method shown in FIG. 202 is also possible as a method for setting 99%.
FIG. 221 is a flowchart showing another example of the processing after step S2400 in FIG. 202. In FIG. 221, the processes different from those in FIG. 202 are underlined under the step numbers.
In FIG. 221 after performing the ones place ratio calculation execution (S_CAL_EXE) in step S2400, the process proceeds to S2651 and 99% is set as the ratio. Specifically, the process of storing "99 (H)" in the RWM address corresponding to the calculated ratio is executed.

In the next step S2652, it is determined whether or not the calculated ratio is "99" or more. When the calculated ratio is "99" or "100", it is "Yes". When it is determined that the calculated ratio is "99" or more, the process proceeds to step S2402, and when it is determined that the calculated ratio is not "99" or more, the process proceeds to step S2401. In step S2401, as described above, the calculation result buffer is acquired. Therefore, when the calculated ratio is "99" or more, the ratio "99" set in step S2651 is maintained, and the calculation result buffer is used by proceeding to step S2402 without performing step S2401 (acquisition of the calculation result buffer). initialize. Subsequent processing is the same as in the 26th embodiment (FIG. 202).
Further, also in the 27th embodiment (1) (FIG. 215), FIG. 221 (however, the process of step S2407 is not performed) can be applied.

(8) In the 26th and 27th embodiments, for example, as shown in step S2390 in FIG. 202, when the divisor (value of the denominator) is "0", the ratio calculation is not executed. Here, in the calculated value set in step S2389, the zero flag = "1" is set so that the ratio calculation process is not executed when the divisor is "0".
However, not limited to this, in the calculated value set in step S2389 (FIG. 203), before step S2411, it is determined whether or not the divisor (numerator value) is "0", and it is determined to be "0". When it is determined, the zero flag may be set to "1" (when it is determined that the division number is "0", the processing according to this flowchart is terminated without executing the processing after step S2411. ). As a result, at the end of the calculated value set, if either the divisor or the divisor is "0", the zero flag = "1". Then, the process proceeds to step S2390 of FIG. 202, and it is determined whether or not either the divisor or the divisor is "0", and when either of them is "0" (that is, when the zero flag = "1"). May proceed to step S2407 without performing the ratio calculation after step S2391.

(9) In the 26th embodiment, in the ratio calculation process (FIG. 202), in step S2404, the process of subtracting "A0 (H)" from the calculated ratio is performed, and when there is no carry, the ratio is "100". % ”.
On the other hand, before executing the ratio calculation process, it is possible to determine whether or not the ratio is 100%, and if it is determined that the ratio is 100%, it is possible not to execute the ratio calculation process. .. For example, the divisor (divided number) and the divisor (divided number) are compared, and it is determined whether or not they match, and when it is determined that they match, it can be determined that the ratio is 100%. However, it is judged whether or not at least one of the divisor or the divisor is "0", and when it is judged that at least one of the divisor or the divisor is "0", it is judged that the ratio is not 100% (divided or divisor or). When at least one of the divisors is "0", the ratio is 0%).
Therefore, when starting the ratio calculation process of FIG. 202, the following process is provided before the process of step S2381.

a) The divisor (divided number) and the divisor (divided number) are compared to determine whether or not they match. If it is determined that they match, the process proceeds to b) below. If it is determined that they do not match, the process proceeds to step S2381 in FIG. 202.
b) Determine whether the dividend is "0". If it is determined that it is not "0", the process proceeds to c) below, and if it is determined that it is "0", the process proceeds to step S2407 of FIG. 202 without performing the ratio calculation.
c) Determine if the divisor is "0". When it is determined that it is not "0", the divisor and the divisor match, and neither the divisor nor the divisor is "0". Therefore, in FIG. 202, the process proceeds to step S2405 and 99% is set. On the other hand, when it is determined to be "0", the process proceeds to step S2407 of FIG. 202 without performing the ratio calculation.
Since the above processing includes determination of whether or not the divisor is "0", the processing of step S2390 in FIG. 202 is unnecessary.

(10) In the present embodiment, the storage area of the RWM 53 for storing the number of games (for example, the total number of games counter at the address "F26D (H)") is filled with "1" each time the number of games is consumed by "1". Was added. Similarly, "1" was added to the storage area of the RWM53 (for example, the total payout (cumulative) counter of the address "F27C (H)") for storing the number of payouts for each medal paid out. In this way, the number to be added is set to the same value with respect to the number of games played and the number of payouts. However, not limited to this, for example, for convenience of calculation, every time the number of games is "1" and / or one medal is paid out, "2", "10", etc. It is also possible to store a value other than "1". For example, in the number of advantageous section games of the first embodiment, "100 (D)" is added every time one game is digested in the advantageous section. As described above, the number of games or the number of payouts and the value added to the RWM 53 do not necessarily have to be the same value. Therefore, when adding the number of games, the value corresponding to the number of games may be added, and when adding the number of payouts, the value corresponding to the number of payouts may be added. In the following, for example, the first invention 52 and the like, the "corresponding value" means this.

(11) A display switching counter (1 byte storage area) may be provided instead of the storage area (address “F290 (H)”) for storing the display switching time. In this case, when the blinking switching time elapses, the blinking switching flag (address "F28F (H)") is updated and the display switching counter is updated ("1" is added). For example, the display switching counter is an increment counter that circulates from "0" to "15 (D)", and when "1" is added while "15 (D)" is stored, the ratio is displayed. Control to update the number. Further, when "1" is added while "15 (D)" is stored in the display switching counter, it is controlled so that "0" is stored. It should be noted that the reason for controlling in this way is that "blinking switching time x 16 = display switching time". With such a configuration, the storage area of the RWM can be reduced. Further, the blinking cycle and the display information can be synchronized.

(12) In the ratio set processing (for example, FIG. 191 in the 26th embodiment, FIG. 212 in the 27th embodiment (1), and FIG. 217 in the 27th embodiment (2)), the count upper limit check in step S2335 and step S2236 It is also possible not to make a judgment as to whether or not the upper limit flag of the number of games played is on.
Further, in the count-up of FIG. 194, it is possible not to execute the processing after step S2284 (when "Yes" in step S2282, the processing according to this flowchart is terminated after executing step S2283). be.
When controlling as described above, the process is executed as follows.
First, in the game count of FIG. 193, it is determined whether or not the game count upper limit flag is on before the process of step S2271 (substantially the same process as step S2236). Then, when it is determined that the game count upper limit flag is on, the game count count ends.

Further, in the game count of FIG. 193, after executing step S2273, it is determined whether or not the carry flag is "1". If the carry flag is not "1", the game count is ended. On the other hand, when the carry flag is "1", the D0 bit (game count upper limit flag) of the count upper limit flag (address "F28B (H)") is set to "1". Here, when the carry flag becomes "1", when the total number of games counter is the upper limit value (FFFFFF (H)), "1" is added in step S2273 (count up) in FIG. 193. It's time. In this case, a process of correcting the total number of games counter to a specific value (here, "FFFFFF (H)") is executed. Then, the game count is finished.
Here, as a reason for correcting the total number of games counter to a specific value, it is determined whether or not to blink the identification segment depending on whether or not 6000 or 175,000 games have been executed, and at that time, the total number of games is totaled. This is because the game count counter is referred to. Therefore, the specific value stored in the total number of games counter does not necessarily have to be "FFFFFFF (H)", and it is sufficient to know that it has reached 175,000 times, for example, "F00000 (H)" (decimal number). It may be 15728640 (D)) or the like.

Further, in the advantageous section game count in FIG. 195, when it is determined as "Yes" in step S2291, it is determined whether or not the game number upper limit flag is on, and when it is determined to be on, the advantageous section game count is determined. When the count is finished and it is determined that the count is off, the process proceeds to step S2292 and subsequent steps.
By doing so, it is possible to prevent the value of the advantageous section game count from being added after the total game counter exceeds the upper limit value.

Furthermore, in the payout number count in FIG. 196, it is also possible not to provide the payout number upper limit buffer set in step S2304.
In this case, in the payout number set in step S2303 in FIG. 196, after the count-up in step S2322 is executed in FIG. 197, it is determined whether or not the carry flag is "1", and the carry flag is "1". If it is not, the payout number set is finished, and if the carry flag is "1", the D1 bit (payout number upper limit flag) of the count upper limit flag (address "F28B (H)") is set to "1", and then the payout number is paid out. Finish the number set. Here, the case where the carry flag becomes "1" means that the upper limit value ("FFFFFF (H)") is obtained when the number of payouts is added to the total payout (cumulative) counter value in the count-up in step S2322 in FIG. ) Is exceeded.
For example, it is assumed that when the total payout (cumulative) counter value in the "X" game is "FFFFFE (H)", a small winning combination of eight payouts is won. At this time, by counting up in step S2322, "000006 (H)" is stored in the total payout (cumulative) counter. At this time, the carry flag is set to "1". In this case, the continuous bonus payout (cumulative) counter and the bonus payout (cumulative) counter after the game including the "X" game are not updated.
When configured in this way, the continuous character ratio (cumulative) data of the "X-1" game and the character ratio (cumulative) data are the data after the game including the "X" game. It becomes. This can be done by executing the same process as the process of steps S2581 to S2583 described in FIG. 215 of the 27th embodiment (1).
The count upper limit flag needs to be stored in a storage area that is not cleared even when the setting change mode is entered.

(13) In the above-described embodiment, the winning probabilities of 1BB (1BBA and 1BBB in the first embodiment) (including single winning and overlapping winning with other winning combinations) are the normal section and the advantageous section. The same value was set in, but not limited to this, it is also possible to set different winning probabilities for the normal section and the advantageous section (during the advantageous section, the performance of the accessory is enhanced).
Specifically, the winning probability of the special winning combination in the normal section (indicating the total value including the single winning and the overlapping winning with other winning combinations. The same shall apply hereinafter in the description of (11) and (12) described later). For example, it is set to "1/250" (hereinafter, also referred to as "normal probability" in the description of (11) and (12)). Then, in the normal section, the winning probability ratio (hereinafter referred to as BR ratio) of 1BB and RB (newly provided) is set to, for example, "1: 6" (RB is easier to win). It is assumed that the expected value of the number of payouts in the 1BB game exceeds the expected value of the number of payouts in the RB game.
After winning a special role in the normal section and completing the special game, the player shifts to an advantageous section (whether it is non-AT or AT is arbitrary). Then, in at least a part of the advantageous sections, the winning probability of the special combination is set higher than the normal probability (for example, it is set to about "1/30". Hereinafter, (11) and (12) ), Also referred to as “high probability”).

In this case, firstly, the winning probability of the special combination is set to a high probability throughout the advantageous section.
Secondly, in the advantageous section, the winning probability of the first special combination is set to high probability A, the winning probability of the second special combination is set to high probability B (B <A), and the third time. The winning probability of the special role is set to a high probability C (C <B) (hereinafter, similarly, A>B>C>D> ...).
Thirdly, the following method can be mentioned.
If a special combination is won during the normal section, the special combination is transferred to the advantageous section and the first specific RT (finite RT) after the end of the special game. In the first specific RT, the BR ratio is set to "2: 1" (1BB is easier to win). When the number of games played in the first specific RT is exhausted without winning a special role in the first specific RT, the game is shifted from the first specific RT to the second specific RT. In the second specific RT, the BR ratio is set to, for example, "1: 4". As a result, the RB is easier to win, so that the second specific RT has a lower expected value of the number of medals to be paid out than the first specific RT. On the other hand, when a special role is won during the first specific RT and the game shifts to a special game, after the special game is completed, the number of games of the first specific RT is reset and then the first specific RT is started.
From the finite number of games of the first specific RT and the winning probability of the special role during the first specific RT, the so-called loop rate (probability of winning the special role before the number of games of the first specific RT is exhausted) is calculated. Can be set.

Further, when the special combination is won during the second specific RT and the special game is completed, the process is shifted to the first specific RT on the condition that the end condition of the advantageous section is not satisfied. With this setting, for example, if a special combination is won during the advantageous section, the process can be shifted to the first specific RT again.
In addition, when the end condition of the advantageous section is satisfied, for example, when the continuation upper limit of the advantageous section is reached, both when staying at the first specific RT and when staying at the second specific RT, the first specific RT or the first specific RT, respectively. 2 End the specific RT and shift to the normal section (RT for the normal section). And the winning probability of the special role is also the normal probability. Initializing all the parameters related to the advantageous section when shifting to the RT for the normal section is the same as in the third embodiment (for example, steps S445, S446, S447, and S471 in FIG. 44 (d)). ..

Furthermore, during the normal section, if the player shifts to an advantageous section by winning a rare role without winning a special role (without going through a special game), the first stay RT may be set as the first specific RT. Alternatively, it may be a second specific RT.
Further, as described above, when the winning probability of the special combination is set to a high probability in the advantageous section, for example, during the advantageous section and during the non-special game (when the accessory is not activated), the ball output rate is set to "1". If it is set to less than ", it is possible to set a lower rate of increase in the number of balls to be played in the advantageous section with respect to the normal section. However, as in the third embodiment, it is of course possible that "advantageous section = AT".

It is also possible to change the winning probability of a special combination in the advantageous section depending on the trigger when the transition is made from the normal section to the advantageous section. For example, in a normal section, it is relatively easy to shift to an advantageous section by winning a special combination (for example, the probability of "1/250" as described above). On the other hand, in the normal section, the probability of winning a rare role (rare cherry, rare replay, etc.) and shifting to an advantageous section without going through a special game is set to, for example, "1/16384" (extremely low probability). do. Then, when the section shifts from the normal section to the advantageous section triggered by the winning of the special combination, the winning probability of the special combination is set to a high probability. On the other hand, when shifting from the normal section to the advantageous section triggered by the winning of the rare role, shift to a special RT and set the winning probability of 1BB to, for example, "1/20" (extremely high probability). Is also possible.
Furthermore, when the normal section shifts to the advantageous section triggered by the winning of the special role, the game after the end of the special game is set to non-AT, and when the normal section shifts to the advantageous section triggered by the winning of the rare role. Can be set to AT from the first game of the advantageous section.

In addition, when shifting from the normal section to the advantageous section and setting the winning probability of the special combination to a high probability, a) the winning probability of the AT is also set to a high probability only during the period in which the winning probability of the special combination is set to a high probability. That, b) the period when the winning probability of the special role is high is set to the normal probability of AT, and c) the winning probability of the special role is set to high probability regardless of the period when AT is set. For example, setting the winning probability of.
Furthermore, when the probability of winning a special combination is set to a high probability after shifting to the advantageous section, an upper limit (limiter) may be set for the number of times the special combination is won in the advantageous section. For example, after shifting to the advantageous section, the winning probability of the special role is set to a high probability, but when the special role is won five times, for example, from the next time onward, the special role is won in the normal section even during the advantageous section. It can be set to the same level as or slightly higher than the probability.
Here, after shifting to the advantageous section, while the winning probability of the special role is high, the winning probability of AT is set to the normal probability, and after the period in which the winning probability of the special role is high is completed, the AT The winning probability of is set to a high probability. Alternatively, conversely, when shifting to the advantageous section, the winning probability of AT is initially set to a high probability, and when the number of winning ATs, the number of games played, and the number of payouts exceeds a predetermined threshold value, AT It is also possible to set the winning probability of the special role to the normal probability and the winning probability of the special role to a high probability.

(14) In the modified example of (13) described above, the winning probability of the special combination is set to a high probability during the advantageous section. However, the present invention is not limited to this, and a combination of a normal section / advantageous section and a winning probability of a special combination (normal probability / high probability) may be provided. for example,
Advantageous section and special role high probability winning section (section 1)
Advantageous section and special role normal probability winning section (section 2)
Normal section and special role high probability winning section (section 3)
Normal section and special role normal probability winning section (section 4) (so-called normal middle)
Can be provided.
Then, for example, in the case where 1 BBA in FIG. 17 of the first embodiment is independently won during the normal section, when the number "20" is won, the section shifts to the advantageous section, but the number "10" If you win, you will not move to the advantageous section. In this case, when the number "20" is won, the game after the end of the special game is set to section 1 or section 2, and when the number "10" is won, the special game ends. It is possible to set the later game in section 3 or section 4.
Furthermore, when the transition to the advantageous section is performed, various settings can be made for the transition condition from the section 1 to the section 2 and the transition condition from the section 2 to the section 1. For example, winning or winning a promotion (fall) role, RT transition, digestion of a predetermined number of games, promotion (or fall) lottery performed every game can be mentioned.

(15) In the flowcharts shown in the 26th and 27th embodiments, the order of processing is not limited to the order shown in the figure, and if the order of processing can be changed, the order of processing is changed. Is also possible.
Further, the 26th and 27th embodiments and the various modifications described above are not limited to being carried out individually, but can be carried out in combination as appropriate.

<28th Embodiment>
In the 28th embodiment, it is possible to confirm whether or not there is a failure in the acquired number display LED 78 (digit 3, digit 4) on which the push order instruction information is displayed, and whether or not there is a failure in the signal line that transmits a signal to the acquired number display LED 78. It was done.

That is, under the situation where the number of medals acquired is displayed, in the interrupt processing when the LED display counter value is "00100000 (B)", the upper digit of the acquired number is displayed in digit 3 and the LED display counter value is "0100000". In the interrupt processing at the time of "(B)", the lower digit of the acquired number is displayed on the digit 4.
Further, under the situation where the push order instruction information is displayed, in the interrupt processing when the LED display counter value is "00100000 (B)", "=", which is a part of the push order instruction information, is displayed on the digit 3. In the interrupt processing when the LED display counter value is "01000000 (B)", any one of "1" to "3", which is another part of the push order instruction information, is displayed on the digit 4.

Further, under the condition that the set value can be changed (during the setting change), in the interrupt processing when the LED display counter value is "00100000 (B)", seven segments A to G of the digit 3 are lit ( "8" is displayed on the digit 3), and in the interrupt processing when the LED display counter value is "01000000 (B)", seven segments A to G of the digit 4 are lit ("8" on the digit 4). To display).
In this way, by lighting the seven segments A to G of the digits 3 and 4 during the setting change, the digits 3 and 4 for which the push order instruction information is displayed in the instruction game section are not broken. , And it can be confirmed that there is no failure in the signal line that transmits the segment signal to the digits 3 and 4.

Further, during the setting change, for example, seven segments A to G of the digit 3 are lit, and of the seven segments of the digit 4, six of the segments A and C to G are lit. When the segment B does not light up, it can be determined that the segment B of the digit 4 may be out of order.
Furthermore, during the setting change, for example, the six segments A to E and G of the digit 3 are lit, but the segment F is not lit, and the six segments A to E and G of the digit 4 are lit. If it lights up but the segment F does not light up, there is a possibility that not only the segment F of the digits 3 and 4 has failed, but also the signal line that transmits the segment signal to the segment F has failed. Then it can be judged.

Hereinafter, the 28th embodiment will be described in more detail.
In the 28th embodiment, the digits 1 to 5 and the circuit configuration for lighting them are the same as those in the 20th embodiment.
Here, although the contents partially overlap with those of the twentieth embodiment, the digits 1 to 5 and the circuit configuration for lighting them will be described.
As shown in FIG. 125 (A), a storage number display LED 76 composed of digits 1 and 2, an acquisition number display LED 78 composed of digits 3 and 4, and a set value display LED 73 composed of digits 5 are provided. I have.
Further, as shown in FIG. 126, the digits 1 to 5 have seven segments A to G.

Furthermore, the main control board 50 is provided with output ports 2 and 3.
Further, as shown in FIG. 128, the output port 2 outputs the digit 1 to 5 signals indicating which digit is to be lit, and the output port 3 is the segment A indicating which segment is to be lit. ~ G signal is output.

Further, as shown in FIG. 129, IC2 and IC3 are provided on the main control board 50.
Furthermore, the IC 2 is an IC related to the control of digit 1 to 5 signals, and has an output port 2 composed of D0 to D7 output terminals.
Further, the IC 3 is an IC related to the control of the segments A to G signals, and has an output port 3 composed of D0 to D7 output terminals.

Further, as shown in FIGS. 129 and 131, the digit 1 signal line exits from the D3 output terminal of the output port 2 of the IC 2 and is connected to the drive signal line of the digit 1.
Similar to the digit 1 signal line, the digit 2 to 5 signal lines also exit from the D4 to D7 output terminals of the output port 2 of the IC 2 and are connected to the drive signal lines of the digits 2 to 5, respectively.

Further, as shown in FIGS. 129 and 131, the segment A signal line exits from the D0 output terminal of the output port 3 of the IC 3 and is connected to the segment A of the digits 1 to 5.
Similar to the segment A signal line, the segment B to G signal lines also exit from the D1 to D6 output terminals of the output port 3 of the IC3 and are connected to the segments B to G of the digits 1 to 5, respectively.
As a result, the segments A to G signals are also used in the digits 1 to 5.

Further, for example, when the digit 3 signal is output from the D5 output terminal of the output port 2, the segments A to G of the digit 3 can be lit. At this time, for example, when the segment B signal is output from the D1 output terminal of the output port 3 and the segment C signal is output from the D2 output terminal of the output port 3, the segments B and C of the digit 3 are lit. As a result, "1" is displayed on the digit 3.

Further, in the interrupt processing, only one of the digits 1 to 5 is set to be lit, and the digit to be lit is sequentially switched for each interrupt processing executed in the 2.235 ms cycle. To go. That is, dynamic lighting is executed.
In particular, in the interrupt processing when the LED display counter value is "00001000 (B)", the digit 1 signal is output from the D3 output terminal of the output port 2 by outputting the signal of "00001000 (B)" from the output port 2. It is output and the digit 1 can be lit.

Similarly, in the interrupt processing when the LED display counter value is "00010000 (B)", the digit 2 can be lit, and in the interrupt processing when the LED display counter value is "0010000 (B)", the digit 3 is lit. It will be possible.
Further, in the interrupt processing when the LED display counter value is "01000000 (B)", the digit 4 can be lit, and in the interrupt processing when the LED display counter value is "10000000 (B)", the digit 5 can be lit. It becomes.

Further, as shown in FIG. 132 (B), the LED display request flag is "01111111 (B)" during normal operation, "1110000 (B)" during setting change, and "111111000 (B)" during setting confirmation. ".
Then, in the LED display control (I_LED_OUT) shown in FIG. 134, the LED display counter and the LED display request flag are ANDed, and the digit corresponding to the calculation result is turned on.

FIG. 222 is a diagram showing addresses, labels, and contents of data stored in the RWM 53.
The data shown in FIG. 222 is for use in the description of the 28th embodiment, and the data stored in the RWM 53 is not limited to these.

The address "F000 (H)" is a set value data storage area (_NB_RANK).
As described in the 25th embodiment, when the set value is "N", the set value data "N-1" is stored in the set value data storage area (_NB_RANK).
In this embodiment, it has set values "1" to "6". Therefore, any value of the set value data "0" to "5" is stored in the set value data storage area (_NB_RANK).
Further, the set value display LED 73 displays "N" as a set value, which is obtained by adding "1" to the set value data "N-1" stored in the set value data storage area (_NB_RANK).

The address "F010 (H)" is a stored number data storage area (_NB_CREDIT), and in the present embodiment, any value of "0" to "50" is stored as the stored number data.
For example, when 50 medals are stored, the stored number data "50" is stored in the stored number data storage area (_NB_CREDIT).

Then, in the interrupt processing when the LED display counter value is "00001000 (B)", the upper digit of the value (stored number) stored in the stored number data storage area (_NB_CREDIT) is digit 1 (stored number display LED76). It is displayed in the upper digit).
Further, in the interrupt processing when the LED display counter value is "00010000 (B)", the lower digit of the value (stored number) stored in the stored number data storage area (_NB_CREDIT) is displayed in digit 2.

The address "F011 (H)" is an acquired number data storage area (_NB_PAYOUT). In the present embodiment, the acquired number of sheets data storage area (_NB_PAYOUT) stores the acquired number of sheets data, the setting changing display data, or the push order instruction number.
At the time of paying out the medals, any value of "0" to "9" is stored as the acquired number data in the acquired number data storage area (_NB_PAYOUT).

Further, during the setting change, "88" is stored in the acquired number data storage area (_NB_PAYOUT) as the setting changing display data.
Furthermore, when the push order is instructed (when the push order of the stop switch 42, which is advantageous to the player, is notified in the designated game section), the acquired number data storage area (_NB_PAYOUT) is set as the push order instruction number. Any value of "A0 (H)", "A1 (H)", "A2 (H)" or "A3 (H)" is stored.

For example, when a 9-card combination wins and 9 medals are paid out, "0" is first stored in the acquired number data storage area (_NB_PAYOUT) as the acquired number data. After that, every time one medal is paid out, "1" is added to the value of the acquired number data storage area (_NB_PAYOUT). That is, the value of the acquired number data storage area (_NB_PAYOUT) is updated according to the payout of medals, such as "0"-> "1"-> "2"-> "3"-> ...-> "9". go. Then, when the ninth medal is paid out, the value of the acquired number data storage area (_NB_PAYOUT) becomes "9".

Then, in the interrupt processing when the LED display counter value is "00100000 (B)", the upper digit of the value stored in the acquired number data storage area (_NB_PAYOUT) becomes digit 3 (the upper digit of the acquired number display LED 78). Is displayed. At this time, if the acquired number data is stored in the acquired number data storage area (_NB_PAYOUT), the upper digit of the acquired number is displayed in digit 3, and if the setting changing display data is stored, the setting is being changed. If the value of "8" indicating that the data is present is displayed on the digit 3 and the push order instruction number is stored, the push order instruction information (indicating that the push order instruction information is used) "=" is displayed on the digit 3. Will be done.

Further, in the interrupt processing when the LED display counter value is "01000000 (B)", the lower digit of the value stored in the acquired number data storage area (_NB_PAYOUT) becomes digit 4 (the lower digit of the acquired number display LED 78). Is displayed. At this time, if the acquired number data is stored in the acquired number data storage area (_NB_PAYOUT), the lower digit of the acquired number is displayed in digit 4, and if the setting changing display data is stored, the setting is being changed. If the value of "8" indicating that the data is present is displayed on the digit 4 and the push order instruction number is stored, the push order instruction information (indicating the push order) "0" to "3" can be any value. It is displayed on the digit 4.

The address “F012 (H)” is an LED display counter value storage area (_CT_LED_DSP), and each time interrupt processing is performed, “00000001 (B)” → “00000010 (B)” → “000000100 (B)” → ...->"10000000(B)"->"0000000000(B)"->"00000001(B)", the value is updated.
The address “F013 (H)” is an LED display request flag storage area (_FL_LED_DSP), and as shown in FIG. 222, a value corresponding to normal, setting change, or setting confirmation is stored.

The address "F014 (H)" is an error number storage area (_NB_ERROR).
When a recoverable error has not occurred, "00 (H)" is stored in the error number storage area (_NB_ERROR).
Then, when a recoverable error occurs, an error number corresponding to the type of recoverable error that has occurred is stored in the error number storage area (_NB_ERROR). In the present embodiment, 10 types of errors shown in FIG. 222 are detected as recoverable errors. The recoverable error is not limited to these.
In addition, the value of the error number storage area (_NB_ERROR) is maintained until the error is cleared, and when the error is cleared (when the error is recovered), the error number storage area (_NB_ERROR) is set to "00 (H)" again. Is memorized.

For example, when an HP error (medal jam error) occurs, "0E (H)" (decimal number "14") is stored as an error number in the error number storage area (_NB_ERROR). In this case, in the interrupt processing when the LED display counter value is "00100000 (B)", the character "H" is displayed in digit 3 (the upper digit of the acquired number display LED 78), and the LED display counter value is "01000000 (01000000). In the interrupt processing at the time of "B)", the character "P" is displayed on the digit 4 (lower digit of the acquired number display LED 78). That is, from the value of "0E (H)" stored in the error number storage area (_NB_ERROR), an offset value for displaying the character "H" in digit 3 and displaying the character "P" in digit 4. Is calculated.

The address "F040 (H)" is a medal payout number data storage area (_NB_PAY_MEDAL), and in the present embodiment, any value of "0" to "9" is stored as the medal payout number data.
In the present embodiment, since the maximum number of medals to be paid out in one game is 9, the medal payout number data is "0" to "9". For example, when a combination of 15 medals is provided, The medal payout number data is "0" to "15".

The address "F041 (H)" is a medal payout number data buffer (_BF_PAY_MEDAL), and in the present embodiment, like the medal payout number data storage area (_NB_PAY_MEDAL) of the address "F040", "0" to "9". Some value of is stored.
When the winning determination is made, the values of both the medal payout number data storage area (_NB_PAY_MEDAL) and the medal payout number data buffer (_BF_PAY_MEDAL) are updated. At this time, the same value is stored in both addresses. For example, when a 9-card combination is won, "9" is stored in both addresses.

After that, the value of the medal payout number data storage area (_NB_PAY_MEDAL) is subtracted by "1" each time one medal is paid out, and becomes "0" at the end of the medal payout. That is, the value of the medal payout number data storage area (_NB_PAY_MEDAL) corresponds to the medal payout, such as "9"->"8"->"7"-> ... "2"->"1"->"0". Will be updated.
On the other hand, the value of the medal payout number data buffer (_BF_PAY_MEDAL) is not updated depending on the medal payout, and is maintained until it is updated at the time of the next game winning judgment.

FIG. 223 is a diagram showing the LED segment table 1 (TBL_SEG_DATA1) and the LED segment table 2 (TBL_SEG_DATA2) in the 28th embodiment, and is a diagram corresponding to the data table in the used area of FIG. 127 in the 20th embodiment. ..
In FIG. 223, the LED segment table 1 (TBL_SEG_DATA1) has "01011110 (B)" as "d" display data, which is different from the data table in the used area of FIG. 127, and other than that, it is in the used area of FIG. 127. It is the same as the data table.

FIG. 224 is a diagram showing the addresses of the data of the LED segment table 1 and the LED segment table 2 stored in the used area of the ROM 54.
The start address of the LED segment table 1 is set to "1811 (H)", and each data of the LED segment table 1 is stored in order from this "1811 (H)".
Further, the start address of the LED segment table 2 is set to "1817 (H)", and each data of the LED segment table 2 is stored in order from this "1817 (H)".
Further, the LED segment table 1 and the LED segment table 2 are stored in consecutive addresses.

As a result, when "1811 (H)" is specified as the start address, each data of the LED segment table 1 and the LED segment table 2 can be represented by an offset value from the start address "1811 (H)".
When "1817 (H)" is specified as the start address, each data in the LED segment table 2 can be represented by an offset value from the start address "1817 (H)".

For example, when an H0 error (abnormality of the payout sensor) occurs, the start address "1811 (H)" of the LED segment table 1 is specified. Further, from the error number "10 (H)" (decimal number "16") of the H0 error, "1" is calculated as the offset value of the upper digit, and "6" is calculated as the offset value of the lower digit.
Then, by reading the data of the start address "1811 (H)" plus the offset value "1" of the upper digit, that is, the data of "1812 (H)", "H" can be displayed in the digit 3. ..
Similarly, by reading the data of the start address "1811 (H)" plus the offset value "6" of the lower digit, that is, the data of "1817 (H)", "0" can be displayed in the digit 4. can.

FIG. 225 is a diagram showing the address of the push order instruction number table stored in the used area of the ROM 54, and corresponds to the one in which the address is entered in FIG. 19 of the first embodiment.
In the push order instruction number table, the start address is set to "1900 (H)", and the push order instruction numbers corresponding to the condition device numbers "0" to "30" are stored in order from this "1900 (H)". ing.

For example, when the small winning combination B1 of the condition device number "11" is won, the condition device number "11" is set as the offset value, and the offset value "11" is set as the start address "1900 (H)" of the push order instruction number table. By reading the added address, that is, the data of "190B (H)", the push order instruction number "A1 (H)" corresponding to the condition device number "11" can be acquired.
The push order instruction number (* 1) when the small winning combination A is won and the pushing order instruction number (* 2) when the small winning combination E1 and E2 are won are the same as those in FIG. 19 of the first embodiment.

Subsequently, information processing by the main control board 50 (main CPU 55) in the 28th embodiment will be described.
When the power switch 11 of the slot machine 10 is turned on, the main control board 50 executes the program start process.
Further, in the program start process, the signal of the door switch 15 is on (the front door is open), the signal of the setting door switch is on (the setting door is open), and the setting key switch 12 When it is determined that the signal of is on (the setting key is inserted and rotated 90 degrees clockwise), the process proceeds to the setting change process (M_RANK_SET) shown in FIG. 226. That is, if the power switch 11 is turned on while the setting key switch 12 is turned on, the setting shifts to the setting changing (setting change mode).

Furthermore, in the program start process, when it is determined that the signal of the door switch 15 is off, the signal of the setting door switch is off, and the signal of the setting key switch 12 is off, the power supply cutoff / recovery data is displayed. Judge whether it is a normal value or not.
Then, when it is determined that the power supply cutoff / recovery data is a normal value, the process proceeds to the power supply recovery processing, the interrupt processing (I_INTR) shown in FIG. 133 is started in this power supply recovery processing, and then the main processing (M_MAIN) shown in FIG. ).
On the other hand, when it is determined that the power-off / recovery data is not a normal value, an "E1" error (power-off / recovery error) occurs, and the process proceeds to the unrecoverable error process 1 (SS_ERROR_STOP1) shown in FIG. 136.

Further, when an "E1" error occurs and the process proceeds to the unrecoverable error processing 1 (SS_ERROR_STOP1), the interrupt processing (I_INTR) shown in FIG. 133 is not executed, and therefore the LED display control (I_LED_OUT) shown in FIG. 134 is not executed either. .. Then, when an "E1" error occurs, "E" is displayed in the digit 3 and "1" is displayed in the digit 4 by the non-recoverable error process 1 (SS_ERROR_STOP1) shown in FIG. 136. Specifically, the process of displaying "E" on the digit 3 and the process of displaying "1" on the digit 4 are alternately and repeatedly executed at predetermined time intervals.
Further, when an unrecoverable error occurs, the power switch 11 is temporarily turned off. Then, the setting key switch 12 is turned on by inserting the setting key and rotating it 90 degrees clockwise, and in this state, the power switch 11 is turned on again. As a result, in the setting change process (M_RANK_SET) described later, the predetermined range of RWM53 is cleared and the "E1" error is cleared.

FIG. 226 is a flowchart showing the setting change process (M_RANK_SET).
First, in step S2121, a "predetermined range" is stored in a register as an initialization range within the used area of the RWM53 ("F000 (H)" to "F1FF (H)" in FIG. 124). Here, the "predetermined range" is an initialization range when it is determined that the power off processing has been executed normally, and at least the setting value data (address "F000 (H)") is not initialized. The range is defined as the "predetermined range".
In addition to the set value data, the initialization range in which the game state (for example, RT state) and all or part of the winning flags are not initialized may be set as the “predetermined range”.

Next, the process proceeds to step S2122, and the main control board 50 determines whether or not the power supply cutoff / recovery data is a normal value. When it is determined that the power-off / recovery data is a normal value, the process proceeds to step S2124, and the storage of the “predetermined range” in step S2121 is maintained. On the other hand, when it is determined in step S2122 that the power off / returning data is not a normal value, the process proceeds to step S2123.
In step S2123, the main control board 50 stores a “specific range” in a register as an initialization range within the used area of the RWM 53. Here, the "specific range" is an initialization range when it is determined that the power off is not normal, and the entire range in the used area including the set value data (address "F000 (H)") is set as the initialization range. Set.

Then, the process proceeds to step S2124, and initialization of the predetermined range set in step S2121 or the specific range set in step S2123 (within the used area of RWM53) is started. In the next step S2125, it is determined whether or not the initialization started in step S2124 is completed. When it is determined that the initialization is completed, the process proceeds to step S2126.

In step S2126, the AF register (A register and F register (flag register)) is saved. It should be noted that the AF register is originally saved here because the F (flag) register is to be saved, but the AF register is saved for the convenience of the instruction. Then, the process proceeds to step S2127, and a predetermined range is stored as the initialization range outside the used area of the RWM53 (after “F200 (H)” in FIG. 124). Here, the "predetermined range" is an initialization range when it is determined that the power off processing has been executed normally, for example, after the address "F28E (H)" or after "F293 (H)" (initialization). The range depends on the specifications, etc.).

In the next step S2128, similarly to step S2122, it is determined whether or not the power supply cutoff / recovery data is a normal value. When it is determined that the power-off / recovery data is a normal value, the process proceeds to step S2130, and the storage of the “predetermined range” in step S2127 is maintained. On the other hand, when it is determined in step S2128 that the power off / returning data is not a normal value, the process proceeds to step S2129.

In step S2129, the main control board 50 stores a "specific range" in the register as an initialization range outside the used area of the RWM 53. Here, the "specific range" is an initialization range when it is determined that the power off is not normal, and the entire range outside the used area after the address "F200" is set as the initialization range. Therefore, in this case, the ring buffer and the like are also initialized.
Then, the process proceeds to step S2130, and initialization of the predetermined range set in step S2127 or the specific range set in step S2129 (outside the used area of RWM53) is started.

In the next step S2131, it is determined whether or not the initialization started in step S2130 is completed. When it is determined that the initialization is completed, the process proceeds to step S2132.
In step S2132, the AF register saved in step S2126 is restored. In the next step S2133, the start setting of interrupt processing is performed. Since the timer interrupt process is used as the interrupt process in the present embodiment, the process of setting the timer interrupt cycle (“2.235 ms” in the present embodiment) corresponds to the process. Then, interrupt processing is executed after the processing of step S2133. In other words, it is configured so that interrupt processing is not executed before "interrupt activation".

In the next step S2134, the output request set at the start of setting change is performed. This process is a process of setting (storing) a control command to be transmitted to the sub control board 80 in a register in order to notify the sub control board 80 side that the setting change process is to be started.
The "output request set" is also executed in the process described below, but as in step S2134, the process of setting the control command to be transmitted to the sub-control board 80 in the register is performed. means. Further, the control command here does not mean only the command to be actually transmitted, but also means the command that is the source of the command to be actually transmitted.
Next, the process proceeds to step S2135, and the main control board 50 executes the control command set 1. This process is a process of storing the control command (control command set in the register) to be transmitted to the sub control board 80 in the control command buffer (RWM53).

Next, the process proceeds to step S2136, and the main control board 50 stores the standby time in a BC register (a pair register composed of a B register and a C register, each of which can store 8-bit data (1 byte data)). In the present embodiment, the interrupt processing number "224" (about 500 ms) is set as the standby time at the start of setting change. Next, the process proceeds to step S2137, and the 2-byte time waiting process (wait process) for starting the setting change is executed. In the present embodiment, the process waits until the number of interrupt processing "224" is counted ("1" is subtracted each time interrupt processing is performed, and the set number of interrupt processing becomes "0"). During this waiting time (during 2-byte time waiting processing), the setting change processing does not proceed, but the interrupt processing is executed.

As described above, the reason why the 2-byte time waiting process (wait process) is executed in step S2137 on the main control board 50 side is that the initialization process of the RWM 83 on the sub control board 80 side takes time. In particular, on the main control board 50 side, it is not possible to know whether or not the initialization process has been completed on the sub control board 80 side.

Therefore, when the initialization process is still in progress on the sub control board 80 side, the process proceeds on the main control board 50 side, and the progress of the control process of the main control board 50 and the progress of the control process of the sub control board 80 It is possible to prevent the synchronization from being lost.
That is, since the sub-control board 80 starts the initialization of the RWM83 after the execution of the output request set and the control command set 1 at the start of the setting change, a sufficient time is set as the wait time for the initialization of the RWM83 to be completed. There is a need to. As a result, after the initialization process of the RWM 83 is completed on the sub control board 80 side, the process can proceed to the steps S4001 and subsequent steps on the main control board 50 side.

Note that the control command at the start of the setting change set in steps S2134 and S2135 can execute interrupt processing even during the 2-byte time wait processing in step S2137, and therefore is subordinated during at least the 2-byte time wait processing. It is transmitted to the control board 80. However, while the 2-byte time wait process is being executed in step S2137, the process does not proceed to the process after step S4001 (the setting change process does not proceed).

After the completion of the 2-byte time waiting process in step S2137, the process proceeds to step S4001, and "88" (binary number "01011000 (B)") indicating that the setting is being changed is set in the acquired number data storage area (_NB_PAYOUT). Remember.
Next, the process proceeds to step S4002, and "11100000 (B)" corresponding to the setting being changed is stored in the LED display request flag storage area (_FL_LED_DSP).

By the process of step S4002, when the interrupt process is executed after the process, the digits 3 to 5 (acquired number display LED78 and set value display LED73) can be turned on.
Specifically, in the interrupt process executed after the process of step S4002, "8" can be displayed in the digits 3 and 4, respectively ("88" is displayed in the acquired number display LED 78), and the digit 5 (set value display) can be displayed. The current set value can be displayed on the LED73).
Since the acquired number data storage area (_NB_PAYOUT) and the LED display request flag storage area (_FL_LED_DSP) are initialized by the initialization process in the used area of the RWM53 in step S2124, the values before step S4001 are ". It is "0".

Next, the process proceeds to step S2139, and interrupt waiting processing is executed. This process is a process of waiting until the interrupt process is executed (2.235 ms elapses). The reason for providing this process will be described later. Then, the process proceeds to step S2140.
In step S2140, it is determined whether or not the operation of the setting switch 13 is detected. Here, it is determined whether or not the setting switch 13 is turned on by determining the rising data of the input port including the setting switch 13. Then, when it is determined that the operation of the setting switch 13 has been detected, the process proceeds to step S2141, and when it is determined that the operation has not been detected, the process proceeds to step S2142.

In step S2141, the set value (set value data) is updated. Specifically, the value of the set value data storage area (_NB_RANK) is updated. Further, when the interrupt process is executed after the set value is updated, the set value display LED 73 displays the updated set value.
As described above, when the set value is "N", the set value data "N-1" is stored in the set value data storage area (_NB_RANK).
Therefore, when the set value data "N-1" is stored in the set value data storage area (_NB_RANK), "N" obtained by adding "1" to the set value data "N-1" is set as the set value. It is displayed on the digit 5 (set value display LED 73).

In the next step S2142, it is determined whether or not the operation of the start switch 41 is detected. In the present 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 S2143, and when it is determined that the start switch 41 has not been operated, the process returns to step S2139.

In the above processing, step S2139 (interrupt waiting processing) is provided to clear the rising data of the setting switch 13.
For example, if the process of step S2139 is not provided, if it is determined in step S2140 that the rising data of the setting switch 13 is on, the setting value is updated in step S2141, and the start switch 41 is not turned on in the next step S2142. If it is determined, the process proceeds to step S2140, and it is determined whether or not the rising data of the setting switch 13 is on.

If the interrupt processing is executed even once after it is determined to be ON in step S2140, the rising data of the setting switch 13 is turned off. However, until the interrupt processing is executed, it continues to be determined in step S2140 that the rising data of the setting switch 13 is on. As a result, the set value continues to rise by 2 or more just by operating the setting switch 13 once. Therefore, in step S2139, interrupt waiting processing is executed.

In step S2143, it is determined whether or not the setting key switch 12 has been turned off. When it is determined that the setting key switch 12 has been turned off, the process proceeds to step S4003, and the acquired number data storage area (_NB_PAYOUT) is cleared (the value is set to "0").
Next, the process proceeds to step S4004, and "01111111 (B)" corresponding to the normal state is stored in the LED display request flag storage area (_FL_LED_DSP).

Due to the interrupt processing executed after the processing of step S4003, the display of the digits 3 and 4 (acquired number display LED78) is changed from "88" to "00".
Further, by the interrupt processing executed after the processing of step S4004, "0" is displayed in the digits 1 and 2, respectively ("00" is displayed in the storage number display LED 76). As a result, the display of digits 1 to 4 (stored number display LED76 and acquired number display LED78) becomes "0000". Further, the digit 5 (set value display LED 73) is turned off.
The digits 1 to 4 (stored number display LED76 and acquired number display LED78) may be turned off.

Next, the process proceeds to step S2145, and the output request set at the end of the setting change is performed in the same manner as in step S2134. This process is a process of terminating the setting change process and setting a control command for notifying the sub-control board 80 side of the determined set value.
Next, the process proceeds to step S2146, and the main control board 50 executes the control command set 1 in the same manner as in step S2135. Then, the process proceeds to step S2147, and the process proceeds to the main process (M_MAIN).

FIG. 227 is a flowchart showing the main process (M_MAIN) process.
In step S2171, the stack pointer is set. The stack pointer refers to an area of RWM53 that stores data at the time of power failure (for example, register value, instruction processing of main processing before interrupt processing, etc.) when a power failure occurs, and is a set of stack pointers. Is a process of setting the register value to the initial value in the area of the RWM53.

In the next step S2172, the game start set process is performed. This process is a process of generating, updating, saving, and the like of the operating state flag.
In the next step S4011, the acquired number data storage area (_NB_PAYOUT) is cleared (the value is set to "0"). For example, it is assumed that the number of medals paid out in the previous game (the number of medals acquired by the player) is displayed on the acquired number display LED 78 (digits 3 and 4). In this case, the display of the acquired number display LED 78 becomes "00" by the interrupt process executed after the process of step S4011.

In the next step S2173, the bet medal is read. This process is a process of reading how many medals are bet at the present time.
In the next step S2174, the presence or absence of a bet medal is determined based on the number of bets read in step S2173.
If it is determined in step S2174 that there is a bet medal, the process proceeds to step S2176, and if it is determined that there is no bet medal, the process proceeds to step S2175 to perform the medal insertion waiting process, and then the process proceeds to step S2176. The medal insertion waiting process in step S2175 determines whether or not the setting key switch 12 is on, and if it is on, performs processing such as shifting to setting confirmation (setting confirmation mode).

In step S2176, the inserted medals are managed. This process is a process of determining whether or not the medal has been maintained, determining whether or not the settlement switch 46 has been operated, and the like.
In the next step S2177, the soft random number is updated. This process is a process of updating (for example, adding "1" at a time) a processing random number (soft random number) for processing (calculation processing) into a built-in random number (hard 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. As an update method, a process of adding an interrupt count value (a count value (variable) that is incremented during interrupt processing) to the value before the update may be executed.

In the next step S2178, the main control board 50 determines whether or not the start switch 41 has been operated. When it is determined that the start switch 41 has been operated, the process proceeds to step S2179, and when it is determined that the start switch 41 has not been operated, the process returns to step S2173. Even when the start switch 41 is operated, if the number of bets does not reach the specified number of the game, it is determined as "No" in step S2178.

In step S2179, the process at the time of accepting the start switch is executed. This process is a process of setting a setting non-changeable flag, setting an output request at the start of reel rotation, setting the number of outputs of a medal insertion signal, and the like.
In step S2180, the winning combination lottery means 61 executes the winning combination lottery at the timing when the start switch 41 is operated, that is, when the operation signal of the start switch 41 is received. The random number value (random number value of the hard random number) at the time of the winning combination lottery is acquired in step S2179. Then, in step S2180, the random number value of the processing random number is added to the acquired random number value, and the combination lottery table is used to determine whether or not the random number value after the addition is a random number value corresponding to any of the winning combinations. Judgment is performed.

In the next step S4012, the push order instruction number set process (M_ORD_INF) is executed.
In this process, when a game has an advantageous push order (for example, a game when the small winning combination B group is won) in the designated game section, the push order instruction number is stored in the acquired number data storage area (_NB_PAYOUT) of the RWM53. It is a process of equalization.
Proceeding to step S4012, the process proceeds to the process of FIG. 228, which will be described later. Although the details will be described later, in a game having an advantageous push order, push order instruction information (for example, "= 1") is displayed on the acquisition number display LED 78 (digits 3 and 4) by the interrupt process executed after this process. Will be done.

In the next step S2181, the reel rotation start preparation process is executed. This process is a process of determining whether or not the minimum game time (4.1 seconds) has elapsed.
Next, the process proceeds to step S2182, and the reel control means 65 starts the rotation of the reel 31. In the next step S2183, the 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 stop position of the reel 31 is determined based on the lottery result of the winning combination and the position of the reel 31. The reel 31 is controlled to be stopped at the determined position.

In the next step S2184, the reel control means 65 checks whether or not all the reels 31 have stopped, and proceeds to step S2185.
In step S2185, 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 S4013, and if it is determined that all reels 31 have not stopped, the process returns to step S2183. ..

In step S4013, the acquired number data storage area (_NB_PAYOUT) is cleared (the value is set to "0"). For example, it is assumed that the game has an advantageous push order in the designated game section, and the push order instruction information (for example, "= 1") is displayed on the acquired number display LEDs 78 (digits 3 and 4). In this case, the display of the acquired number display LED 78 becomes "00" by the interrupt process executed after the process of step S4013.
The acquired number display LED 78 may be turned off. Specifically, "00011111 (B)" may be stored in the LED display request flag storage area (_FL_LED_DSP), or "off" display data (0000000000B) is provided instead of the "0" display data. May be good.

In step S2186, a symbol display determination (winning determination) is performed. Here, the winning determination means 66 determines whether or not the combination of symbols corresponding to the winning combination has stopped on the effective line.
In the next step S2187, it is determined whether or not a symbol display error has occurred, and if it is determined that a display error has occurred, the process proceeds to unrecoverable error processing 1 (SS_ERROR_STOP1), and if no display error has occurred. When the determination is made, the process proceeds to step S4014.
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 defined in the stop position determination table. However, as a result of the symbol display determination, when a symbol (kicking symbol) that should not be originally displayed is displayed on the effective line, it is determined to be abnormal (“E5” error), and the return shown in FIG. 136 is performed. Impossible error processing 1 (SS_ERROR_STOP1) is executed.

When it is determined in step S2187 that no display error has occurred and the process proceeds to step S4014, the medal payout number update process is executed. Details of this process will be described later with reference to FIG. 229.
In the next step S4015, the payout means 67 executes the medal payout process by winning. This process is a process of paying out medals corresponding to a winning combination (small combination), and when the number of stored medals is less than "50", the number of stored medals is added until the number of stored medals reaches "50". When the number of stored medals reaches "50" or more, the hopper motor 36 is driven to control the hopper 35 to pay out medals to the player. Details of this process will be described later with reference to FIG. 230.

Next, the process proceeds to step S2190, and interrupt waiting processing is performed. This process is the same as step S2139 of FIG. 226.
In the next step S2191, interrupt processing is disabled. By the processing of these steps S2190 and S2191, the interrupt processing is prohibited immediately after the interrupt processing.
In the next step S2192, the AF register is saved. This process is the same as step S2126 of FIG. 226.

Next, the process proceeds to step S2193 to execute the ratio setting process. This ratio set process is a process executed outside the used area.
The ratio set processing is performed on the management information display LED74 (digits 6 to 9), the advantageous section ratio, the continuous bonus ratio (6000 times), the bonus ratio (6000 times), the continuous bonus ratio (cumulative), and the bonus ratio. In order to display (cumulative), it is a process of executing various counter value update processes, ratio calculation processes, and the like.

Then, when the process proceeds to step S2194, the AF register saved in step S2192 is restored, and interrupts are permitted (restarted) in the next step S2195. In this way, when the ratio set processing is executed, the AF register is saved and the interrupt processing is prohibited before the execution. Note that interrupt processing is prohibited during execution of ratio set processing because if interrupt processing is performed when a program outside the used area is executed in the main processing, programs inside the used area and programs outside the used area are mixed. This is because the processing becomes complicated.

Next, the process proceeds to step S2196, and the game end check process is performed. This process clears the conditional device flags (winning combination flag, winning flag) and the like. Then, the process proceeds to step S2197, and the output request set at the end of the game and the control command set 1 are performed in the next step S2198. These processes are the same as those in steps S2134 and S2135 of FIG. 226, and are processes for setting control command data for transmitting to the sub-control board 80 that one game has been completed.
Then, when the process of step S2198 is completed, the process returns to the main process (step S2147) again.

FIG. 228 is a flowchart showing the push order instruction number set process (M_ORD_INF) in step S4012 of FIG. 227.
In step S4021, it is determined whether or not the game section (AT) is indicated.
Here, when it is determined that the game section is the designated game section, the process proceeds to the next step S4022.
On the other hand, when it is determined that the game section is not the designated game section, the process according to this flowchart is terminated. In this case, since the acquired number data storage area (_NB_PAYOUT) is cleared in step S4011 of FIG. 227 and step S4026 is skipped, the value of the acquired number data storage area (_NB_PAYOUT) remains “0”. Therefore, the display of the acquired number display LED 78 (digits 3 and 4) remains “00”.

In step S4022, the condition device number is set. The condition device number determined by the winning combination lottery process in step S2180 of FIG. 227 is stored in the winning and replay condition device number storage area (_NB_CND_NOR) and the accessory condition device number storage area (_NB_CND_BNS) of the RWM 53. Then, in step S4022, the value of the winning and replay condition device number storage area (_NB_CND_NOR) is stored in the A register.
Next, the process proceeds to step S4023, and the push order instruction number table is set. In step S4023, the start address "1900 (H)" of the push order instruction number table shown in FIG. 225 is stored in the HL register. As a result, the HL register value becomes "1900 (H)". Then, the process proceeds to the next step S4024.

Proceeding to step S4024, the designated address data is set. In step S4024, the 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 and replay condition device number (_NB_CND_NOR) 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.

For example, when the small winning combination B1 is won in the winning combination lottery process of step S2180 in FIG. 227, the condition device number “11” of the small winning combination B1 is stored in the winning and replay condition device number storage area (_NB_CND_NOR). Therefore, after the processing of step S4022, the A register value becomes "11".
Further, the A register value "11" is added to the HL register value "1900 (H)" after the processing in step S4023 to obtain a new HL register value "190B (H)". In this way, the address of the storage area of the push order instruction number of the small winning combination B1 can be calculated.
Then, the push order instruction number "A1 (H)" corresponding to the address "190B (H)" of the push order instruction number table is stored in the A register. As a result, the A register value after the processing in step S4024 becomes "A1 (H)".

Next, the process proceeds to step S4025, and the push order instruction number is stored in the RWM53. That is, the A register value is stored in the storage area of the push order instruction number in the RWM53.
In this way, by performing arithmetic processing using the data stored in the winning and replay condition device number storage area (_NB_CND_NOR) as an offset value, the push order instruction number corresponding to the condition device number is calculated and stored in the RWM53. be able to.

In the next step S4026, the A register value (pushing order instruction number) is stored in the acquired number data storage area (_NB_PAYOUT). Then, the process according to this flowchart is completed.
When the push order instruction number is stored in the acquired number data storage area (_NB_PAYOUT) in step S4026 of FIG. 228, the push order instruction is given to the acquired number display LEDs 78 (digits 3 and 4) by the interrupt process executed after this process. Information is displayed.
For example, it is assumed that "A2 (H)" is stored as a push order instruction number in the acquired number data storage area (_NB_PAYOUT). In this case, by the LED display control (I_LED_OUT) in FIG. 134, "10" is calculated as the offset value of the upper digit and "2" is calculated as the offset value of the lower digit from the push order instruction number "A2 (H)". do.

Then, by reading the data of "1821 (H)", which is the address obtained by adding the offset value "10" of the upper digit to the start address "1817 (H)" of the LED segment table 2, "=" is added to the digit 3. indicate.
Similarly, by reading the data of the start address "1817 (H)" of the LED segment table 2 plus the offset value "2" of the lower digit, that is, the data of "1819 (H)", the digit 4 is "2". Is displayed.
In this way, the push order instruction information "= 2" is displayed on the acquired number display LED 78.

FIG. 229 is a flowchart showing the medal payout number update process in step S4014 of FIG. 227.
First, in step S4031, the medal payout number data is acquired. Since the winning combination (combination of symbols) can be specified based on the display determination (winning determination) in step S2186 of FIG. 227, the number of medals to be paid out corresponding to the combination of symbols is read from a data table or the like.

In the next step S4032, the medal payout number data acquired in step S4031 is stored (stored) in the medal payout number data storage area (_NB_PAY_MEDAL) of the RWM53.
Since the value of the medal payout number data storage area (_NB_PAY_MEDAL) is "0" at the time of processing in step S4031, a process of newly writing data is executed. For example, when a single winning combination is won, the data value is updated from "0" to "1".
It is optional whether or not the process of step S4031 is performed when the winning combination having the medal payout is not won. For example, a method of skipping step S4031 and a method of executing the process of step S4031 and writing the data value "0" can be mentioned.

In the next step S4033, the medal payout number data acquired in step S4031 is stored (stored) in the medal payout number data buffer (_BF_PAY_MEDAL) of the RWM53.
Since the value written in the previous game remains in the medal payout number data buffer (_BF_PAY_MEDAL), the process of writing (overwriting) the medal payout number data (“0” if there is no medal payout) in the game. To execute.
Then, the process according to this flowchart is completed.

In the above-mentioned medal payout number update process of FIG. 229, the value of the medal payout number data storage area (_NB_PAY_MEDAL) stored in step S4032 is subsequently subtracted by "1" for each medal payout, and the medal payout is performed. At the end, it becomes "0".
On the other hand, the value of the medal payout number data buffer (_BF_PAY_MEDAL) stored in step S4033 is maintained (cannot be changed) until the next game is updated, that is, until the process of step S4033 is performed in the next game. No).

FIG. 230 is a flowchart showing a medal payout process (MS_WIN_PAY) by winning a prize in step S4015 of FIG. 227.
First, in step S4041, the medal payout number data is acquired. This process is a process of storing the value of the medal payout number data storage area (_NB_PAY_MEDAL) of the RWM53 in the A register. As a result, the medal payout number data is stored in the A register.

Next, the process proceeds to step S4042, and it is determined whether or not the medal is paid out. Specifically, it is determined whether or not the value (A register value) of the medal payout number data storage area (_NB_PAY_MEDAL) is "0". Then, when it is determined that the value is "0", that is, when it is determined that the medal is not paid out, the process according to this flowchart is terminated. On the other hand, when it is determined that the value is not "0", that is, when it is determined that the medal is paid out, the process proceeds to step S4043.

In step S4043, the number of stored sheets is read. Specifically, the value of the stored number data storage area (_NB_CREDIT) of the RWM53 is acquired.
Next, the process proceeds to step S4044, and it is determined whether or not the number of medals stored has reached the limit value. Specifically, when the stored number data acquired in step S4043 is "50", it is determined that the stored number has reached the limit value, the process proceeds to step S4083, and the acquired stored number data is less than "50". At a certain time, it is determined that the number of stored sheets has not reached the limit value, and the process proceeds to step S4045.

In step S4045, the waiting time at the time of adding the stored medals is set. In the present embodiment, in order to set the wait time to be about 100 ms, the interrupt processing number “46” (46 × 2.235 ms = about 100 ms) is set. Therefore, "00000000000 (B)" is set as the B register value, and "00101110 (B)" is set as the C register value.
Next, the process proceeds to step S4046, and the 2-byte time wait 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 S4046 is completed, the process proceeds to step S4047 to execute the one-sheet addition process for the number of stored sheets. Specifically, "1" is added to the value of the stored number data storage area (_NB_CREDIT) of the RWM53. Then, the display of digits 1 and 2 (stored number display LED76) is "+1" by the interrupt processing executed after the processing of step S4047. For example, the display of the storage number display LED 76 changes from "08" to "09".
When the process of step S4047 is completed, the process proceeds to step S4049.

When the process proceeds from step S4044 to step S4048, one medal payout process (process of paying out the actual medal from the hopper 35 to the player) is executed. By the above processing, the number of stored medals is added until the number of stored medals reaches the limit value, and when the number of stored medals is the limit, the process of paying out the actual medals from the hopper 35 is executed.

In step S4049, "1" is added to the value of the acquired number data storage area (_NB_PAYOUT) of the RWM53. By the interrupt processing executed after the processing of step S4049, the display of digits 3 and 4 (acquired number display LED78) is "+1". For example, the display of the acquired number display LED 78 changes from "02" to "03".

In the next step S4050, "1" is subtracted from the value of the medal payout number data storage area (_NB_PAY_MEDAL) of the RWM53.
In step S4050, only the value of the medal payout number data storage area (_NB_PAY_MEDAL) is updated, and the value of the medal payout number data buffer (_BF_PAY_MEDAL) is not updated.

Next, the process proceeds to step S4051, and it is determined whether or not the medal payout is completed. This process is a process of determining whether or not the value of the updated medal payout number data storage area (_NB_PAY_MEDAL) has become "0". When it is determined that the value of the medal payout number data storage area (_NB_PAY_MEDAL) is "0", the process according to this flowchart is terminated, and when it is determined that the value of the medal payout number data storage area (_NB_PAY_MEDAL) is not "0". Returns to step S4043.

In the above payout process, when the payout is performed by adding one stored sheet, the waiting time of about 100 ms is set by the processes of steps S4045 and S4046. As a result, it is possible to show the player that the display of the stored number display LED 76 counts up. For example, when the display of the storage number display LED76 before the storage addition is "08" and eight medals are stored and added to this, "display" 08 "-> 100 ms weight processing->display" 09 "-> 100 ms. Wait processing → ... → 100ms weight processing → display “16”. On the other hand, if the waiting time is not provided when adding one of the stored sheets, it looks as if the display "08" is changed to the display "16" instantly.
Then, as in the present embodiment, when the number of stored sheets is added, the payout sound output from the sub-control board 80 side is executed by executing the waiting process for 2 bytes for each addition of the sheets (“Purululu ...”). ) And the count-up of the number of stored sheets can be synchronized.

On the other hand, when the number of stored sheets exceeds the maximum number "50" and the medal is actually paid out in the process of step S4048, the 2-byte time waiting process of steps S4046 and S4047 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. As a result, the payout time per medal is about 100 ms. Therefore, when the actual medal is paid out, the 2-byte time waiting process is not provided. Therefore, when actually paying out medals, 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. 231 (1) is a diagram showing a state in which “88” is displayed on the acquired number display LED 78 (7 of the segments A to G of the digits 3 and 4 are lit) during the setting change. be.
As described above, in step S4001 of the setting change process (M_RANK_SET) of FIG. 226, "88 (D)" (binary number "88 (D)" indicating that the setting is being changed in the acquired number data storage area (_NB_PAYOUT) of the RWM53. 01011000 (B) ”) is stored, and in the next step S4002, the corresponding“ 1110000 (B) ”is stored in the LED display request flag storage area (_FL_LED_DSP) of the RWM53 during the setting change. Then, "88" is displayed on the acquired number display LED 78 by the interrupt processing executed after this processing.

Here, when "88 (D)" is stored in the acquired number data storage area (_NB_PAYOUT), in step S1447 of the LED display control (I_LED_OUT) of FIG. 134, the acquired number data storage area (_NB_PAYOUT) is changed to "88 (D)". D) ”is acquired and stored in the A register.
Further, in step S1450 of FIG. 134, an operation of dividing the A register value "88 (D)" by "10 (D)" is executed, and the quotient "8 (D)" is set in the A register as an offset value for the upper digit. It is stored, and the remainder "8 (D)" is stored in the C register as an offset value for lower digits.

Further, in the interrupt processing when the LED display counter value is "00100000 (B)", in step S1455 of FIG. 134, the offset value "8 (D)" for the upper digit is added to the start address of the LED segment table 2 of FIG. 224. By adding, "8" display data (address "181F (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, "8" is displayed on the digit 3 (upper digit of the acquired number display LED 78).

In the interrupt processing when the LED display counter value is "01000000 (B)", the LED of FIG. 224 is performed in step S1455 of FIG. 134, as in the interrupt processing when the LED display counter value is "00100000 (B)". By adding the lower digit offset value "8 (D)" to the start address of the segment table 2, the "8" display data is acquired as the segment output data. Then, in step S1458, “8” is displayed on the digit 4 (lower digit of the acquired number display LED 78).

In this way, "88" is displayed on the acquired number display LED 78 while the setting is being changed.
Further, the display of "88" continues until the acquired number data storage area (_NB_PAYOUT) is cleared in step S4003 of the setting change process of FIG. 226. Then, when the acquired number data storage area (_NB_PAYOUT) is cleared, the display of the acquired number display LED 78 (digits 3 and 4) changes from "88" to "00" by the interrupt process executed after this process.

FIG. 231 (2) is a diagram showing a state in which “= 1” is displayed on the acquired number display LEDs 78 (digits 3 and 4) as push order instruction information in the instruction game section.
As described above, when proceeding to the push order instruction number set process (M_ORD_INF) of step S4012 in the main process (M_MAIN) of FIG. 227, when the game has an advantageous push order in the instruction game section, the RWM53 The push order instruction number is stored in the acquired number data storage area (_NB_PAYOUT).
Then, when the push order instruction number is stored in the acquired number data storage area (_NB_PAYOUT), the push order instruction information is displayed on the acquired number display LEDs 78 (digits 3 and 4) by the interrupt process executed after this process. NS.

For example, it is assumed that the push order instruction number "A3 (H)" is stored in the acquired number data storage area (_NB_PAYOUT). In this case, in step S1447 of the LED display control (I_LED_OUT) of FIG. 134, "A3 (H)" is acquired from the acquired number data storage area (_NB_PAYOUT) and stored in the A register.
Further, in step S1450 of FIG. 134, an operation of dividing the A register value "A3 (H)" by "10 (D)" is executed, and the offset value for the upper digit is "A (H)"("10 (D)). ") Is acquired and stored in the A register, and" 3 (H) "(" 3 (D) ") is acquired as the offset value for the lower digit and stored in the C register.

Further, in the interrupt processing when the LED display counter value is "00100000 (B)", in step S1455 of FIG. 134, the offset value "10 (D)" for the upper digit is added to the start address of the LED segment table 2 of FIG. 224. By adding, "=" display data (address "1821 (H)" in FIG. 224)) is acquired as segment output data. Then, in step S1458, "=", which is a part of the push order instruction information, is displayed on the digit 3 (upper digit of the acquired number display LED 78).

Further, in the interrupt processing when the LED display counter value is "01000000 (B)", in step S1455 of FIG. 134, the offset value "3 (D)" for lower digits is added to the start address of the LED segment table 2 of FIG. 224. By adding, the "3" display data (address "181A (H)" in FIG. 224) is acquired as the segment output data. Then, in step S1458, "3", which is another part of the push order instruction information, is displayed on the digit 4 (lower digit of the acquired number display LED 78).

In this way, when the game has an advantageous push order in the designated game section, the push order instruction information "= 3" is displayed on the acquired number display LED 78.
Further, the display of the push order instruction information "= 3" continues until the acquired number data storage area (_NB_PAYOUT) is cleared in step S4013 of the main process of FIG. 227. Then, when the acquired number data storage area (_NB_PAYOUT) is cleared, the display of the acquired number display LED 78 (digits 3 and 4) changes from "= 3" to "00" by the interrupt process executed after this process. ..

FIG. 231 (3) shows a state in which a “dE” error (opening of the front door), which is one of the recoverable errors, is detected and “dE” is displayed on the acquired number display LEDs 78 (digits 3 and 4). It is a figure which shows.
When the front door is opened, the door switch 15 is turned on. At this time, when it is detected that the door switch 15 is turned on in the input port reading process of step S1407 in the interrupt process of FIG. 133, "dE" is set as an error number in the error number storage area (_NB_ERROR) of the RWM53. "35 (H)" corresponding to the error is stored (FIG. 222).

Then, when "35 (H)" is stored in the error number storage area (_NB_ERROR), the interrupt processing executed after this processing causes the acquisition number display LEDs 78 (digits 3 and 4) to indicate a dE error. "dE" is displayed.
Here, when "35 (H)" is stored in the error number storage area (_NB_ERROR), in step S1439 of the LED display control in FIG. 134, the error number "35 (H)" is stored from the error number storage area (_NB_ERROR). Is acquired and stored in the B register.

Further, in step S1448 of FIG. 134, it is determined that an error is displayed (“Yes”) because the B register value is not “0”, and in the next step S1449, the B register value is set in the A register and the LED. The start address of the segment table 1 is set in the HL register.
Further, in step S1450 of FIG. 134, an operation of dividing the A register value “35 (H)” (“53 (D)”) by “10 (D)” is executed, and the quotient “5 (D)” is ranked higher. The digit offset value is stored in the A register, and the remainder "3 (D)" is stored in the C register as the lower digit offset value.

Then, in the interrupt processing when the LED display counter value is "00100000 (B)", in step S1455 of FIG. 134, the offset value "5 (D)" for the upper digit is added to the start address of the LED segment table 1 of FIG. 224. By adding, the "d" display data (address "1816 (H)" in FIG. 224) is acquired as the segment output data. Then, in step S1458, "d" is displayed on the digit 3 (upper digit of the acquired number display LED 78).

Further, in the interrupt processing when the LED display counter value is "01000000 (B)", in step S1455 of FIG. 134, the offset value "3 (D)" for lower digits is added to the start address of the LED segment table 1 of FIG. 224. By adding, the "E" display data (address "1814 (H)" in FIG. 224) is acquired as the segment output data. Then, in step S1458, "E" is displayed on the digit 4 (lower digit of the acquired number display LED 78).

In this way, when a "dE" error occurs, "dE" is displayed on the acquired number display LED 78. Further, the display of "dE" is not resolved only by closing the front door and turning off the door switch 15, and continues until the error is cleared.
When the door key is inserted into the keyhole of the front door and rotated 90 degrees counterclockwise, the reset switch 14 is turned on. At this time, when it is detected that the reset switch 14 is turned on by the input port reading process in step S1407 in the interrupt process of FIG. 133, the error number storage area (_NB_ERROR) of the RWM 53 indicates that there is no error data. 00 (H) ”is stored (FIG. 222).

This clears the error. Then, the display of the acquired number display LED 78 (digits 3 and 4) returns from "dE" to the original display (for example, the acquired number "09") by the interrupt process executed after this process.
In this way, when a recoverable error occurs, it is possible to recover from the error by removing the cause of the error and operating the reset switch 14 without operating the power switch 11 on / off. ..
The "dE" error may be cleared by closing the front door and turning off the door switch 15.

FIG. 231 (4) shows an "E1" error (an error indicating that the recovery from the power failure is not normal), which is one of the unrecoverable errors, and "E1" is acquired. It is a figure which shows the state displayed in 3 and 4).
In the program start processing executed when the power switch 11 of the slot machine 10 is turned on, if it is determined that the power off / returning data is not a normal value, an "E1" error occurs and an unrecoverable error processing shown in FIG. 136 is performed. Proceed to 1 (SS_ERROR_STOP1).

When the process proceeds to the unrecoverable error process 1, the interrupt process (I_INTR) shown in FIG. 133 is not executed, and therefore the LED display control (I_LED_OUT) shown in FIG. 134 is not executed either.
Then, when an "E1" error occurs, "E" is displayed on the digit 3 and "1" is displayed on the digit 4 by the unrecoverable error processing 1.

Here, if it is determined that an unrecoverable error has occurred, segment data for displaying the lower digit of the unrecoverable error that has occurred is stored in the L register before shifting to the unrecoverable error processing.
When it is determined that an "E1" error has occurred in the program start processing, a segment for displaying the lower digit "1" of the "E1" error in the L register before shifting to the unrecoverable error processing 1. The data "00000011 (B)" is stored.

Further, in step S1491 of FIG. 136, digit data “01000000 (B)” for lighting the digit 4 is stored in the H register.
Furthermore, in step S1492 of FIG. 136, the digit data “00100000 (B)” for lighting the digit 3 is stored in the D register, and the upper digit “E” of the “E1” error is displayed in the E register. The segment data "01111001 (B)" for this purpose is stored.

Then, in step S1497 of FIG. 136, the data (digit signal) stored in the D register is output from the output port 2, and the data (segment signal) stored in the E register is output from the output port 3. As a result, "E" is displayed on the digit 3 (the upper digit of the acquired number display LED 78).
Further, in step S1501 of FIG. 136, the DE register value and the HL register value are exchanged, and in the next step S1502, the data stored in the D register is output from the output port 2 as in step S1497, and the output port. From 3, the data stored in the E register is output. As a result, "1" is displayed on the digit 4 (lower digit of the acquired number display LED 78).

After that, until the return process is performed, the process of displaying "E" on the digit 3 and the process of displaying "1" on the digit 4 are alternately and repeatedly executed.
In this way, when an "E1" error occurs, "E1" is displayed on the acquired number display LED 78.
Further, when an unrecoverable error occurs, the power switch 11 is temporarily turned off. Then, the setting key switch 12 is turned on by inserting the setting key and rotating it 90 degrees clockwise, and in this state, the power switch 11 is turned on again. As a result, the predetermined range of the RWM 53 is cleared by the initialization process in the setting change process (M_RANK_SET) of FIG. 226, and the return process is performed.

FIG. 231 (5) shows a state in which the stored number display LED 76 (digits 1 and 2) displays the stored number “50” and the acquired number display LED 78 (digits 3 and 4) displays the acquired number “09”. It is a figure which shows.
When the number of stored medals is 50, the stored number data "50" is stored in the stored number data storage area (_NB_CREDIT) of the RWM53.
When the number of medals paid out (the number of medals acquired by the player) is 9, the acquired number data "9" is finally stored in the acquired number data storage area (_NB_PAYOUT) of the RWM53.

Further, when the stored number data "50" is stored in the stored number data storage area (_NB_CREDIT), in step S1443 of the LED display control (I_LED_OUT) of FIG. 134, the stored number data "50" is stored from the stored number data storage area (_NB_CREDIT). 50 ”is acquired and stored in the A register. Proceeding to the next step S1444, the operation of dividing the A register value "50" by "10" is executed, the quotient "5" is stored in the A register as the offset value for the upper digit, and the remainder "0" is the lower digit. It is stored in the C register as an offset value.

Then, in the interrupt processing when the LED display counter value is "00001000 (B)", in step S1455 of FIG. 134, the offset value "5" for the upper digit is added to the start address of the LED segment table 2 of FIG. 224. As a result, "5" display data (address "181C (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, “5” is displayed on digit 1 (upper digit of the stored number display LED 76).

Further, in the interrupt processing when the LED display counter value is "00010000 (B)", in step S1455 of FIG. 134, the offset value "0" for the lower digit is added to the start address of the LED segment table 2 of FIG. 224. As a result, "0" display data (address "1817 (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, “0” is displayed in digit 2 (lower digit of the stored number display LED 76).
In this way, "50" is displayed on the storage number display LED 76.

Further, when the acquired number data "9" is stored in the acquired number data storage area (_NB_PAYOUT), in step S1447 of the LED display control (I_LED_OUT) of FIG. 134, the acquired number data "9" is stored from the acquired number data storage area (_NB_PAYOUT). 9 ”is acquired and stored in the A register. Further, when the process proceeds to step S1450 of FIG. 134, the operation of dividing the A register value “9” by “10” is executed, the quotient “0” is stored in the A register as the offset value for the upper digit, and the remainder “9” is generated. Is stored in the C register as an offset value for lower digits.

Then, in the interrupt processing when the LED display counter value is "00100000 (B)", in step S1455 of FIG. 134, the offset value "0" for the upper digit is added to the start address of the LED segment table 2 of FIG. 224. As a result, "0" display data (address "1817 (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, “0” is displayed in digit 3 (the upper digit of the acquired number display LED 78).

Further, in the interrupt processing when the LED display counter value is "00010000 (B)", in step S1455 of FIG. 134, the offset value "9" for lower digits is added to the start address of the LED segment table 2 of FIG. 224. As a result, "9" display data (address "1820 (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, "9" is displayed on the digit 4 (lower digit of the acquired number display LED 78).
In this way, "09" is displayed on the acquired number display LED 78.

Here, the operation information of the stop switch, which is advantageous to the player, is important information related to whether or not the medal is paid out.
However, if the segments of the acquired number display LEDs 78 (digits 3 and 4) are out of order, or if there is an obstacle in the signal line that transmits signals to these segments, the operation information of the stop switch that is advantageous to the player is acquired. The number display LED 78 may not be displayed correctly, which may be disadvantageous to the player.

Here, it is assumed that the small winning combination B5 is won in the designated game section. At this time, if none of the segments has failed and none of the signal lines that transmit signals to the segments have failed, the acquired number display LED 78 has "= 2" indicating a middle first stop. Should be displayed (FIGS. 19 and 20).
However, for example, it is assumed that the segment E of the digit 4 has failed, or the signal line that transmits a signal to the segment E has failed. In this case, when the small winning combination B5 is won in the designated game section, the segments A, B, D and G of the digit 4 are turned on and the segments C, E and F are turned off. In this case, the player whether "= 2" indicating the middle first stop is displayed on the acquired number display LED 78 or "= 3" indicating the right first stop is displayed on the acquired number display LED 78. Is indistinguishable.

Then, the player who sees the digit 4 in the state where the segments A, B, D and G are lit and the segments C, E and F are extinguished guesses that "3" is displayed on the digit 4 and right. It is assumed that the stop switch 42 is operated in the pressing order of the first stop. In this case, the number of medals acquired by the player is 1 or 0 (FIG. 14), and if "= 2" indicating the first stop in the middle is correctly displayed on the acquired number display LED 78, the medals could have been acquired. The player will not be able to win nine medals.

Therefore, in the present embodiment, during the interrupt processing when the LED display counter value is "00100000 (B)" during the setting change, seven segments A to G of the digit 3 are turned on (the digit 3 is "8". Is displayed), and in the interrupt processing when the LED display counter value is "01000000 (B)", seven segments A to G of the digit 4 are turned on (" 8" is displayed on the digit 4).

In this way, by lighting the seven segments A to G of the digits 3 and 4 during the setting change, the digits 3 and 4 for which the push order instruction information is displayed during the instruction game section are not out of order. It can be confirmed that there is no failure in the signal line that transmits the segment signal to the digits 3 and 4.

Further, during the setting change, for example, seven segments A to G of the digit 3 are lit, and of the seven segments of the digit 4, six of the segments A and C to G are lit. When the segment B does not light up, it can be determined that the segment B of the digit 4 may be out of order.

Furthermore, during the setting change, for example, the six segments A to E and G of the digit 3 are lit, but the segment F is not lit, and the six segments A to E and G of the digit 4 are lit. If it lights up but the segment F does not light up, there is a possibility that not only the segment F of the digits 3 and 4 has failed, but also the signal line that transmits the segment signal to the segment F has failed. Then it can be judged. In particular, since the setting change is performed by the hall clerk before the hall business starts, the hall clerk can check whether there is a segment failure and a signal line failure before the hall business starts. It is possible to prevent the player from being disadvantaged.

Further, in the present embodiment, when an "dE" error occurs, "d" is displayed on the digit 3 in the interrupt processing when the LED display counter value is "00100000 (B)", and the LED display counter value is "01000000 (01000000). In the interrupt processing at the time of "B)", "E" is displayed on the digit 4.

Here, when "d" is displayed on the digit 3, the segments B, C, D, E and G of the digit 3 are lit. This makes it possible to confirm that these segments have not failed and that the signal lines that transmit the segment signals to these segments have not failed.
Further, when "E" is displayed on the digit 4, the segments A, D, E, F and G of the digit 4 are lit. This makes it possible to confirm that these segments have not failed and that the signal lines that transmit the segment signals to these segments have not failed.

Further, in the digits 3 and 4, the segments A to G signals are also used. Therefore, by confirming that the segments B, C, D, E and G of the digit 3 are lit and that the segments A, D, E, F and G of the digit 4 are lit, the segments A to G signals It can be confirmed that no obstacles have occurred in the common parts of the lines 3 and 4.

Of the segment A to G signal lines, the portion common to the digits 3 and 4 is a branch portion in which the signal line branches from the output port 3 (D0 to D7 output terminals of the IC3) into the digit 3 and the digit 4. Means up to.
Further, in the segment A to G signal lines, the portion common to the digits 3 and 4 includes a harness and a connector for connecting the main control board 50 and the display board 75.
Therefore, by confirming that the segments B, C, D, E and G of the digit 3 are lit and that the segments A, D, E, F and G of the digit 4 are lit, the display is displayed from the main control board 50. It can be confirmed that the harness and the connector for transmitting the digit signal and the segment signal to the board 75 are not damaged.

In particular, when the hall clerk opens the front door before or during the opening of the hall, for example, to supply medals to the hopper 35, the door switch 15 is turned on and "dE" is displayed on the acquired number display LED 78. Is displayed. As a result, the clerk of the hall can confirm whether or not there is a failure in the segment and whether or not there is a failure in the signal line before or during the opening of the hall, so that it is possible to prevent the player from being disadvantaged.
Also, during the setting confirmation, unlike during the setting change, "88" is not displayed on the acquisition number display LED 78, but if the front door is open, the door switch 15 remains on and the acquisition number display LED 78. "DE" continues to be displayed. As a result, the clerk in the hall can confirm whether or not there is a failure in the segment and whether or not there is a failure in the signal line, so that it is possible to prevent the player from being disadvantaged.

Further, when the transition is made during the setting confirmation, the image display device 23 displays a "menu screen" which is one of the screens for the clerk in the hall. On the menu screen, items such as "volume setting" and "history of setting changes", "current volume" and "date and time of the last setting change" are displayed. Then, when the cross key 24 is operated to select the item of "setting change history" and the menu button 25 is operated in this state, the "setting change history screen" is displayed on the image display device 23. On the setting change history screen, you can check the "date and time when the setting was changed" and the "setting value after the change" multiple times.

In this way, during the setting confirmation, the set value can be confirmed while looking at the image display device 23 provided on the front side of the front door. Therefore, "dE" is displayed on the acquired number display LED 78 also provided on the front side of the front door. It is easy to check whether is displayed correctly.
However, it is not preferable to display the set value on the image display device 23 in a situation where the player can visually recognize the image display device 23. Therefore, when the transition is made during the setting confirmation, the image display device 23 is first set. The menu screen where the value is not displayed is displayed.
In a situation where the player can visually recognize the image display device 23, the clerk in the hall may check the set value with the set value display LED 73 provided inside the slot machine 10.

In addition, in order to change the setting or confirm the setting, a fraudulent act of opening the front door without the permission of the clerk in the hall may be performed. Further, in order to prevent the hall clerk from noticing that such fraudulent activity is being performed, fraudulent activity such as destroying the sub control board 80 or cutting off the power supply to the sub control board 80 is performed. May be done.
If the sub-control board 80 is destroyed or the power supply to the sub-control board 80 is cut off, the effect lamp 21, the speaker 22, and the image display device 23 will not operate, so that an error notification using these is performed. It disappears.

Here, if the sub-control board 80 is destroyed or the power supply to the sub-control board 80 is cut off, the effect lamp 21, the speaker 22, and the image display device 23 do not operate. Notification will not be performed either.
However, in the present embodiment, since the push order instruction information is displayed on the acquired number display LED 78, even if the sub control board 80 is destroyed or the power supply to the sub control board 80 is cut off, a person who commits fraudulent acts Will be informed of the favorable push order.

Therefore, in the present embodiment, when the opening of the front door is detected, "dE" is displayed on the acquired number display LED 78. As a result, even if the sub control board 80 is destroyed or the power supply to the sub control board 80 is cut off, the clerk in the hall can know that the front door has been opened.
Further, when the acquired number display LED 78 is destroyed, "dE" is not displayed on the acquired number display LED 78, but the push order instruction information is also not displayed. In this case, even a cheating person cannot know the favorable push order. Therefore, the destruction of the acquired number display LED 78 can be suppressed by displaying the push order instruction information on the acquired number display LED 78.
That is, by displaying the error information and the push order instruction information on the acquired number display LED 78, even if the sub control board 80 is destroyed, the error information is displayed and the destruction of the acquired number display LED 78 is suppressed. can do.

Further, in the present embodiment, when an "E1" error occurs, interrupt processing is not executed, but a digit signal is output from the output port 2 and a segment signal is output from the output port 3 so that "E" is displayed on the digit 3. The process of outputting the digit signal and the process of outputting the digit signal from the output port 2 and outputting the segment signal from the output port 3 are alternately and repeatedly executed so that "1" is displayed on the digit 4.

Here, when "E" is displayed on the digit 3, the segments A, D, E, F and G of the digit 3 are lit. This makes it possible to confirm that these segments have not failed and that the signal lines that transmit the segment signals to these segments have not failed.
Further, when "1" is displayed on the digit 4, the segments B and C of the digit 4 are lit. This makes it possible to confirm that these segments have not failed and that the signal lines that transmit the segment signals to these segments have not failed.

Further, since the segments A to G are also used in the digits 3 and 4, the segments A, D, E, F and G of the digit 3 are lit, and the segments B and C of the digit 4 are lit. By confirming that, it can be confirmed that no failure has occurred in the common portion of the segments A to G signal lines in the digits 3 and 4.
That is, it can be confirmed that the harness and the connector for transmitting the digit signal and the segment signal from the main control board 50 to the display board 75 are not faulty.

In particular, when the power switch 11 is turned on for the first time after shipment from the factory, it is determined that the power off / returning data is not a normal value in the program start process. Therefore, when the power switch 11 is turned on for the first time after shipment from the factory, an "E1" error always occurs, and the process proceeds to the unrecoverable error processing 1 (SS_ERROR_STOP1) shown in FIG. 136.
When an "E1" error occurs, after turning off the power switch 11, turn the setting key 90 degrees clockwise to turn on the setting key switch 12, and then turn on the power switch 11 again in this state. To. As a result, the process proceeds to the setting change process (M_RANK_SET), the predetermined range of the RWM53 is cleared, and the "E1" error is cleared.

From the above, when the power switch 11 is first turned on after shipment from the factory, "E1" is displayed on the acquired number display LED 78. Further, when the operation for canceling the "E1" error is performed, the process proceeds to the setting change process (M_RANK_SET), and "88" is displayed on the acquired number display LED 78.
As a result, when the power switch 11 is turned on for the first time after shipment from the factory, the clerk in the hall can check whether there is a segment failure or a signal line failure, so that the player is not disadvantaged. be able to.
In particular, there is a possibility that the harness and the connector for transmitting the digit signal and the segment signal may be damaged during transportation from the factory to the hall or installation in the hall. Therefore, it is effective to confirm that "E1" is displayed on the acquired number display LED 78 when the power switch 11 is turned on for the first time in order to confirm that the harness and the connector are not damaged. Is.

Further, in the present embodiment, in the interrupt processing when the LED display counter value is "00001000 (B)", the upper digit of the number of stored sheets is displayed in digit 1 and the LED display counter value is "00010000 (B)". In the interrupt processing of, the lower digit of the number of stored sheets is displayed in digit 2. Further, in the interrupt processing when the LED display counter value is "00100000 (B)", the upper digit of the acquired number is displayed in digit 3, and in the interrupt processing when the LED display counter value is "01000000 (B)", The lower digit of the number of acquired sheets is displayed on the digit 4.

Here, if it can be confirmed that the numerical values from "0" to "2" are displayed in the digit 1, the segments A to G of the digit 1 have not failed, and the segments A to G signals are transmitted to the digit 1. It can be confirmed that there is no failure in the signal line to be transmitted. This also applies to digits 2 to 4.

Further, since the segments A to G signals are also used in the digits 1 to 4, by confirming that the segments A to G of the digit 1 are lit, the digits 1 to 4 of the segment A to G signal lines are used. Regarding the common part in 4, it can be confirmed that no failure has occurred. That is, it can be confirmed that the harness and the connector for transmitting the digit signal and the segment signal from the main control board 50 to the display board 75 are not faulty.

Here, when the player inserts medals from the medal slot 43 while the number of stored medals is 0, the first three medals are not stored (credited) and bet (bet) for the game. The fourth and subsequent medals are stored.
Therefore, for example, when the number of stored medals is 0 and the player inserts 5 medals from the medal insertion slot 43, 2 medals are stored. Therefore, the stored number display LED76 (digit 1) And the display of 2) changes as "00"->"01"->"02". As a result, the numerical values from "0" to "2" are sequentially displayed on the digit 2 (lower digit of the storage number display LED 76), and the player confirms this to confirm the segments A to G of the digit 2. It can be confirmed that there is no failure and that there is no failure in the signal line that transmits the segments A to G signals to the digits 1 to 4.

Also, in a hall where 50 medals can be borrowed for 1,000 yen, if the player borrows 50 medals at the start of the game and inserts all of them from the medal slot 43, the number of medals stored will be 47. .. At this time, since the numerical values from "00" to "47" are sequentially displayed on the storage number display LED 76, the player confirms this, and the segments A to G of the digits 1 and 2 are out of order. It can be confirmed that there is no failure and that the signal lines that transmit the segments A to G signals to the digits 1 to 4 are not disturbed.

<29th Embodiment>
In the 29th embodiment, the digit 5 is not provided. Then, under the situation where the number of medals acquired is displayed, the number of acquired medals is displayed on the digits 3 and 4 (acquired number display LED78), and under the situation where the push order instruction information is displayed, the push order instruction information is displayed on the digits 3 and 4. Is displayed, and in a situation where the set value can be changed, the set value is displayed on the digit 4.
Further, also in the 29th embodiment, as in the 28th embodiment, when a "dE" error occurs, "dE" is displayed on the acquired number display LED 78, and when an "E1" error occurs, "E1" is displayed on the acquired number display LED. Is displayed.

Here, in the 29th embodiment, the digits 1 to 4 and the circuit configuration for lighting them are the same as those in the 21st embodiment.
That is, as shown in FIG. 138, digits 1 to 4 and 6 to 9 signals are output from the output port 3, and segment A to G signals are output from the output port 4. Further, the segments A to G signals are also used for digits 1 to 4.

Further, as shown in FIG. 139 (B), in the interrupt processing when the LED display counter value is “00000001 (B)”, digit 1 can be turned on, and when the LED display counter value is “00000010 (B)”. In the interrupt processing of, the digit 2 can be turned on. Further, in the interrupt processing when the LED display counter value is "00000100 (B)", the digit 3 can be lit, and in the interrupt processing when the LED display counter value is "00001000 (B)", the digit 4 can be lit. It becomes.
In this way, the digit to be turned on is sequentially switched for each interrupt process. That is, dynamic lighting is executed.

FIG. 232 is a diagram showing addresses, labels, and contents of data stored in the RWM 53 in the 29th embodiment, and is a diagram corresponding to FIG. 222 in the 28th embodiment.
In the 28th embodiment, the setting changing display data (“88”) is stored in the acquired number data storage area (_NB_PAYOUT) during the setting change, but in the 29th embodiment, the setting changing display data is replaced with the setting changing display data. , The set value display data (value of any one of "1" to "6") is stored.
Further, storing the LED display request flag in the LED display request flag storage area (_FL_LED_DSP) is the same in the 28th embodiment and the 29th embodiment, but the value of the LED display request flag is the 28th embodiment. And the 29th embodiment.
Other than the above, it is the same as FIG. 222 of the 28th embodiment.

FIG. 233 is a diagram showing the relationship between the set value data, the set value display data, and the set value display.
As described above, the set value data is stored in the set value data storage area (_NB_RANK).
Further, the set value display data is data obtained by adding "1" to the set value data, and is stored in the acquired number data storage area (_NB_PAYOUT) during the setting change.
Then, when the set value is "N", the set value data "N-1" is stored in the set value data storage area (_NB_RANK). The set value display data "N" is stored in (_NB_PAYOUT), and the set value "N" is displayed in the digit 4 (lower digit of the acquired number display LED 78).

FIG. 234 is a flowchart showing the setting change process (M_RANK_SET) in the 29th embodiment, and is a flowchart corresponding to FIG. 226 in the 28th embodiment.
In the flowchart described below, the steps for executing the same processing as those in the 28th embodiment are designated by the same step numbers, and duplicate description will be omitted. Further, steps having contents different from those of the 28th embodiment are underlined in step numbers.

Step S4101 is a step corresponding to step S4001 of FIG. 226, and here, set value display data is generated and stored in the acquired number data storage area (_NB_PAYOUT). Details of this process will be described later with reference to FIG. 235.
The next step S4102 is a step corresponding to step S4002 of FIG. 226, and here, “000001100 (B)” corresponding to the setting is stored in the LED display request flag storage area (_FL_LED_DSP).
By the process of step S4102, the digits 3 and 4 (acquired number display LED78) can be turned on. Then, the current set value is displayed on the digit 4 (lower digit of the acquired number display LED 78) by the interrupt process executed after the process of step S4102.

In step S4103, the set value display data is generated and stored in the acquired number data storage area (_NB_PAYOUT) in the same manner as in step S4101 described above. The step corresponding to this step S4103 is not provided in FIG. 226.
The next step S4104 is a step corresponding to step S4004 of FIG. 226, and here, "11111111 (B)" corresponding to the normal state is stored in the LED display request flag storage area (_FL_LED_DSP).
Then, by the interrupt processing executed after the processing of step S4104, the display of digits 1 to 4 (stored number display LED76 and acquired number display LED78) becomes "0000". The stored number display LED 76 and the acquired number display LED 78 may be turned off.
Other than the above, it is the same as the flowchart of FIG. 226 of the 28th embodiment.

FIG. 235 is a flowchart showing the set value display data set processing in steps S4101 and S4103 of FIG. 234.
First, in step S4111, the set value data is acquired from the set value data storage area (_NB_RANK), and in the next step S4112, "1" is added to the set value data to generate the set value display data. Then, the process proceeds to the next step S4413.
Proceeding to step S4113, the set value display data is stored in the acquired number data storage area (_NB_PAYOUT). Then, the process according to this flowchart is completed.

FIG. 236 (1) is a diagram showing a state in which the set values “1” to “6” are displayed on the digit 4 (lower digit of the acquired number display LED 78) during the setting change.
As described above, in step S4101 of the setting change process of FIG. 234, the set value display data is generated and stored in the acquired number data storage area (_NB_PAYOUT), and in the next step S4102, the LED display request flag storage area ( _FL_LED_DSP) stores the corresponding LED display request flag "00001100 (B)" during the setting change. Then, the set value is displayed on the digit 4 by the interrupt processing executed after this processing.

Here, it is assumed that, for example, "6" is stored in the acquired number data storage area (_NB_PAYOUT) as the set value display data. In this case, in the LED display control (I_LED_OUT) of FIG. 134, in step S1447, the set value display data “6” is acquired from the acquired number data storage area (_NB_PAYOUT) and stored in the A register. Further, in step S1450, an operation of dividing the set value display data "6" stored in the A register by "10" is executed, and the quotient "0" is stored in the A register as an offset value for the upper digit, and the remainder is obtained. "6" is stored in the C register as an offset value for lower digits.

Further, in the interrupt processing when the LED display counter value is "00001000 (B)", in step S1455 of FIG. 134, the offset value "6" for the lower digit is added to the start address of the LED segment table 2 of FIG. 224. As a result, "6" display data (address "181D (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, “6” is displayed on the digit 4 (lower digit of the acquired number display LED 78).

Further, when the operation of the setting switch 13 is detected in step S2140 of FIG. 234, the process proceeds to step S2141, where the set value data of the set value data storage area (_NB_RANK) is updated, and in the next step S4103, the setting is set. Value display data is generated and stored in the acquired number data storage area (_NB_PAYOUT). Then, the updated set value is displayed in the digit 4 by the interrupt process executed after this process.

Further, when the process proceeds to step S2140 in FIG. 234, the processes of steps S2140 to S4103 are repeated until the operation of the start switch 41 is detected in step S2142. As a result, the display of the digit 4 is switched as “1” → “2” → ... → “5” → “6” → “1” → ... As shown in FIG. 236 (1).
In this way, the set value is displayed on the digit 4 while the setting is being changed.
Further, the display of the set value continues until the acquired number data storage area (_NB_PAYOUT) is cleared in step S4003 of the setting change process of FIG. 234. Then, when the acquired number data storage area (_NB_PAYOUT) is cleared, the digit 4 is displayed from the set value (any value of "1" to "6") by the interrupt processing executed after this processing. It becomes "0".

FIG. 236 (2) is a diagram showing a state in which the push order instruction information “= 1” is displayed on the acquisition number display LED 78 in the instruction game section. The process for displaying the push order instruction information on the acquired number display LED 78 is the same as in FIG. 231 (2).
Further, FIG. 236 (3) is a diagram showing a state in which the acquired number “09” is displayed on the acquired number display LED 78. The process for displaying the acquired number on the acquired number display LED 78 is the same as in FIG. 231 (5).

As described above, in the 29th embodiment, during the setting change, the set value is displayed on the digit 4 (lower digit of the acquired number display LED 78) in the interrupt processing when the LED display counter value is "00001000 (B)". do.
Further, during the setting change, each time the setting switch 13 is operated, the display (set value) of the digit 4 is changed from "1" → "2" → ... → "5" → "6" → "1". Switch to → ...

Here, if it can be confirmed that the numerical values from "2" to "4" are displayed in the digit 4, the segments A to G of the digit 4 have not failed, and the segments A to G signals are displayed in the digit 4. It can be confirmed that there is no failure in the signal line that transmits.
Further, since the segments A to G signals are also used in the digits 3 and 4, by confirming that the segments A to G of the digit 4 are lit, the digits 3 and 4 of the segment A to G signal lines are used. Regarding the common part in 4, it can be confirmed that no failure has occurred. That is, it can be confirmed that the harness and the connector for transmitting the digit signal and the segment signal from the main control board 50 to the display board 75 are not faulty. In particular, since it can be confirmed when the clerk of the hall changes the set value before the opening of the hall, there is no disadvantage to the player.

<Modified Examples of 28th and 29th Embodiments>
Although the 28th and 29th embodiments have been described above, the present invention is not limited to the above-mentioned contents, and various modifications such as the following are possible.
(1) In the 28th embodiment, when the game has an advantageous push order in the indicated game section, the push order is set to digit 3 by the interrupt processing when the LED display counter value is "00100000 (B)". "=", Which is a part of the instruction information, is displayed, and in the interrupt processing when the LED display counter value is "01000000 (B)", the digit 4 is the other part of the push order instruction information, "1" to "3" was displayed. However, it is not limited to this.

(2) In the circuit configuration of the 28th embodiment, when the game has an advantageous push order in the indicated game section, the digit 3 is interrupted by the interrupt processing when the LED display counter value is "00100000 (B)". The push order instruction information "1" to "3" may be displayed on the.
Further, regarding the digit 4, "0" or "=" may be displayed in the interrupt processing when the LED display counter value is "01000000 (B)", and "0" or "=" may be displayed, or hidden (segments A to G are turned off). ) May be used.

(3) In the circuit configuration of the 28th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 3, the LED display counter value is "00100000 (B)" during the setting change. In the interrupt process, "8" may be displayed on the digit 3 (segments A to G are lit).
From this, it can be confirmed that the segments A to G of the digit 3 have not failed and that the signal line for transmitting the segment A to G signals to the digit 3 has not failed.

(4) In the circuit configuration of the 28th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 3, the LED display counter value is "01000000 (B)" during the setting change. In the interrupt process, "8" may be displayed on the digit 4 (segments A to G are lit).
As a result, by confirming that the segments A to G of the digit 4 are lit, it is possible to confirm that no failure has occurred in the common portion of the segment A to G signal lines in the digits 3 and 4.

(5) In the circuit configuration of the 28th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 3, the numerical value from "0" to "2" may be displayed on the digit 3. ..
Even in this way, it can be confirmed that the segments A to G of the digit 3 have not failed and that the signal line for transmitting the segment A to G signals to the digit 3 has not failed.

(6) In the circuit configuration of the 28th embodiment, even when the push order instruction information "1" to "3" is displayed on the digit 3, the LED display counter value is "00100000 (B)" when the "dE" error occurs. "D" may be displayed on the digit 3 in the interrupt processing when "", and "E" may be displayed on the digit 4 in the interrupt processing when the LED display counter value is "01000000 (B)".
By confirming that the segments B, C, D, E and G of the digit 3 are lit and the segments A, D, E, F and G of the digit 4 are lit, the segments A to G signals are lit. It can be confirmed that no obstacle has occurred in the common part of the lines 3 and 4.

(7) In the circuit configuration of the 28th embodiment, even when the push order instruction information "1" to "3" is displayed on the digit 3, the process of displaying "E" on the digit 3 when an "E1" error occurs. And the process of displaying "1" on the digit 4 may be alternately and repeatedly executed.
By confirming that the segments A, D, E, F and G of the digit 3 are lit and the segments B and C of the digit 4 are lit, the digit 3 of the segment A to G signal lines is lit. It can be confirmed that there is no failure in the common part in and 4.

(8) In the circuit configuration of the 28th embodiment, even when the push order instruction information "1" to "3" is displayed on the digit 3, the interrupt processing is performed when the LED display counter value is "00001000 (B)". , The upper digit of the number of stored sheets is displayed in digit 1, and the lower digit of the number of stored sheets is displayed in digit 2 by the interrupt process when the LED display counter value is "00010000 (B)". Further, in the interrupt processing when the LED display counter value is "00100000 (B)", the upper digit of the acquired number is displayed in digit 3, and the interrupt processing when the LED display counter value is "01000000 (B)" is performed. The lower digit of the number of acquired sheets is displayed on the digit 4.
By confirming that the segments A to G are lit for the digits 1 to 4, it is confirmed that the common parts of the segments A to G signal lines are not damaged. can.

(9) In the circuit configuration of the 28th embodiment, when the game has an advantageous push order in the indicated game section, the digit 3 is interrupted by the interrupt processing when the LED display counter value is "00100000 (B)". When "0" is displayed or digit 3 is hidden (segments A to G are turned off) and the LED display counter value is "01000000 (B)", the push order instruction information "0" is displayed on digit 4. 1 ”to“ 3 ”may be displayed.

(10) In the circuit configuration of the 28th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 4, the LED display counter value is "01000000 (B)" during the setting change. In the interrupt process, "8" may be displayed on the digit 4 (segments A to G are lit).
From this, it can be confirmed that the segments A to G of the digit 4 have not failed and that the signal line for transmitting the segment A to G signals to the digit 4 has not failed.

(11) In the circuit configuration of the 28th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 4, the LED display counter value is "00100000 (B)" during the setting change. In the interrupt process, "8" may be displayed on the digit 3 (segments A to G are lit).
As a result, by confirming that the segments A to G of the digit 3 are lit, it is possible to confirm that no failure has occurred in the common portion of the segment A to G signal lines in the digits 3 and 4.

(12) In the circuit configuration of the 28th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 4, the numerical value from "0" to "2" may be displayed on the digit 4. ..
Even in this way, it can be confirmed that the segments A to G of the digit 4 have not failed and that the signal line for transmitting the segment A to G signals to the digit 4 has not failed.

(13) In the circuit configuration of the 28th embodiment, even when the push order instruction information "1" to "3" is displayed on the digit 4, the LED display counter value is "00100000 (B)" when the "dE" error occurs. "D" may be displayed on the digit 3 in the interrupt processing when "", and "E" may be displayed on the digit 4 in the interrupt processing when the LED display counter value is "01000000 (B)".
By confirming that the segments B, C, D, E and G of the digit 3 are lit and the segments A, D, E, F and G of the digit 4 are lit, the segments A to G signals are lit. It can be confirmed that no obstacle has occurred in the common part of the lines 3 and 4.

(14) In the circuit configuration of the 28th embodiment, even when the push order instruction information "1" to "3" is displayed on the digit 4, the process of displaying "E" on the digit 3 when an "E1" error occurs. And the process of displaying "1" on the digit 4 may be alternately and repeatedly executed.
By confirming that the segments A, D, E, F and G of the digit 3 are lit and the segments B and C of the digit 4 are lit, the digit 3 of the segment A to G signal lines is lit. It can be confirmed that there is no failure in the common part in and 4.

(15) In the circuit configuration of the 28th embodiment, even when the push order instruction information "1" to "3" is displayed on the digit 4, the interrupt processing is performed when the LED display counter value is "00001000 (B)". , The upper digit of the number of stored sheets is displayed in digit 1, and the lower digit of the number of stored sheets is displayed in digit 2 by the interrupt process when the LED display counter value is "00010000 (B)". Further, in the interrupt processing when the LED display counter value is "00100000 (B)", the upper digit of the acquired number is displayed in digit 3, and the interrupt processing when the LED display counter value is "01000000 (B)" is performed. The lower digit of the number of acquired sheets is displayed on the digit 4.
By confirming that the segments A to G are lit for the digits 1 to 4, it is confirmed that the common parts of the segments A to G signal lines are not damaged. can.

(16) In the 29th embodiment, when the game has an advantageous push order in the indicated game section, the push order is set to digit 3 by the interrupt processing when the LED display counter value is "00000100 (B)". "=", Which is a part of the instruction information, is displayed, and in the interrupt processing when the LED display counter value is "00001000 (B)", the digit 4 is the other part of the push order instruction information, "1" to "3" was displayed. However, it is not limited to this.

(17) In the circuit configuration of the 29th embodiment, when the game has an advantageous push order in the indicated game section, the digit 3 is interrupted by the interrupt processing when the LED display counter value is "00000100 (B)". The push order instruction information "1" to "3" may be displayed on the.
Further, regarding the digit 4, "0" or "=" may be displayed in the interrupt processing when the LED display counter value is "00001000 (B)", or "0" or "=" may be displayed, and the segments A to G are turned off. ) May be used.

(18) In the circuit configuration of the 29th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 3, the LED display counter value is "00001000 (B)" during the setting change. The set value may be displayed on the digit 4 by interrupt processing.
Further, during the setting change, each time the setting switch 13 is operated, the display (set value) of the digit 4 is changed from "1" → "2" → ... → "5" → "6" → "1". Switch to → ...

Then, if it can be confirmed that the numerical values from "2" to "4" are displayed in the digit 4, the segments A to G of the digit 4 have not failed, and the segments A to G signals are transmitted to the digit 4. It can be confirmed that there is no failure in the signal line to be transmitted.
Further, since the segments A to G signals are also used in the digits 3 and 4, by confirming that the segments A to G of the digit 4 are lit, the digits 3 and 4 of the segment A to G signal lines are used. It can be confirmed that there is no failure in the common part.

(19) In the circuit configuration of the 29th embodiment, when the game has an advantageous push order in the indicated game section, the digit 4 is interrupted by the interrupt processing when the LED display counter value is "00001000 (B)". The push order instruction information "1" to "3" may be displayed on the.
Further, regarding the digit 3, "0" may be displayed or hidden (segments A to G are turned off) in the interrupt processing when the LED display counter value is "000000100 (B)". ..

(20) In the circuit configuration of the 29th embodiment, when the push order instruction information "1" to "3" is displayed on the digit 4, the LED display counter value is "00001000 (B)" during the setting change. The set value may be displayed on the digit 4 by interrupt processing.
Further, during the setting change, each time the setting switch 13 is operated, the display (set value) of the digit 4 is changed from "1" → "2" → ... → "5" → "6" → "1". Switch to → ...
Then, if it can be confirmed that the numerical values from "2" to "4" are displayed in the digit 4, the segments A to G of the digit 4 have not failed, and the segments A to G signals are transmitted to the digit 4. It can be confirmed that there is no failure in the signal line to be transmitted.

(21) In the 29th embodiment, the set value is displayed on the digit 4 (lower digit of the acquired number display LED 78) during the setting change. At this time, the digit 3 (upper digit of the acquired number display LED 78) is displayed. “0” may be displayed, “_” may be displayed (only segment D is lit), or it may be hidden (segments A to G are turned off).

(22) In the 28th and 29th embodiments, as shown in FIGS. 20 and 225, there are three types of advantageous push orders: left first stop, middle first stop, and right first stop. The push order instruction numbers had four types of "A0 (H)" to "A3 (H)", and the push order instruction information had four types of "= 0" to "= 3". However, it is not limited to this.

(23) As shown in FIG. 237, as an advantageous push order, nine types including a three-choice push order such as left first stop and a six-choice push order such as 123 (left middle right) are provided. Ten types of push order instruction numbers "A0 (H)" to "A9 (H)" may be provided, and ten types of push order instruction information "= 0" to "= 9" may be provided.
Even in this case, by storing the push order instruction number in the acquired number data storage area (_NB_PAYOUT), the push order instruction information "= 0" to "= 9" is displayed on the acquired number display LEDs 78 (digits 3 and 4). can do.

(24) In FIG. 237, the push order instruction number corresponding to the left first stop is set to "A1 (H)" and the push order instruction information is set to "= 1". The instruction number may be "A1 (H)" and the push order instruction information may be "= 1".
Similarly, the push order instruction number corresponding to the left first stop may be set to "A7 (H)", and the push order instruction information may be set to "= 7".
In this way, the relationship between the advantageous push order, the push order instruction number, and the push order instruction information can be appropriately set.

Specifically, for example, the push order instruction numbers may be set to "1A (H)" to "9A (H)", and "1" to "9" may be displayed as push order instruction information on the digit 3. At this time, the digit 4 is hidden (segments A to G are turned off). In this case, it is necessary to provide non-display data "0000000000 (B)" instead of "=" display data.
Further, for example, the push order instruction numbers may be set to "A1 (H)" to "A9 (H)", and the push order instruction information "1" to "9" may be displayed on the digit 4. At this time, the digit 3 is hidden (segments A to G are turned off). Also in this case, it is necessary to provide the non-display data “0000000000 (B)” instead of the “=” display data.

Furthermore, for example, the push order instruction numbers may be set to "1" to "9", and "01" to "09" may be displayed as push order instruction information on the digits 3 and 4, and the push order instruction numbers may be displayed. "10" to "90" may be set, and "10", "20", "30" ... "80" or "90" may be displayed on the digits 3 and 4 as push order instruction information, and the push may be displayed. The order instruction numbers are set to "1A (H)" to "9A (H)", and the push order instruction information for digits 3 and 4 is "1 =", "2 =", "3 =" ... "8 =". Alternatively, "9 =" may be displayed.

(25) In the 28th and 29th embodiments, when there is no advantageous push order (push order instruction number "A0 (H)") in the designated game section, the acquired number display LED 78 (digits 3 and 4) is displayed. Although the push order instruction information "= 0" is displayed, the acquired number display LED 78 may be hidden (segments A to G are turned off) without displaying "= 0".

(26) In the indicated game section, when the game has an advantageous push order, the push order instruction information is displayed on the digit 3 (upper digit of the acquired number display LED 78), and the digit 4 (acquired number display LED 78) is displayed. Information indicating the stop switch 42 to be operated next (next operation instruction information) may be displayed in the lower digit).
Of course, contrary to the above, the next operation instruction information may be displayed on the digit 3 and the push order instruction information may be displayed on the digit 4.

Here, regarding the push order instruction information, "left middle right" is set to "1", "left and right middle" is set to "2", "middle left and right" is set to "3", and "middle right left" is set to "4". "Right, left, middle" is "5", and "right, middle, left" is "6". Further, "left first stop" is set to "7", "middle first stop" is set to "8", and "right first stop" is set to "9".
Furthermore, regarding the next operation instruction information, "left" is set to "1", "middle" is set to "2", and "right" is set to "3". Further, when there is no stop switch 42 to be operated next, the next operation instruction information is set to "0".

In this case, when the advantageous push order is "middle left and right" and the stop switch 42 to be operated next is "middle", "3" is displayed as push order instruction information on the digit 3 and next to the digit 4. "2" is displayed as the operation instruction information. At this time, "32" is stored in the acquired number data storage area (_NB_PAYOUT).
Further, when the advantageous pressing order is "middle left and right" and the stop switch 42 to be operated next is "left", "3" is displayed as the pressing order instruction information on the digit 3 and the next operation is performed on the digit 4. "1" is displayed as instruction information. At this time, "31" is stored in the acquired number data storage area (_NB_PAYOUT).

Furthermore, when the advantageous pressing order is "right first stop" and the stop switch 42 to be operated next is "right", "9" is displayed on the digit 3 as the pressing order instruction information, and the digit 4 is displayed. "3" is displayed as the next operation instruction information. At this time, "93" is stored in the acquired number data storage area (_NB_PAYOUT).
Further, when the advantageous pressing order is "right first stop" and there is no stop switch 42 to be operated next, "9" is displayed as the pressing order instruction information on the digit 3 and the next operation instruction is displayed on the digit 4. "0" is displayed as information. At this time, "90" is stored in the acquired number data storage area (_NB_PAYOUT).
When there is no stop switch 42 to be operated next, the next operation instruction information may be set to "4" instead of "0". Further, the digit in which the next operation instruction information is displayed may be hidden (segments A to G may be turned off).

(27) In the indicated game section, when the game has an advantageous push order, the condition device number may be displayed on the acquired number display LED 78 (segments 3 and 4).
For example, in the indicated game section, when the small winning combination B2 of the condition device number "12" is won, the interrupt processing when the LED display counter value is "00100000 (B)" is performed, and the digit 3 (the upper rank of the acquired number display LED 78) is used. In the digit), "1" which is the upper digit of the condition device number "12" is displayed, and in the interrupt processing when the LED display counter value is "01000000 (B)", digit 4 (the lower digit of the acquired number display LED 78) is displayed. ) Displays "2", which is the lower digit of the condition device number "12".

Further, in the indicated game section, when the replay B3 of the condition device number "4" is won, "0" is displayed in the digit 3 by the interrupt processing when the LED display counter value is "00100000 (B)". , The condition device number "3" is displayed on the digit 4 by the interrupt processing when the LED display counter value is "01000000 (B)".
As described above, when the condition device number is one digit, "0" may be displayed on the digit 3, but the digit 3 may be hidden (segments A to G are turned off).

Furthermore, in the designated game section, when the condition device number "0" is not won, "0" may be displayed in the digits 3 and 4, respectively, and both the digits 3 and 4 are hidden (segments). A to G may be turned off).
Further, in the designated game section, when the condition device has no advantageous push order, such as replay A (conditional device number "1") and small winning combination F (conditional device number "29"), digit 3 and The condition device number may be displayed in 4, the "0" may be displayed in the digits 3 and 4, respectively, and both the digits 3 and 4 may be hidden (segments A to G are turned off).

(28) In the indicated game section, when the game has an advantageous push order, the push order instruction number is determined by the lighting or extinguishing pattern of the segments A to G of the digit 4 (lower digit of the acquired number display LED 78). The numerical value corresponding to may be displayed in binary.
In this case, the push order instruction numbers are "1" to "9" instead of "A1 (H)" to "A9 (H)".
In addition, instead of the digit 4, the numerical value corresponding to the push order instruction number may be displayed in binary according to the lighting or extinguishing pattern of the segments A to G of the digit 3.

FIG. 238 is a diagram showing the relationship between the segments A to G and the bits 0 to 6.
As shown in FIG. 238, segment A corresponds to bit 0 and segment B corresponds to bit 1. Similarly, the segments C to G correspond to bits 2 to 6, respectively.
Then, when the numerical value corresponding to the push order instruction number is expressed in binary, if the bit 0 is "0", the segment A of the digit 4 is turned off, and if the bit 0 is "1", the digit 4 is turned off. The segment A of is turned on. The same applies to the segments B to G.

FIG. 239 is a diagram showing the relationship between the push order instruction number, the display data, the digit display, and the advantageous push order.
As shown in FIG. 239, the push order instruction number "1 (D)" is expressed as "00000001 (B)" in binary, and this is used as the display data (segment output data) of the segments A to G of the digit 4. When used, the segment A of the digit 4 can be turned on and the segments B to G can be turned off.
In this way, the push order instruction number is represented by a binary number, and this can be displayed in the pattern of turning on or off the segments A to G of the digit 4. In this case, the LED segment table 1 (TBL_SEG_DATA1) and the LED segment table 2 (TBL_SEG_DATA2) are not used. The same applies to the push order instruction numbers "2 (D)" to "9 (D)".

For example, it is assumed that the small winning combination B12 is won in the designated game section. The advantageous push order corresponding to the small winning combination B12 is "right first stop", and the push order instruction number is "3 (D)".
In this case, in the push order instruction number set processing (M_ORD_INF), the push order instruction number "3 (D)" (binary number "00000011 (B)") corresponding to the winning small winning combination B12 is given to the push order instruction of the RWM53. Store in the number storage area. In addition, the push order instruction number is not stored in the acquired number data storage area (_NB_PAYOUT).
Then, in the LED display control (I_LED_OUT), in the interrupt processing when the LED display counter value is "01000000 (B)" (digit 4 signal is on), the push order stored in the push order instruction number storage area of the RWM53 is stored. The instruction number "00000011 (B)" is acquired as display data (segment output data), and this is output from the output port 3 (output port 4).

As a result, the segments A and B of the digit 4 can be turned on and the segments C to G can be turned off.
In this way, the numerical value corresponding to the push order instruction number can be displayed in binary according to the lighting or extinguishing pattern of the segments A to G of the digit 4.
Further, when the numerical value corresponding to the push order instruction number is displayed in the digit 4 in binary, the digit 3 may be hidden (segments A to G are turned off), and the next operation instruction information is displayed in binary. You may.

FIG. 240 is a diagram showing the relationship between the next operation instruction information, the display data, the digit display, and the stop switch 42 to be operated next.
As shown in FIG. 240, when the stop switch 42 to be operated next is on the left, the next operation instruction information is "1", which is expressed in binary number as "00000001 (B)". Therefore, when the next operation instruction information "1" is displayed in the digit 3 in binary, the segment A of the digit 3 is turned on and the segments B to G are turned off. The same applies to the next operation instruction information “2” to “4”.
The numerical value corresponding to the push order instruction number may be displayed in the digit 3 as a binary number instead of the digit 4. In this case, the digit 4 may be hidden (segments A to G are turned off), and the next operation instruction information may be displayed in binary.

(29) In the indicated game section, when the game has an advantageous push order, the condition device number is set according to the lighting or extinguishing pattern of the segments A to G of the digit 4 (lower digit of the acquired number display LED 78). It may be displayed in binary.
FIG. 241 is a diagram illustrating the relationship between the condition device number, the display data, the digit display, and the advantageous push order for the small combinations B1 to B12.
As shown in FIG. 241, the condition device number of the small winning combination B1 is "11", and when this is expressed in binary, it is "00001011 (B)". Therefore, when the condition device number "11" is displayed in the digit 4 in binary, the segments A, B, and D of the digit 4 are turned on, and the segments C and E to G are turned off. The same applies to other conditional device numbers.

Specifically, in the designated game section, when the small winning combination B1 of the conditional device number "11" is won, the conditional device number "11" (binary number "000001011 (B)") is given to the RWM53 for winning and replaying. Condition Store in the device number storage area (_NB_CND_NOR).
Then, in the LED display control (I_LED_OUT), in the interrupt processing when the LED display counter value is "01000000 (B)" (digit 4 signal is on), the prize is stored in the RWM53 and the replay condition device number storage area (_NB_CND_NOR). The condition device number "00001011 (B)" is acquired as display data (segment output data), and this is output from the output port 3 (output port 4).

As a result, the segments A, B and D of the digit 4 can be turned on, and the segments C and E to G can be turned off.
In this way, the condition device number can be displayed in binary according to the lighting or extinguishing pattern of the segments A to G of the digit 4.

When the condition device number is displayed in binary on the digit 4, the digit 3 may be hidden (segments A to G are turned off), and the next operation instruction information may be displayed in binary.
Furthermore, the conditional device number may be displayed in binary not in digit 4 but in digit 3. In this case, the digit 4 may be hidden (segments A to G are turned off), and the next operation instruction information may be displayed in binary.

(30) In the 28th and 29th embodiments, in the same interrupt processing, the digits that can be lit are different depending on the LED display counter value. For example, in the 28th embodiment, in the same interrupt processing, when the LED display counter value is "00100000 (B)", the digit 3 can be turned on, and when the LED display counter value is "01000000 (B)", the digit 3 can be turned on. , Digit 4 can be turned on. However, the display control of the LED including the digits 3 and 4 is not limited to the case where the same interrupt processing is executed.

For example, interrupt processing A is executed, and interrupt processing B is executed independently of interrupt processing A. That is, a plurality of interrupt processes are executed. Then, the interrupt process A controls the display of the digit 3, and the interrupt process B controls the display of the digit 4. In this way, the display of the LED including the digits 3 and 4 may be controlled by a plurality of separate and independent interrupt processes.

(31) In the 28th and 29th embodiments, interrupt processing is not executed at the time of an unrecoverable error, and the display of digits 3 and 4 is controlled by the unrecoverable error processing 1 (SS_ERROR_STOP1) shown in FIG. 136. However, the LED display control at the time of an unrecoverable error is not limited to this.
For example, interrupt processing may be executed even when an unrecoverable error occurs, and the display of the LED including the digits 3 and 4 may be controlled by this interrupt processing.
In this case, when an unrecoverable error occurs, the error number corresponding to the type of the unrecoverable error that has occurred is stored in the error number storage area (_NB_ERROR) of the RWM53.

Specifically, when an "E1" error occurs, the error number "25 (H)" of the "E1" error is stored in the error number storage area (_NB_ERROR) of the RWM53.
Further, in step S1439 of the LED display control of FIG. 134, the error number “25 (H)” is acquired from the error number storage area (_NB_ERROR) and stored in the B register.
Furthermore, in step S1448 of FIG. 134, it is determined that an error is displayed (“Yes”) because the B register value is not “0”, and in the next step S1449, the B register value is set in the A register. The start address of the LED segment table 1 is set in the HL register.

Further, in step S1450 of FIG. 134, the operation of dividing the A register value “25 (H)” (“37 (D)”) by “10 (D)” is executed, and the quotient “3 (D)” is ranked higher. The digit offset value is stored in the A register, and the remainder "7 (D)" is stored in the C register as the lower digit offset value.
Then, in the interrupt processing when the LED display counter value is "00100000 (B)", in step S1455 of FIG. 134, the offset value "3 (D)" for the upper digit is added to the start address of the LED segment table 1 of FIG. 224. By adding, "E" display data (address "1814 (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, "E" is displayed on the digit 3 (upper digit of the acquired number display LED 78).

Further, in the interrupt processing when the LED display counter value is "01000000 (B)", in step S1455 of FIG. 134, the offset value "7 (D)" for lower digits is added to the start address of the LED segment table 1 of FIG. 224. By adding, "1" display data (address "1818 (H)" in FIG. 224) is acquired as segment output data. Then, in step S1458, "1" is displayed on the digit 4 (lower digit of the acquired number display LED 78).
In this way, when an "E1" error occurs, "E1" can be displayed on the acquired number display LED 78 by interrupt processing. The same applies to other unrecoverable errors.

(32) In the 28th embodiment, "88" is displayed on the acquired number display LED 78 (digits 3 and 4) while the setting is being changed.
However, the present invention is not limited to this, and for example, “88” may be displayed on the stored number display LEDs 76 (digits 1 and 2) in addition to the acquired number display LED 78 while the setting is being changed. That is, "8888" may be displayed on the stored number display LED 76 and the acquired number display LEDs 78 (digits 1 to 4) while the setting is being changed.

Specifically, for example, in the setting change process (M_RANK_SET), the acquired number data storage area (_NB_PAYOUT) and the stored number data storage area (_NB_CREDIT) of the RWM53 are set to "88 (D)" (binary number "01011000 (2)", respectively. B) ”) is memorized.
Further, during the setting change, "11111000 (B)" is stored as the LED display request flag in the LED display request flag storage area (_FL_LED_DSP) of the RWM53.
Then, "8888" is displayed on the stored number display LED 76 and the acquired number display LEDs 78 (digits 1 to 4) by the interrupt processing executed after these processes.

Further, for example, the stored number display LED76 and the acquired number display LED78 (digits 1 to 4) are dynamically lit, and the set value display LED73 (digit 5) is statically lit. Then, during the setting change, "01111000 (B)" is output as a digit signal from the output port 2 and "01111111 (B)" is output as a segment signal from the output port 3 for each interrupt process. As a result, "8" can be displayed on digits 1 to 4 at the same time for each interrupt process while the setting is being changed.
In the setting change process (M_RANK_SET), the output port 2 may output "01111000 (B)" as a digit signal, and the output port 3 may output "01111111 (B)" as a segment signal. ..

(33) In the 29th embodiment, when the operation of the setting switch 13 is detected in step S2140 of FIG. 234, the set value data (value of the set value data storage area (_NB_RANK)) is updated in step S2141, and in step S4103. , The set value display data was generated from the set value data after the update, and this was stored in the acquired number data storage area (_NB_PAYOUT). However, it is not limited to this.

FIG. 242 is a flowchart showing the setting change process (M_RANK_SET) in the modified example of the 29th embodiment, and is a flowchart corresponding to FIG. 234 of the 29th embodiment.
In the flowchart described below, the steps for executing the same processing as those in the 29th embodiment are designated by the same step numbers, and duplicate description will be omitted. Further, steps having contents different from those of the 29th embodiment are underlined in step numbers.

First, in FIG. 242, step S4121 is provided instead of steps S2141 and S4103 in FIG. 234. In this step S4121, the set value display data (value of the acquired number data storage area (_NB_PAYOUT)) is updated.
For example, if the operation of the setting switch 13 is detected in step S2140 while the set value display data "1" is stored in the acquired number data storage area (_NB_PAYOUT), in step S4121, the acquired number data storage area ( _NB_PAYOUT) stores the set value display data "2".
Further, if the operation of the setting switch 13 is detected in step S2140 while the set value display data "6" is stored in the acquired number data storage area (_NB_PAYOUT), in step S4121, the acquired number data storage area ( _NB_PAYOUT) stores the set value display data "1". Then, the process proceeds to the next step S2142.

Further, in FIG. 242, step S4122 is newly provided between step S2142 and step S2143. In this step S4122, the set value data (value of the set value data storage area (_NB_RANK)) is updated.
For example, if the operation of the start switch 41 is detected in step S2142 when the set value display data "1" is stored in the acquired number data storage area (_NB_PAYOUT), the set value display data "1" is detected in step S4122. "0" obtained by subtracting "1" from "" is stored in the set value data storage area (_NB_RANK) as set value data.
Further, if the operation of the start switch 41 is detected in step S2142 when the set value display data "6" is stored in the acquired number data storage area (_NB_PAYOUT), the set value display data "6" is detected in step S4122. "5" obtained by subtracting "1" from "" is stored in the set value data storage area (_NB_RANK) as set value data. Then, the process proceeds to the next step S2143.

(34) In the 28th and 29th embodiments, when the set value is "N", the set value data "N-1" is stored in the set value data storage area (_NB_RANK). However, it is not limited to this.
For example, when the set value is "N", the set value data "N" may be stored in the set value data storage area (_NB_RANK). In this case, the set value display data can be obtained without adding "1" to the set value data. That is, when the set value data is "N", the set value display data is also "N".

(35) In the flowcharts shown in the 28th and 29th embodiments, the order of processing is not limited to the order shown in the figure, and if the order of processing can be changed, the order of processing is changed. Is also possible.
(36) The 28th and 29th embodiments and the various modifications described above are not limited to being carried out alone, but can be carried out in combination as appropriate.

<30th Embodiment>
Subsequently, the thirtieth embodiment will be described.
FIG. 243 is a diagram showing a storage area of the RWM 53 described in the thirtieth embodiment.
In FIG. 243, the advantageous section type flag (_NB_ADV_KND) is a flag indicating whether the current game section is a normal section, a standby section, or an advantageous section. This advantageous section type flag is substantially the same as the game section flag (address “F020 (H)”) shown in FIG. 182 in the 26th embodiment.
In the advantageous section type flag, when it is a normal section, it becomes a value of "00000000 (B)", and when shifting from a normal section to an advantageous section, the D0th bit becomes "1". Further, when shifting from the normal section to the standby section, the D1 bit becomes "1". Furthermore, when shifting from the standby section to the advantageous section, the "1" in the first bit is shifted to the right by one. Further, when shifting from the advantageous section to the normal section, the D0th bit is changed from "1" to "0".
The timing at which the advantageous section type flag is updated will be described later.

The advantageous section clear counter (_CT_ADV_CLR) is "0" during the normal section and the standby section (details will be described later, but it will be "FFFF (H)" for a moment), and the section shifts to the advantageous section. At that time, "1500 (D)" is set as the initial value (specific value). Further, the advantageous section flag counter is set so that "1" is subtracted per game not only during the advantageous section but also during the normal section or the standby section. However, the minimum value is "0". Therefore, in the normal section or the standby section, when the advantageous section clear counter (before subtraction) is "0", subtracting "1" causes a carry (although it becomes "FFFF (H)"). , If a carry occurs, set it to "0". Therefore, during the normal section and the standby 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 or a standby section (non-advantageous section).
In addition, during the advantageous section, "1" is subtracted per game. For example, when "1500 (D)" is set as the initial value (specific value) as described above, the advantageous section clear counter becomes "1499 (D)" in the next game.
Since the advantageous section clear counter stores the initial value "1500 (D)" at the maximum, it is composed of 2 bytes. In other words, when a value other than "0" is stored in the advantageous section clear counter, it is an advantageous section.

The maximum payout notification flag (_FL_ADV_ORD) is "0" during the normal section and the standby section. Then, after shifting to the advantageous section, when the push order bell that can obtain the maximum number of payouts is first won in the slot machine (when the instruction function is activated so that the maximum number of payouts can be obtained (correct answer push order is displayed). When)) is "00000001 (B)".
Here, taking the first embodiment as an example, the push order bells that can obtain the maximum number of payouts in the first embodiment are the push order bells that can be obtained when the small winning combination B is won (see FIGS. 14 and 15; 9 in the correct push order). Payout.). Therefore, when the small winning combination B is won and the instruction function is activated after shifting to the advantageous section, the maximum payout notification flag is updated to "1" at a predetermined timing.

Therefore, for example, when the small winning combination C is won in the first embodiment (in the correct answer pressing order, the number of payouts is 3), it does not correspond to the "maximum payout" here. Further, for example, even if an advantageous push order is displayed at the time of winning a duplicate replay, it does not correspond to the "maximum payout" here. Furthermore, for example, in the first embodiment, the small winning combination F (paying out 10 cards) and the small winning combination G (paying out 9 cards) are won, and the effect suggesting the winning of the small winning combination F and the winning of the small winning combination G, respectively. Even if it is output, it does not correspond to the "maximum payout" here.

This maximum payout notification flag is
a) Winning a condition device having an advantageous operation mode of the stop switch 42,
b) The winning condition device is a condition device having the largest number of payouts when the stop switch 42 is operated in an advantageous operation mode among the condition devices having an advantageous operation mode.
c) When activating the instruction function, such as during AT (when displaying push order instruction information)
The first game of is one of the conditions for updating from "0" to "1".

Further, the maximum payout notification flag may be set to "1" even when the advantageous operation mode that results in the maximum payout is not displayed.
Examples of this include:
a) Win a special role that does not have a setting difference (including duplicate winning of a special role and another small role or replay), and based on the winning of that special role (the special role wins from the time the special role is won) If you want to move to an advantageous section (until you win the special role), after you win the special role, you will win the special role at the specified timing (when you win the special role, from the time you win the special role until the special role wins). At the time, at the start of the special game, during the special game, at the end of the special game, etc.), the maximum payout notification flag is updated to "1". That is, when shifting to the advantageous section based on the winning of the special combination, the maximum payout notification flag is updated to "1" based on the winning of the special combination.
b) After winning a rare small combination (for example, small combination D and small combination E1 in the first embodiment) and shifting to an advantageous section, a special combination (a special combination with a setting difference or no setting difference) When the player wins (regardless of whether it is a special role), the maximum payout notification flag is updated to "1" thereafter.
In the case of a) or b) above, the timing at which the maximum payout notification flag becomes "1" is set at the time of winning a special combination in the thirtieth embodiment. However, the present invention is not limited to this, for example, at the time of winning the special role, at the predetermined timing between the time of winning the special role and the time of winning, during the special game, at the end of the special game, or at the predetermined timing after the end of the special game. You may.

The maximum payout notification flag is a flag that is referred to when determining whether or not it is possible to end the advantageous section. When the maximum payout notification flag is "1", it is possible to end the advantageous section. Therefore, after shifting to the advantageous section, the instruction function is activated at the time of winning the small winning combination B, which is the maximum payout, and when the maximum payout notification flag becomes "1", the advantageous section can be terminated.
Further, as described above, when the maximum payout notification flag becomes "1" based on the winning of the special combination, it is possible to end the advantageous section without activating the instruction function even once. ..

When the maximum payout notification flag is "0", in principle, the advantageous section cannot be ended. After shifting to the advantageous section, the maximum payout notification flag is waited to be updated to "1", and then the advantageous section is terminated.
However, when the maximum payout notification flag remains "0" and the maximum number of games of "1500" in the advantageous section is reached, that is, during the advantageous section of 1500 games, the small winning combination B is won once. If not, even if the maximum payout notification flag is "0", the upper limit number of games of the advantageous section "1500" can be prioritized and the advantageous section can be ended.
Further, when the maximum payout notification flag becomes "1" after shifting to the advantageous section, it is updated to "0" at the end of the advantageous section (based on the end of the advantageous section). In the present embodiment, the timing from "1" to "0" is the initial RWM of step S2746 during the advantageous section setting (M_ADV_SET; FIG. 246) in step S2724 in the game start set (MS_GAME_SET; FIG. 245) described later. (M_RWM_CLEAR; Fig. 248) (these processes will be described later). Not limited to this, the maximum payout notification flag may be updated to "0" in the game end check process (M_GAME_CHK) (described later) or the like executed in the last game of the advantageous section.

The advantageous section display LED flag is a flag that becomes "0" when it is a normal section or a standby section (that is, when it is not an advantageous section) and "1" when it is an advantageous section. Then, when the advantageous section display LED flag is "1", the advantageous section display LED 77 is turned on, and when the advantageous section display LED flag is "0", the advantageous section display LED 77 is turned off.
Here, in the thirtieth embodiment, as shown in FIG. 142 (22nd embodiment), the advantageous section display LED 77 starts from the segment 1P (decimal point (DP)) of the digit 4a (lower digit of the acquired number display LED 78). It shall be configured.
Shifting to the advantageous section and changing the advantageous section display LED flag from "0" to "1" is performed by setting the advantageous section (M_ADV_SET) in the game start set (MS_GAME_SET). Also, ending the advantageous section and changing the advantageous section display LED flag from "1" to "0" is performed by RWM initialization (M_RWM_SET) during the advantageous section setting (M_ADV_SET) in the game start set (MS_GAME_SET). .. Details of these processes will be described later.

The AT game count counter (_CT_ART) is a decrement counter that counts the number of games played at AT (including ART), and is similar to the AT counter of the third embodiment (for example, FIG. 43).
In addition, unlike the advantageous section clear counter, when it becomes "0", the counting (subtraction) after that is stopped.
The AT game count counter is updated (subtracted) during AT immediately after the start switch 41 is operated during the main process (step S2702 in FIG. 244, which will be described later).

Further, in the present embodiment, the initial value of the number of AT games may exceed "255 (D)", so a 2-byte counter is used. When the maximum number of AT games is "255 (D)" or less, a 1-byte counter may be used.
When starting AT (or when shifting to AT preparation), the initial value is set in the AT game count counter. The initial value may be a constant value, or may be determined by lottery or the like when the AT is won. Further, after the initial value is determined, the number of AT games may be updated to "0" without being changed thereafter. Alternatively, when it is decided to add the number of AT games during AT (when winning in the additional lottery, etc.), the number of AT games may be increased. In this case, the increase is added to the AT game count counter.

Further, in FIG. 243, the addresses of the respective data are not shown, but when they are arranged at consecutive addresses, for example,
F020 (H): Advantageous section type flags F021 (H) and F022 (H): Advantageous section clear counter F023 (H): Maximum payout notification flag F024 (H): Advantageous section display LED flags F025 (H) and F026 (H) ): Arranged in the storage area of the RWM53 like the AT game count counter.
Also, some or all of the addresses do not have to be continuous. for example,
F020 (H): Advantageous section type flags F021 (H) and F022 (H): Advantageous section clear counter F030 (H): Maximum payout notification flag F031 (H): Advantageous section display LED flags F032 (H) and F033 (H) ): It may be arranged like an AT game count counter.
However, in the case of a storage area composed of 2 bytes such as an advantageous section clear counter and an AT game count counter, the upper digit storage area and the lower digit storage area are continuous for convenience of calculation. It is preferably an address.

FIG. 244 is a flowchart showing the main process in the thirtieth embodiment, and is a flowchart corresponding to the twenty-sixth embodiment shown in FIG. 188. In FIG. 244, the same processes as those in FIG. 188 are given the same step numbers, different or added processes are given different step numbers, and the step numbers are underlined.
In FIG. 244, the game start set (M_GAME_SET) in step S2701 is a process corresponding to step S2172 in FIG. 188 (26th embodiment). In the game start set, at the end of the advantageous section, clear processing of data related to the advantageous section (data shown in FIG. 243) and the like are executed. This process will be described later.

Further, after receiving the start switch in step S2179, the process proceeds to step S2702 to update the AT game count counter. This process is a process of subtracting "1" from the above-mentioned AT game count counter during AT. Therefore, this process is not executed in the normal section, the waiting section, and the advantageous section during non-AT.
Further, whether or not to add the number of AT games during AT is determined based on the result of the winning combination lottery by the winning combination lottery process in step S2180. For example, when a rare role is won, the number of additional games of AT is determined. Therefore, when the number of AT games is added and the added amount is added to the number of AT games counter, it is executed after the processing of step S2180 (not shown in FIG. 244).
In the present embodiment, after the start switch is accepted (step S2179), the AT game count counter is updated in step S2702, but the present invention is not limited to this, and may be performed after the winning combination lottery process in step S2180.

Further, after the winning combination lottery process in step S2180, the process proceeds to step S2703 to update the advantageous section type. This process is the process shown in FIG. 249, which will be described later, and is the process of updating the value of the above-mentioned advantageous section type flag according to any one of the normal section, the standby section, and the advantageous section.
Next, the process proceeds to step S2704, and the push order instruction number set (M_ORD_INF) is performed. This process corresponds to the push order instruction number set of the 28th embodiment shown in FIG. 228. This process will be described later with reference to FIG. 250. The push order instruction number set is a process of generating push order instruction data and displaying the push order when the instruction function is activated in the game. Further, in the thirtieth embodiment, the maximum payout notification flag described above may be updated during this process.

The game end check process (M_GAME_CHK) in step S2705 is a process corresponding to step S2196 in the 26th embodiment shown in FIG. 188. In the thirtieth embodiment, in the game end check process, it is determined whether or not to end the advantageous section, and when the advantageous section is ended, the end preparation of the advantageous section is performed. Details of this process will be described later (FIGS. 252 and 253).

FIG. 245 is a flowchart showing the game start set (M_GAME_SET) in step S2701 in FIG. 244.
It should be noted that 1BB in the thirtieth embodiment is a special role having no setting difference. In addition, when 1BB is won, it is assumed that after the end of the 1BB game, the section shifts to the advantageous section. That is, at the same time as winning 1BB, it is assumed that the advantageous section is also won.

First, in step S2711, the game standby display time is set (stored in a predetermined storage area (not shown) of the RWM 53). In the present embodiment, the game standby display time is set to "26846" interrupt (≈60,000 ms, that is, about 60 seconds (1 minute)). When the game standby display time is set in step S2701, the value is subtracted by "1" for each interrupt process from this point.

When the game waiting display time becomes "0", the acquired number of sheets data is cleared in step S2175 (waiting for medal insertion) in FIG. 244. This process is a process of clearing the storage area (_NB_PAYOUT) of the acquired number data of the address “F011 (H)” shown in FIG. 222 (28th embodiment).
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 "9" and the player pays by operating the checkout switch 46 and finishes the game, "00" is displayed after about 1 minute. Will be done. This has the effect that the vacant table can be reduced because the clerk in the hall or another player can recognize it as a vacant table.
The acquisition number display LED 78 is not limited to displaying "00", and the acquisition number display LED 78 (upper digit and lower digit) may be turned off, or the upper digit of the acquisition number display LED 78 is turned off and the lower digit is turned off. May display "0". In any case, it suffices if the display is executed so that the clerk in the hall or another player can recognize it as a vacant table.

Next, the process proceeds to step S2712, and the push order instruction number initialization process is executed. This process is a process of clearing the storage area of the push order instruction number stored in the address of the RWM 53.
In the next step S2713, the data of the symbol combination display flag is acquired. This process acquires the symbol combination (data of the symbol combination display flag (not shown) provided on the RWM 53) on the effective line after the reel 31 is stopped in the previous game.

In the next step S2714, it is determined whether or not the 1BB operation symbol is displayed. In this process, among the data of the symbol combination display flag, when the bit corresponding to 1BB 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 symbol is displayed, the process proceeds to step S2715, and when it is determined that the 1BB operation symbol is not displayed, the process proceeds to step S2719.
It should be noted that each bit of the symbol combination display flag and each bit of the operation state flag are set so as to correspond to each other. Therefore, as shown in FIG. 182 (26th embodiment), since the D2 bit of the operating state flag of the address “F010 (H)” is the bit corresponding to 1BB, the bit corresponding to 1BB of the symbol combination display flag. Also, it is assumed that the D2 bit is used.

In step S2715, it is determined whether or not the waiting section is in progress. In this determination, the value of the advantageous section type flag is determined in FIG. 243, and when the D1 bit is "1", it is determined that the interval is a standby section. When it is determined that the section is in the waiting section, the process proceeds to step S2716, and when it is determined that the section is not in the waiting section, the process proceeds to step S2718.
In step S2716, the bit of the advantageous section type flag is shifted to the right by "1". That is,
Before shift: 000000010 (B)
After shift: 00000001 (B)
Will be.
As a result, the advantageous section type flag is updated from the value indicating the waiting section to the value indicating the advantageous section.

Next, the process proceeds to step S2717, and "1" is stored (stored) in the maximum payout notification flag. That is,
Before saving (memory): 00000000 (B)
After saving (memory): 00000001 (B)
Will be.
As a result, as shown in FIG. 243, the value of the maximum payout notification flag changes from the non-notification state to another.
When the maximum payout notification flag is already "1" and the process proceeds to set the maximum payout notification flag to "1" (for example, when the process proceeds to step S2812 of FIG. 251 described later), the maximum payout notification is notified. The flag is overwritten with "1".
In steps S2716 and S2717 described above, the advantageous section type flag is updated (updated from the standby section to the advantageous section) and the maximum payout notification flag is updated (updated from not notified to others) based on the winning of 1BB.

In step S2718, the number of sheets that can be acquired when 1BB is operated (during 1BB game) is saved. This process is a process of storing the maximum number of sheets that can be acquired in the 1BB game in the predetermined storage area of the RWM 53. Then, the process proceeds to step S2719.
In the next step S2719, the operating state flag (_FL_ACTION) is generated. This operating state flag is the same as that shown in the 26th embodiment (address "F010 (H)") of FIG. 182. In this step S2719, the value of the operating state flag is generated based on the symbol combination display flag.
Further, in the next step S2720, the operating state flag is saved (stored). This process is a process of storing the generated operating state flag (at this time, for example, stored in the A register) at the above address "F010 (H)" of the RWM53. 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 S2720.
For example, when a combination of 1BB symbols is displayed (at the time of winning 1BB), the D2 bit corresponding to 1BB of the operating state flag changes from "0" to "1".

In the next step S2722, 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 two games (or when winning twice), but when the end condition of the 1BB game is not satisfied ( (When the D2 bit corresponding to 1BB of the operating state flag is "1") is set to "1" in this game start set. If it is determined in step S2715 that the RB is in operation, the process proceeds to step S2723, and if it is determined that the RB is not in operation, the process proceeds to step S2724.

In the next step S2723, the number of games played and the number of winnings when the RB is activated are saved. In this process, "2 (H)" is stored (stored) in the storage area (not shown) of the game count counter when the RB is operated, which is provided in the RWM53, and when the RB is operated, which is provided in the RWM53. This is a process of storing (storing) "2 (H)" in the storage area (not shown) of the winning count counter. Then, the process proceeds to step S2724.

Both the game count counter during RB operation and the winning count counter during RB operation are set to "2 (H)" as initial values, and each time the number of games or the number of winnings increases by "1", respectively. It is a counter that is decremented by "1". However, not limited to this, the initial values of these counter values are set to "0", and each time the number of games or the number of winnings increases by "1", the counter values are incremented by "1", and these counter values become "2 ( It may be determined whether or not "H)" has been reached.

In the next step S2724, the advantageous section setting (M_ADV_SET) is performed. This process is the process shown in FIG. 246, which will be described later, and updates the advantageous section clear counter and the like.
Here, the advantageous section clear counter is a counter in which "1" is subtracted for each game not only in the advantageous section but also in all the game sections (normal section, standby section, and all advantageous sections). In this respect, it differs from the counter that counts only during the advantageous section, such as the advantageous section counter shown in the third embodiment of FIG.
In step S501 shown in FIG. 46 (e), the advantageous section counter value is updated (“1” is added), but since this process is executed only during the advantageous section, before this process, It is necessary to judge whether or not the game is an advantageous section this time. However, in the present embodiment, the advantageous section clear counter is subtracted by "1" for each game without determining whether or not it is an advantageous section, so that the processing can be simplified accordingly. As a result, the program capacity can be reduced (the storage capacity of the ROM 54 can be reduced).
Then, even if the value of the advantageous section clear counter is subtracted by "1" for each game in any game section, the value of the advantageous section clear counter is "0" if it is a normal section and a standby section. It becomes.
When the start condition of the advantageous section is satisfied, the value of the advantageous section clear counter is set to "1500 (D)", and if the value is other than "0", the value of each game and the previous game is changed to "1". It is updated to the subtracted value.
Then, when it becomes "0" by subtracting "1", it can be determined that the end condition of the advantageous section is satisfied.
In addition, when there is a carry down by subtracting "1", it can be determined that the previous game is a normal section or a waiting section.
In this way, program processing can be reduced (simplified).

In the next step S2725, it is determined whether or not the combination of symbols of the replay is displayed (whether the replay has won a prize) based on the data of the symbol combination display flag acquired in step S2713. When it is determined that the combination of the symbols of the replay is displayed, the process proceeds to step S2716, and when it is determined that the combination of the symbols of the replay is not displayed, the process proceeds to step S2728.

In step S2726, the main control board 50 reads the bet medal. This process is a process of reading the number of medals bet in the previous game. Next, the process proceeds to step S2727, and the automatic bet number data is set. This process is a process of updating the data in the storage area of the number of automatic bets provided in the RWM 53 (memorizing "3 (H)").
Next, the process proceeds to step S2728 to set the output request of the operating state. In the next step S2729, the control command set 1 is executed. Specifically, information indicating that the replay has been activated, that 1BB has been activated, or the like is transmitted to the sub-control board 80. Then, the process according to this flowchart is completed.

FIG. 246 is a flowchart showing the advantageous section setting (M_ADV_SET) in step S2724 in FIG. 245.
First, in the advantageous section clear counter RWM address set in step S2741, the address of the advantageous section clear counter shown in FIG. 243 is stored. Here, the advantageous section clear counter is composed of 2 bytes and stores the data of the lower byte. Therefore, when the address of the advantageous section clear counter is, for example, the above-mentioned "F021 (H)" and "F022 (H)", the address of the lower byte (F021 (H)) is specified. Then, the low-order byte data is stored in the HL register.

Next, the process proceeds to step S2742, and a 2-byte countdown (M_W_CNT_DOWN) is executed. Here, the process of subtracting "1" from the value of the advantageous section clear counter is executed. The details will be described later (FIG. 247).
In this 2-byte countdown, when the calculation result becomes "0" (that is, when the value before the calculation is "1"), the zero flag becomes "1".
Further, in the 2-byte countdown, when a carry occurs as a result of the calculation (that is, when the value before the calculation is "0"), the carry flag becomes "1".

Here, the zero flag and the carry flag will be described.
An F (flag) register is provided as one of the registers (A register, H register, etc.) used in this embodiment. The F register, like the other registers, is composed of D0 to D7 bits. A carry flag is assigned to the D0 bit, and a zero flag is assigned to the D6 bit.
The carry flag executes arithmetic processing (for example, addition processing, subtraction processing, logical product operation processing, OR operation processing, exclusive OR, etc. The same applies hereinafter), and digit overflow or carry occurs depending on the operation result. Sometimes it becomes "1". On the other hand, when the arithmetic processing is executed and no overflow or carry occurs due to the arithmetic result, the value becomes "0".
Further, the zero flag becomes "1" when the calculation process is executed and the calculation result becomes "0". On the other hand, when the arithmetic processing is executed and the arithmetic result is not "0", it becomes "0".

Next, the process proceeds to step S2743, and it is determined whether or not the advantageous section clear counter before the calculation is “0”. This judgment is made when the above-mentioned carry flag becomes "1" after the 2-byte countdown calculation, it is determined that the advantageous section clear counter before the calculation is "0", and the carry flag is not "1". Determines that the advantageous section clear counter before the calculation is not "0".
When it is determined that the advantageous section clear counter before the calculation is "0", the process proceeds to step S2747, and when it is determined that the counter is not "0", the process proceeds to step S2744. Here, "the advantageous section clear counter before calculation is" 0 "" indicates that the previous game is a normal section or a standby section (non-advantageous section).

In step S2744, it is determined whether or not the advantageous section clear counter after the 2-byte countdown calculation is "0". In this judgment, when the above-mentioned zero flag becomes "1" after the calculation, it is determined that the advantageous section clear counter after the calculation is "0", and when the zero flag is not "1", the advantage after the calculation is performed. It is determined that the section clear counter is not "0". Here, "the advantageous section clear counter after calculation is not" 0 "" indicates that the previous game and the current game are advantageous sections.
When it is determined that the advantageous section clear counter after the calculation is "0", the process proceeds to step S2745, and when it is determined that the counter is not "0", the process according to this flowchart is terminated. Here, "the advantageous section clear counter after calculation is" 0 "" means that the previous game was an advantageous section, but this time the game is a normal section (non-advantageous section) (from the advantageous section to the normal section). (Migrate).
In step S2745, the number of RWM initialization bytes is set. In this process, the total value of the number of initialization bytes is stored in the B register. For example, when the number of initialization bytes is 20 (H), "20 (H)" is set in the B register value.

Next, the process proceeds to step S2746, and RWM initialization (M_RWM_CLEAR) is executed. Since this initialization is a process performed when the advantageous section clear counter value becomes "0" after subtracting "1" (that is, when the end condition of the advantageous section is satisfied), the data of the storage area relating to the advantageous section is performed. Is the process of initializing (clearing). Therefore, for example, the data (counter, flag, etc.) shown in FIG. 243 is cleared. RWM initialization will be described later (Fig. 248).

Next, the process proceeds to step S2747, and it is determined whether or not the advantageous section type flag is "1". This process determines whether or not the D0 bit of the advantageous section type flag is "1", determines "Yes" if it is "1", and determines "No" if it is not "1". .. That is, this process determines whether or not the transition condition from the normal section or the waiting section (non-advantageous section) to the advantageous section is satisfied.
When it is determined that the game section type flag is "1" (satisfying the transition condition to the advantageous section), the process proceeds to step S2748, and it is not "1" (the transition condition to the advantageous section is not satisfied). When it is determined, the process according to this flowchart is terminated.

In step S2748, the initial value is stored (stored) in the advantageous section clear counter. The initial value of this embodiment is set to "1500 (D)". Therefore, "DC (H)" is stored in the address indicated by the HL register value, and "5 (H)" is stored in the address indicated by the value obtained by adding "1" to the HL register value. Since "F021 (H)" is stored in the HL register in step S2741 described above, the HL register value indicates the address of the lower bit of the advantageous section clear counter at the time of step S2748.
therefore,
F021 (H) (advantageous section clear counter lower byte): DC (H)
F022 (H) (advantageous section clear counter upper byte): 5 (H)
Will be.
In addition, "5DC (H)" = "1500 (D)".

Next, the process proceeds to step S2749, and "1" is stored (stored) in the advantageous section display LED flag. Then, the process according to this flowchart is completed. When "1" is stored in the advantageous section display LED flag in step S2749, the advantageous section display LED 77 is turned on when the digit 4a is turned on in the interrupt processing executed thereafter.
Here, the LED display control for lighting the advantageous section display LED 77 will be described. The LED display control of the thirtieth embodiment can be described by using the LED display control (I_LED_OUT) of FIG. 149 (22nd embodiment).

In FIG. 149, when the interrupt process corresponds to the interrupt “2” in FIG. 148 (A), the lighting timing of the advantageous section display LED 77 is set. Therefore, even if the advantageous section display LED flag is "1", the lighting process of the advantageous section display LED 77 is actually executed only when the interrupt is "2" due to the dynamic lighting, and the interrupts "1" and "3" are executed. In the case of "5", step S1552 is not executed in FIG. 149.

In the thirtieth embodiment, when the process proceeds to step S1552 in FIG. 149, it is referred to whether or not the value of the advantageous section display LED flag is “1”. Then, when it is determined that the advantageous section display LED flag is "1", it is determined whether or not the digit lit by the interrupt processing this time is digit 4. When the LED display counter value is "00001000 (B)", it is determined that the digit 4 is lit. In this case (when the advantageous section display LED flag is "1" and the digit 4 is lit), the segment 1 data set in step S1551 and the data obtained by ORing "10000000 (B)" are output. Set as segment 1 data for port 3. As a result, data that can light the segment 1P of the digit 4a (that is, the advantageous section display LED 77) is set.
On the other hand, when it is determined that the advantageous section display LED flag is not "1", the above-mentioned OR calculation is not executed, or the segment 1 data set in step S1551 and "00000000000 (B)" are OR-calculated. The data is set as segment 1 data for the output port 3.

FIG. 247 is a flowchart showing a 2-byte countdown (M_W_CNT_DOWN) in step S2742 in FIG. 246.
In the 2-byte countdown, the 2-byte data subtraction in step S2761 is executed. This process is executed as follows.
When the process proceeds to step S2761, as described above, in step S2741 of FIG. 246, the lower digit address of the advantageous section clear counter is stored in the HL register. Therefore, the value stored in the address indicated by the HL register value is the lower digit data of the advantageous interval clear counter. Further, the value stored in the address indicated by the value obtained by adding "1" to the HL register value is the data of the upper digit of the advantageous section clear counter.
Then, when the carry flag becomes "1" as a result of subtracting "1" (Example 4 described later), "0" is stored in the address indicated by the HL register value, and "1" is stored in the HL register value. "0" is stored in the address indicated by the value obtained by adding "". That is, "0" is stored in the upper byte of the advantageous section clear counter, and "0" is stored in the lower byte.

Specific examples are as follows.
(Example 1)
Data stored in the address of HL register value + 1 (upper digit): 05 (H)
Data stored in the address of the HL register value (lower digit): DC (H)
When, when "1" is subtracted,
Data stored in the address of HL register value + 1 (upper digit): 05 (H)
Data stored in the address of the HL register value (lower digit): DB (H)
Then, the carry flag = "0" and the zero flag = "0".
(Example 2)
Data stored in the address of HL register value + 1 (upper digit): 01 (H)
Data stored in the address of the HL register value (lower digit): 00 (H)
When, when "1" is subtracted,
Data stored in the address of HL register value + 1 (upper digit): 00 (H)
Data stored in the address of the HL register value (lower digit): FF (H)
Then, the carry flag = "0" and the zero flag = "0".

(Example 3)
Data stored in the address of HL register value + 1 (upper digit): 00 (H)
Data stored in the address of the HL register value (lower digit): 01 (H)
When, when "1" is subtracted,
Data stored in the address of HL register value + 1 (upper digit): 00 (H)
Data stored in the address of the HL register value (lower digit): 00 (H)
Then, the carry flag = "0" and the zero flag = "1".
(Example 4)
Data stored in the address of HL register value + 1 (upper digit): 00 (H)
Data stored in the address of the HL register value (lower digit): 00 (H)
When, when "1" is subtracted,
Data stored in the address of HL register value + 1 (upper digit): 00 (H)
Data stored in the address of the HL register value (lower digit): 00 (H)
Then, the carry flag = "1" and the zero flag = "0".

In this example 4, when "1" is actually subtracted, a carry occurs at that point (the upper digit "FF (H)" and the lower digit "FF (H)"), but as described above, "0" is stored in the address indicated by the HL register value, and "0" is stored in the address indicated by the value obtained by adding "1" to the HL register value. As a result, both the data stored in the address indicated by the HL register value (lower digit) and the data stored in the address indicated by the value obtained by adding "1" to the HL register value (upper digit) are "0". It becomes.

FIG. 248 is a flowchart showing RWM initialization (M_RWM_CLEAR) in step S2746 in FIG. 246.
Before this RWM initialization is executed, the number of initialization bytes is stored in the B register in step S2745 of FIG. 246. In the above example, "20 (H)" is set in the B register value. Further, in step S2741 of FIG. 246, the address of the lower byte of the advantageous section clear counter is stored in the HL register. In the above example, "F021 (H)" is stored in the HL register.
In FIG. 248, in step S2771, the RWM initialization data is set. In this process, the A register value and the A register value are XOR-operated, and the operation result is stored in the A register. By this operation, the A register value becomes "0 (H)".

Next, the process proceeds to step S2772, and the RWM is initialized. This process is a process of storing the A register value (that is, "0 (H)") at the address indicated by the HL register value. By this process, the data of "F021 (H)" to be initialized first becomes "0".
Next, the process proceeds to step S2773 to change the RWM initialization address. This process is a process of adding "1" to the HL register value.
In the next step S2774, it is determined whether or not the initialization of the RWM has been completed. This process subtracts "1" from the B register value, determines whether or not the subtracted B register value is "0", and ends RWM initialization when it is determined to be "0". Then judge.
When it is determined that the initialization of the RWM is finished, the process according to this flowchart is finished. When it is determined that the initialization of the RWM is not completed (B register value ≠ “0”), the process returns to step S2772 and the initialization is continued.

According to the above flowchart, the number of bytes corresponding to the number set in the B register is initialized. In addition, the initialization is executed in the order of addresses. Therefore, if the RWM addresses to be initialized at the end of the advantageous section are arranged consecutively, the smallest address is specified first, and the number of bytes to be initialized is set in the B register, the initial address is set at the end of the advantageous section. You can initialize all the data that needs to be converted.
Here, all of the five data shown in FIG. 243 are the data to be initialized by the RWM initialization.
On the other hand, regardless of whether or not the advantageous section has ended, data that is continuously used in the next game after the end of the advantageous section, for example, set value information (“F000 (H)” in the example of FIG. 182), RT The status number, the number of stored sheets data, the LED display counter (“F018 (H)” in the example of FIG. 182), and the like are not the targets of initialization.
Further, the data to be initialized by the RWM initialization is limited to the data in the used area shown in the 20th embodiment and the 26th embodiment, and the data outside the used area is not the object of initialization.

In the example of RWM initialization in FIG. 248, the addresses of the data relating to the advantageous section to be initialized are continuously arranged at the end of the advantageous section, and the addresses to be initialized are updated by "1" in step S2773. I made it. However, not limited to this, even if the addresses of the data to be initialized are not continuous, by building a program that can individually specify the addresses of the data to be initialized, the advantageous section to be initialized is related. The data can be initialized.

FIG. 249 is a flowchart showing the advantageous section type update in step S2703 in FIG. 244.
First, in step S2781, it is determined whether or not the advantageous section has been won. The winning of the advantageous section may be any of the above-described embodiments. For example, taking the first embodiment as an example, as shown in FIG. 17, there is a case where a specific condition device is won and an advantageous section is won at the same time. Alternatively, in addition to the lottery of the conditional device (combination), for example, in FIG. 244, the advantageous section lottery may be performed after the combination lottery of step S2180. If the lottery for the advantageous section is based on, for example, the first embodiment, it is a condition that the winning probability does not differ depending on the set value.

When it is determined in step S2781 that the advantageous section has been won, the process proceeds to step S2782, and when it is determined that the advantageous section has not been won, the process according to this flowchart ends.
In step S2782, it is determined whether or not to shift to the standby section. When the advantageous section is won, it can be arbitrarily set whether to shift to the advantageous section or the standby section before the start of the next game. For example, taking FIG. 23 of the first embodiment as an example, when the advantageous section is won based on the winning of the rare role without winning the special role as in “Timing 1” in FIG. 23, the waiting section It is judged that the section will shift to the advantageous section without going through.

On the other hand, as shown in "Timing 2" in FIG. 23, when the special combination (1BBA) is won and the advantageous section is won, it is determined that the section shifts to the waiting section.
When it is determined in step S2782 to shift to the standby section, the process proceeds to step S2783, and when it is determined not to shift to the standby section (shift to the advantageous section), the process proceeds to step S2784.
In step S2783, the advantageous section type flag is updated (stored) to "00000010 (B)". Then, the process according to this flowchart is completed.
On the other hand, in step S2784, the advantageous section type flag is updated (stored) to "00000001 (B)". Then, the process according to this flowchart is completed.

In the above, when the process proceeds to step S2783 and the advantageous section type flag is updated (stored) to "00000010 (B)", as described above when the process proceeds from step S2714 and step S2715 to step S2716 in FIG. 245. The advantageous section type flag is shifted to the right by "1".
According to this step S2716, the advantageous section type flag is set.
Before update: 000000010 (B) (indicates the waiting section)
After update: 00000001 (B) (indicates advantageous section)
Will be.

On the other hand, in the above, when the process proceeds to step S2784 and the advantageous section type flag is updated (stored) to "00000001 (B)", the value of the advantageous section type flag is maintained until the advantageous section ends. ..
Further, when the advantageous section is terminated, if the RWM initialization is executed in step S2746 of FIG. 246 described above, the advantageous section type flag is also initialized at this time. As a result, the advantageous section type flag becomes "00000000000 (B)" and is updated to a value indicating a normal section.

FIG. 250 is a flowchart showing a push order instruction number set (M_ORD_INF) in step S2704 in FIG. 244.
The push order instruction number set is described in FIG. 228 (28th embodiment), but will be described again in the 30th embodiment.
First, in step S2791, it is determined whether or not the operation condition of the instruction function is satisfied in the game. In the present embodiment, it is determined that the operation condition of the instruction function is satisfied when the condition device having an advantageous operation mode of the stop switch 42 is won during AT or the like.
Here, whether or not AT is in progress is determined by reading the value of the AT game count counter, and if it is not "0", it is determined that AT is in progress. Further, as a method of determining whether or not AT is in progress, in addition to determining the value of the AT game count counter, for example, an RWM address for storing the main game state is provided, and the value of the main game state is AT. When the value corresponds to the inside, it may be determined that the AT is in progress.
Further, as in the third embodiment, when "advantageous section = AT", when the advantageous section clear counter is a value other than "0", AT is in progress (satisfying the operation condition of the instruction function). You may judge that.

Furthermore, not only during AT, but also in the advantageous section and before the start of AT (AT precursor, AT preparation, etc.), or in the state where it has not yet been decided to start AT (AT gasse precursor, CZ, etc.). It may be judged that the operation condition of the instruction function is satisfied. For example, there is a case where the maximum payout notification flag is "0" after shifting to the advantageous section. In such a case, the instruction function is activated when the first small winning combination B group is won, and the maximum payout notification flag is set to "1" as soon as possible. This is because, after that, the advantageous section can be ended when the end condition of the advantageous section is satisfied. Therefore, in step S2791, the case where the operation condition of the instruction function is satisfied is
(1) When AT is in progress and a conditional device having an advantageous operation mode of the stop switch 42 is won. (2) When RT is in an advantageous section and RT needs to be promoted (for example, Replay B of the first embodiment). When you win the group)
(3) Small winning combination B when the maximum payout notification flag is "0" in a state where AT has not yet started (AT precursor, AT preparation, AT gasse precursor, CZ, etc.) after shifting to the advantageous section. This is the case when the group is elected.

During AT, even if the maximum payout notification flag is already "1", when the condition device having an advantageous operation mode of the stop switch is won, it is determined that the operation condition of the instruction function is satisfied.
On the other hand, when the maximum payout notification flag is still "0" in the case where the AT is not executed yet (AT precursor, AT preparation, AT gasse precursor, CZ, etc.) although it is an advantageous section. , It is judged that the operation condition of the instruction function is satisfied when the small winning combination B group is won. On the other hand, when the maximum payout notification flag is "1", it is determined that the operating condition of the instruction function is not satisfied even when the small winning combination B group is won.
When it is determined in step S2791 that the condition for activating the instruction function is satisfied, the process proceeds to step S2792, and when it is determined that the condition for activating the instruction function is not satisfied, the process according to this flowchart is terminated.

In step S2792, the condition device number is set. When the winning combination lottery is performed in step S2180 of FIG. 244, the conditional device number won in the game is stored in a predetermined address of the RWM 53. Then, in this step S2792, the value stored in this address is stored in the A register.
In the example of this flowchart, it is assumed that the small winning combination B1 of the condition device number "11" is won in FIG. Therefore, "11 (D)", that is, "B (H)" is stored in the storage area of the condition device number of the RWM53 and the A register.
Next, the process proceeds to step S2793 to update the maximum payout notification flag. This process will be described later.

In the next step S2794, the push order instruction number table is set. Taking the 28th embodiment of FIG. 225 as an example, this process is a process of storing the start address “1900 (H)” of the push order instruction number table in the HL register in FIG. 225.
Next, the process proceeds to step S2795, and the designated address data is set. In step S2795, the 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 of the condition device number stored in the RWM 53 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.
Therefore, since the HL register value at this point is "1900 (H)" as described above, the A register value "B (H)" is added to this value, and a new HL register value "190B (" H) ”.
Then, as shown in FIG. 225, the push order instruction number "A1 (H)" corresponding to the address "190B (H)" of the push order instruction number table is stored in the A register.

Next, the process proceeds to step S2996, and the push order instruction number is stored in the RWM53. That is, the A register value is stored in the storage area of the push order instruction number in the RWM53.
In the next step S2797, the A register value (pushing order instruction number) is stored in the acquired number data storage area. In the example of FIG. 222 (28th embodiment), it is stored in the address “F011 (H)”. Then, the process according to this flowchart is completed.

When the push order instruction number is stored in the storage area of the acquired number data in step S2797, the push order instruction is given to the acquired number display LED 78 at the lighting timing of the digit 3a and the digit 4a in the interrupt process executed after this process. Information is displayed. For example, when the push order instruction number "A1 (H)" is stored as described above, "=" is displayed on the digit 3a during the interrupt processing for lighting the digit 3a, and the interrupt processing for lighting the next digit 4a. Sometimes "1" is displayed on the digit 4a.

On the other hand, when it is determined in step S2791 that the operating condition of the instruction function is not satisfied and the process according to this flowchart is completed, the storage area of the acquired number data is cleared in the game start set in step S2701 in FIG. 244. Therefore, the value of the storage area of the acquired number data remains "0". Therefore, the display of the acquired number display LED 78 (digit 3a and digit 4a) remains “00”.

FIG. 251 is a flowchart showing the update of the maximum payout notification flag in step S2793 in FIG. 250.
First, in step S2811, it is determined whether or not the small winning combination B (any of B1 to B12) has been won in the game. Before proceeding to this process, in step S2792, the condition device number won in the game is stored in the A register, so that the A register value is the condition device numbers "11 (D)" to "22 (D)". ) ”(“ 0B (H) ”to“ 16 (H) ”) is determined. When it is determined that the small winning combination B has been won, the process proceeds to step S2812, and when it is determined that the small winning combination B has not been won, the process according to this flowchart ends.
Proceeding to step S2812, "1" is saved (stored) as the maximum payout notification flag. Then, the process according to this flowchart is completed.

From FIGS. 250 and 251 above, even during AT, the maximum payout notification flag does not become "1" unless the small winning combination B is won. For example, even if the small winning combination C is won during AT and the correct answer pressing order is displayed by the operation of the instruction function, the maximum payout notification flag does not become "1".
In addition, after starting AT, the maximum payout notification flag is set to "1" when the first small winning combination B is won. Therefore, during the AT after that, the maximum payout notification flag "1" may be overwritten each time the small winning combination B is won, or after the maximum payout notification flag is once set to "1", the figure is shown in the figure. In 250, step S2793 may be skipped.
Furthermore, in the thirtieth embodiment, when the small winning combination B is first won during AT, the maximum payout is substantially made before the push order instruction number is stored in the acquired number data (step S2797 in FIG. 250). The notification flag is updated to "1". However, not limited to this, even if the maximum payout notification flag is updated to "1" after the push order instruction number is stored in the acquired number data, that is, after the push order instruction information is substantially displayed. good.

FIG. 252 is a flowchart showing the game end check process (M_GAME_SET) in step S2705 in FIG. 244.
In the various embodiments described above, the type that ends the advantageous section at the same time when the AT ends (for example, the third embodiment) and the end condition of the advantageous section for the advantageous section even when the AT ends. There is a type that does not end the advantageous section unless the above conditions are satisfied (for example, FIG. 61 (fifth embodiment (Example 2) shown in a9)). Suppose it is a thing.
First, in step S2821, it is determined whether or not the number of AT games is "0". This process is performed by determining whether or not the AT game count counter is "0". When it is determined that the number of AT games is "0", the process proceeds to step S2822, and when it is determined that the number of AT games is not "0", the process proceeds to step S2824.

In step S2822, it is determined whether or not the maximum payout notification flag is "1". This is because if the maximum payout notification flag is "1", the advantageous section can be ended, but if it is not "1", the advantageous section cannot be ended (however, there are some exceptions as described later).
In step S2822, when it is determined that the maximum payout notification flag is "1", the process proceeds to step S2823, and when it is determined that the maximum payout notification flag is not "1", the process proceeds to step S2824.
In step S2823, preparation for the end of the advantageous section (M_ADVEND_STNBY) is executed. Details of this process will be described later (FIG. 253).

In step S2824, a process of clearing the flag of the condition device is performed. This process is a process of clearing other than the special combination condition device, and when it is determined that the combination of symbols corresponding to the special combination has stopped at the effective line, the process of clearing the special combination condition device is also executed. In the next step S2825, the replay display LED is turned off. This process corresponds to the process of setting the bit (for example, the D3 bit) corresponding to the replay of the medal management flag stored in the predetermined storage area of the RWM 53 to “0”. Next, the process proceeds to step S2826, and the replay operation flag is cleared. This process, for example, is not shown in the 26th embodiment of FIG. 182, but is a process of setting the bit to "0" when the operating state flag has a bit corresponding to the replay.

In the next step S2827, 1BB operation management is performed. This process is a process of determining whether or not the end condition of the 1BB game is satisfied during the 1BB game. In the next step S2828, it is determined whether or not the RB is in operation. This process determines whether or not the D4 bit is "0" in the operating state flag shown in the 26th embodiment of FIG. 182, and determines that it is not "0" (zero flag ≠ 1) (RB operation). When it is determined that it is time), the process proceeds to step S2829 to execute the RB operation management, and when it is determined that it is “0” (not when the RB is operating), the process according to this flowchart is terminated.

FIG. 253 is a flowchart showing the advantageous section end preparation (M_ADVEND_STNBY) in step S2823 in FIG. 252.
In FIG. 253, in step S2841, "1" is stored in the advantageous section clear counter. This process executes the following process.
(1) “1 (H)” is stored 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 of the advantageous section clear counter, and the H register value "0 (H)" is stored in the upper address.
Then, the process according to this flowchart is completed. From the above, the upper byte of the advantageous section clear counter is "00000000000 (B)", and the lower byte is "00000001 (B)".

Further, the preparation for the end of the advantageous section is executed at the time of the game end check as described above, but when the game return set (FIG. 245) is returned in the main process (FIG. 244), the advantageous section is set in step S2724 (FIG. 245). Is executed. In the advantageous section setting (FIG. 246), “1” is subtracted from the advantageous section clear counter value in steps S2741 and S2742, so that the determination in step S2744 determines “Yes”. As a result, the process proceeds to steps S2745 and S2746, and RWM initialization of the data regarding the advantageous section is executed.

The advantageous section clear counter is set to "1500 (D)" as an initial value (specific value) when shifting to the advantageous section, and then is subtracted by "1" for each game.
Then, in the thirtieth embodiment, since the specification is such that the advantageous section ends at the same time as the end of the AT, the end preparation of the advantageous section is performed when the number of games of the AT becomes "0". For example, when the player shifts to the advantageous section, then shifts to the AT of the "100" game after the "50" game, the count is as follows. The following numerical values are all shown in decimal.
a) Advantageous section clear counter at the time of transition to advantageous section: "1500"
AT game count counter: "0"
b) Advantageous section clear counter at the time of AT transition: "1450"
AT game count counter: "100"
c) At the end of AT AT game count counter: "0"
Advantageous section clear counter: Updated from "1350" to "1" d) At the time of game start set after c) above AT game count counter: "0"
Advantageous section clear counter: "0"

By storing "1" in the advantageous section clear counter by the above preparation for the end of the advantageous section, it is not necessary to store the data indicating whether or not the end condition of the advantageous section is satisfied at 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 the predetermined address of the RWM53, the capacity of the RWM53 will be compressed accordingly.
Further, when the end condition of the advantageous section is satisfied, it is necessary to store the data indicating that the end condition of the advantageous section is satisfied at the predetermined address of the RWM 53. Further, it is necessary to read the data stored in the predetermined address for each game 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 squeezed.
On the other hand, in the present embodiment, only by storing "1" in the advantageous section clear counter in preparation for the end of the advantageous section, the advantageous section clear counter becomes "0" in the advantageous section setting (FIG. 246) executed thereafter. Therefore, the processing at the end of the advantageous section (clearing processing of RWM53) can be executed.

In addition, in FIG. 252, the determination of step S2821 is determined to be "Yes" when the AT game count counter changes from "1" to "0" in the game (step S2702 in FIG. 244). I'm assuming. Therefore, it is possible not to execute the processes of steps S2821 to S2823 in FIG. 252 when the AT is not in the first place.
However, even in the normal section, the process of step S2821 may be executed in each game, in FIG. 252, the process proceeds from step S2821 to step S2822, and if "No" is determined in step S2822, the process may proceed to step S2824.

Further, in the flowchart of FIG. 252, when the maximum payout notification flag remains "0" and the number of games in the advantageous section reaches "1500", which is the continuation upper limit, the result is as follows.
After shifting to the advantageous section, the advantageous section clear counter is subtracted by "1" in each game and the advantageous section setting (FIG. 246) in the game start set. Then, when the advantageous section clear counter becomes "0" as a result of the subtraction in the game, it becomes "Yes" at the judgment of step S2744 in FIG. 246, so that the RWM initialization is executed. As a result, the normal section shifts to the normal section at the start of the game.
Therefore, in such a case, the advantageous section is ended without going through the preparation for the end of the advantageous section shown in FIG. 253.

Although the thirtieth embodiment of the present invention has been described above, the present invention is not limited to the above description, and various modifications such as the following are possible.
(1) The subtraction of the game section clear counter was executed at the time of setting the game start, but immediately after the start switch was operated (for example, in FIG. 244, after step S2178) and after all reels were stopped (in FIG. 244, after step S2187). The game end check process (step S2705 in FIG. 244) or the like may be executed at any timing.
(2) In the present embodiment, the value set in the advantageous section clear counter when shifting to the advantageous section is set to "1500 (D)". This is based on the fact that the upper limit of the number of games in the advantageous section is "1500" and that "1" is subtracted per game in the advantageous section. Therefore, the initial value set in the advantageous section clear counter is not necessarily limited to "1500 (D)", and a value less than "1500 (D)" or a value exceeding "1500 (D)". It may be. For example, "3000 (D)" may be set as an initial value in the advantageous section clear counter, and "1" may be subtracted for each medal payout.

Further, the subtraction is not limited to "1" per game, and for example, "10 (D)" may be subtracted per game for the convenience of calculation. In this case, for example, "15000 (D)" is set as the initial value of the advantageous section clear counter.
It is necessary to set the initial value of the advantageous section clear counter when shifting to the advantageous section after the subtraction timing of the advantageous section clear counter.
That is, when the advantageous section clear counter value before the subtraction process is "0" and the advantageous section type flag is "1", the initial value is set in the advantageous section clear counter.

(3) In the preparation for the end of the advantageous section (FIG. 253), "1" was stored in the advantageous section clear counter. This is because, as described above, the advantageous section clear counter is set to "0" in the game start set executed thereafter. However, not limited to this, for example, when it is confirmed at that time that the advantageous section (and AT) will be ended after the "10" game, the value of the advantageous section clear counter is set to "10 (D)" at that time. It is also possible to update to. As described above, in the preparation for the end of the advantageous section, it is not a condition that the value of the advantageous section clear counter is always set to "1", and an arbitrary value can be set.

(4) In the present embodiment, the advantageous section clear counter value in the standby section is "0", and when the standby section shifts to the advantageous section, the advantageous section clear counter value is set to "1500 (D)". .. However, not limited to this, for example, when an advantageous section is won in the normal section, "1500 (D)" is set in the advantageous section clear counter value, and when shifting from the normal section to the standby section, the standby is performed. It may be controlled to maintain the advantageous section clear counter value "1500 (D)" throughout the section. For example, even during the waiting section, the value of the advantageous section clear counter is subtracted by "1" for each game, but only during the waiting section, a process of adding "1" is added thereafter. As a result, when the advantageous section is won in the normal section, the advantageous section clear counter value can be uniformly set to "1500 (D)" at that time.

(5) In the present embodiment, even if the maximum payout notification flag is "0" after winning the advantageous section, it is set that the advantageous section may be terminated when 1BB wins. Here, there are various examples of which special combination is set to end the advantageous section even if the maximum payout notification flag is "0" when a prize is won.
For example, for 1BB, RB, and 2BB (MB), when any of these wins, the maximum payout notification flag may be set to "0" or the advantageous section may be terminated. Be done.
On the other hand, for SB (single bonus) and CB (challenge bonus), even if they win, it is possible to set that the advantageous section cannot be ended unless the maximum payout notification flag is "1". ..
Even if the maximum payout notification flag is "0", when the advantageous section clear counter reaches "0", in other words, when the continuous upper limit of the advantageous section (the number of games is 1500 games or the number of payouts is 3000) is reached. Can end the advantageous section.

(6) Although the advantageous section display LED flag is provided in the present embodiment, it is also possible not to provide the advantageous section display LED flag. For example, when the advantageous section clear counter is "0", the advantageous section display LED 77 is controlled to be turned off, and when the advantageous section clear counter is not "0" (however, "1" is subtracted from "0"). When the carry is carried down (excluding "FFFF (H)"), it is possible to control the advantageous section display LED 77 to be turned on.

When set in this way, the advantageous section display LED 77 is turned on after the interrupt process for turning on the digit 4a after the advantageous section clear counter is updated from "0" to "1500 (D)". Therefore, in this case, in FIG. 246, the advantageous section display LED 77 is turned on in the interrupt process for turning on the digit 4a after step S2748.
Further, since it is step S2742 in FIG. 246 that the advantageous section clear counter changes from "1" to "0" after shifting to the advantageous section, it is an advantageous section in the interrupt process for lighting the digit 4a after step S2742. The display LED 77 goes out.

On the other hand, when the advantageous section display LED 77 is turned on based on the advantageous section display LED flag as in the present embodiment, the advantageous section display LED 77 is turned on in the interrupt process for turning on the digit 4a after step S2749 in FIG. 246.
Further, since it is step S2746 in FIG. 246 that the advantageous section display LED flag changes from "1" to "0" after shifting to the advantageous section, the digit 4a after step S2746 is lit in the same manner as described above. The advantageous section display LED 77 is turned off in the interrupt processing to be performed.

(7) The advantageous section type flag is set to "000000000000 (B)" in the normal section, "000000010 (B)" in the standby section, and "00000001 (B)" in the advantageous section. However, the value is not limited to these values, and any value may be set as long as the normal section, the standby section, and the advantageous section can be determined. For example, it may be set to "10 (D)" in the normal section, "11 (D)" in the standby section, and "12 (D)" in the advantageous section.
Further, in the present embodiment, when shifting from the standby section to the advantageous section, a process (shift instruction) for shifting the bit of the advantageous section type flag to the right by "1" is executed. However, when the value of the standby section or the advantageous section is set to an arbitrary value as described above in the advantageous section type flag, when shifting from the standby section to the advantageous section, the shift command is not used and the advantageous section is set. A processing instruction that stores the corresponding value may be executed.

(8) The maximum payout notification flag was set to "0" when not notified, and "1" for others (notified, etc.). However, it is not limited to these values. For example, it is possible to set the value of "not notified" of the maximum payout notification flag to "1 (H)" and set the value of "others (notified, etc.)" to "FF (H)". In other words, any value may be used as long as data capable of determining whether or not the advantageous section can be ended is stored.

(9) In the RWM initialization (FIG. 248) in the present embodiment, the start address is specified in the address range to be initialized, and the initialization is executed in ascending order of the addresses. However, the present invention is not limited to this, and it is also possible to specify the last address in the address range to be initialized and subtract "1" by address update (initialize in descending order of addresses).

(10) In the example of the advantageous section type update shown in FIG. 249, it was first determined in step S2781 whether or not the advantageous section was won, and then it was determined whether or not to shift to the standby section. However, not limited to this, it is also possible to update the advantageous section type flag to the standby section or the advantageous section at once based on the winning condition device. For example, in FIG. 17, when it corresponds to "winning including 1BBA", the advantageous section type flag is updated to the standby section (00000010 (B)), and "the number of small winning combination D is" 50 "" or "small winning combination E1". When the number "250" is won, the advantageous section type flag may be updated to the advantageous section (00000001 (B)).

(11) In the flowchart shown in the thirtieth embodiment, the order of processing is not limited to the order shown in the figure, and if the order of processing can be changed, the order of processing can be changed. be.
(12) The thirtieth embodiment and the above-mentioned various modifications are not limited to being carried out alone, but can be carried out in combination as appropriate.

<31st Embodiment>
Subsequently, the 31st embodiment will be described.
The 31st embodiment will be described based on the 26th and 27th embodiments (FIGS. 181 to 221). Further, the management information display LED 74 for displaying each ratio is abbreviated as "role ratio monitor" if necessary.
In the 26th embodiment shown in FIG. 181, the ratio of 5 items is displayed. On the other hand, in the 31st embodiment, the following 6 ratios are calculated and displayed in the following order.
(Display ratio)
1. 1. Advantageous section ratio 2. Continuous character ratio (6000 times)
3. 3. Character ratio (6000 times)
4. Continuous character ratio (cumulative)
5. Character ratio (cumulative)
6. Character instruction ratio (cumulative)
Therefore, in the 31st embodiment, "6. Character instruction ratio (cumulative)" is added to the 26th embodiment.

Here, the "feature instruction ratio" is a value obtained by dividing the total of the number of payouts when the bonus is activated and the number of payouts in the instruction function operating game by the total number of payouts. Further, as in the 26th embodiment, when a value after the decimal point is generated as a result of the calculation of the ratio, the value after the decimal point is rounded down.
In addition, the "number of payouts in the instruction function operation game" is set when a high bell (9 bells in the present embodiment) wins because the stop switch 42 is operated according to the pressing order displayed by the operation of the instruction function. According to the first embodiment, the number of cards is 9, so "9" is added to the accessory instruction counter (cumulative) and the total number of payouts (cumulative) counter, which will be described later.
On the other hand, in the instruction function operation game, when the lower bell (one bell in the first embodiment) wins because the stop switch 42 is operated in a pressing order different from the displayed pressing order, the accessory instruction counter Add "1" to the (cumulative) and total payout (cumulative) counters.
Similarly, in the instruction function operation game, when the winning combination is missed (when the combination is not won) because the stop switch 42 is operated in a pressing order different from the displayed pressing order, the number of payouts is not added (or The process of adding "0" is executed.). In other words, the values of the accessory instruction counter (cumulative) and the total payout (cumulative) counter are the same as the values stored in the previous game.

Further, in the 31st embodiment, the ratio of the above 6 items is calculated for each set value. Here, "for each set value" means a ratio of 6 items in a game with a set value of 1, a ratio of 6 items in a game with a set value of 2, ..., a game with a set value of 6. Refers to all of the ratios of the 6 items in.
Therefore, in the 31st embodiment, outside the use area of the RWM53 shown in FIGS. 182 to 183 of the 26th embodiment,
Total payout ring buffer 0-14
Continuous accessory payout ring buffer 0-14
Character payout ring buffer 0-14
Is provided for each set value (set values 1 to 6).
Further, as shown in the address “F000 (H)” in FIG. 182, originally, a storage area for the set value data is provided in the used area, but in the 31st embodiment, in addition to the set value data in the used area. The set value data is also stored outside the used area.
As the storage method, for example, when a set value is set, the set value is stored in the set value data in the used area, but at that time, the set value data in the used area is stored outside the used area. Copying to the set value data can be mentioned.

Furthermore, in order to calculate and display the above-mentioned character instruction ratio, the "character instruction payout ring" for storing "the total number of payouts when the character is activated and the number of payouts in the instruction function operating game" is stored. "Buffers 0 to 14" are provided for each set value (set values 1 to 6).
From the above, in the 31st embodiment, the storage area shown below is provided outside the used area of the RWM53.
Set value data (1 byte)
Set value 1 Total payout ring buffer 0 (2 bytes) ~ Set value 1 Total payout ring buffer 14 (2 bytes)
Set value 2 Total payout ring buffer 0 (2 bytes) ~ Set value 2 Total payout ring buffer 14 (2 bytes)
Set value 3 Total payout ring buffer 0 (2 bytes) ~ Set value 3 Total payout ring buffer 14 (2 bytes)
Set value 4 Total payout ring buffer 0 (2 bytes) ~ Set value 4 Total payout ring buffer 14 (2 bytes)
Set value 5 Total payout ring buffer 0 (2 bytes) ~ Set value 5 Total payout ring buffer 14 (2 bytes)
Set value 6 Total payout ring buffer 0 (2 bytes) ~ Set value 6 Total payout ring buffer 14 (2 bytes)

Set value 1 Continuous accessory payout ring buffer 0 (2 bytes) ~ Set value 1 Continuous accessory payout ring buffer 14 (2 bytes)
Set value 2 Continuous accessory payout ring buffer 0 (2 bytes) ~ Set value 2 Continuous accessory payout ring buffer 14 (2 bytes)
Set value 3 Continuous accessory payout ring buffer 0 (2 bytes) ~ Set value 3 Continuous bonus payout ring buffer 14 (2 bytes)
Set value 4 Continuous accessory payout ring buffer 0 (2 bytes) ~ Set value 4 Continuous accessory payout ring buffer 13 (2 bytes)
Set value 4 Continuous accessory payout ring buffer 14 (2 bytes) ~ Set value 5 Continuous accessory payout ring buffer 13 (2 bytes)
Set value 5 Continuous accessory payout ring buffer 14 (2 bytes) ~ Set value 6 Continuous bonus payout ring buffer 14 (2 bytes)

Set value 1 accessory payout ring buffer 0 (2 bytes) ~ Set value 1 accessory payout ring buffer 14 (2 bytes)
Set value 2 accessory payout ring buffer 0 (2 bytes) ~ Set value 2 accessory payout ring buffer 14 (2 bytes)
Set value 3 accessory payout ring buffer 0 (2 bytes) ~ Set value 3 accessory payout ring buffer 14 (2 bytes)
Set value 4 Character payout ring buffer 0 (2 bytes) ~ Set value 4 Character payout ring buffer 14 (2 bytes)
Set value 5 Character payout ring buffer 0 (2 bytes) ~ Set value 5 Character payout ring buffer 14 (2 bytes)
Set value 6 accessory payout ring buffer 0 (2 bytes) ~ Set value 6 accessory payout ring buffer 14 (2 bytes)

In this way, in order to control the storage area stored in each ring buffer to be different for each set value (set values 1 to 6), 400 game counters (2 bytes) and ring buffer number (1) are used for each set value. A storage area of bytes) is also provided.

In this embodiment, only the cumulative total is calculated and displayed as the accessory instruction ratio. Therefore, a ring buffer corresponding to the accessory instruction ratio is not provided. However, when calculating and displaying the accessory instruction ratio (6000 times), the same as the other ring buffers described above,
Set value 1 Character instruction payout ring buffer 0 (2 bytes) ~ Set value 1 Character instruction payout ring buffer 14 (2 bytes)
Set value 2 Character instruction payout ring buffer 0 (2 bytes) ~ Set value 2 Character instruction payout ring buffer 14 (2 bytes)
Set value 3 Character instruction payout ring buffer 0 (2 bytes) ~ Set value 3 Character instruction payout ring buffer 14 (2 bytes)
Set value 4 Character instruction payout ring buffer 0 (2 bytes) ~ Set value 4 Character instruction payout ring buffer 14 (2 bytes)
Set value 5 Character instruction payout ring buffer 0 (2 bytes) ~ Set value 5 Character instruction payout ring buffer 14 (2 bytes)
Set value 6 Character instruction payout ring buffer 0 (2 bytes) ~ Set value 6 Character instruction payout ring buffer 14 (2 bytes)
Should be provided.

Further, in FIG. 183 of the 26th embodiment, the total number of games counter of the address "F026D (H)" to the character ratio (cumulative) data of the address "F289 (H)" and the count of the address "F289 (H)". In the 31st embodiment, the upper limit flag to the blinking request flag of the address "F28D (H)" are set values by further adding "the character instruction payout (cumulative) counter" and "the character instruction ratio (cumulative) data". It is provided every 1 to 6.
The "feature instruction payout (cumulative) counter" is the total of the number of payouts when the bonus is activated and the number of payouts in the instruction function activated game.
In addition, the "character instruction ratio (cumulative) data" is a ratio calculated by "(number of payouts when the character is activated + number of payouts in the instruction function operation game) / total number of payouts".

Specifically, the following storage area is provided outside the used area of the RWM53.
Set value 1 Total number of games counter (3 bytes) ~ Set value 6 Total number of games counter (3 bytes)
Set value 1 Advantageous section game count counter (3 bytes) ~ Set value 6 Advantageous section game count counter (3 bytes)
Set value 1 Total payout (6000 times) Counter (3 bytes) ~ Set value 6 Total payout (6000 times) Counter (3 bytes)
Set value 1 continuous bonus payout (6000 times) counter (3 bytes) ~ Set value 6 continuous bonus payout (6000 times) counter (3 bytes)
Set value 1 accessory payout (6000 times) counter (3 bytes) ~ Set value 6 accessory payout (6000 times) counter (3 bytes)
Set value 1 Continuous bonus payout (cumulative) counter (3 bytes) ~ Set value 6 Continuous bonus payout (cumulative) counter (3 bytes)
Set value 1 Character payout (cumulative) counter (3 bytes) ~ Set value 6 Character payout (cumulative) counter (3 bytes)
Set value 1 Character instruction payout (cumulative) counter (3 bytes) ~ Set value 6 Character instruction payout (cumulative) counter (3 bytes)

Set value 1 Advantageous section ratio data (1 byte) ~ Set value 6 Advantageous section ratio data (1 byte)
Set value 1 continuous bonus ratio (6000 times) data (1 byte) ~ Set value 6 continuous bonus ratio (6000 times) data (1 byte)
Set value 1 accessory ratio (6000 times) data (1 byte) to set value 6 accessory ratio (6000 times) data (1 byte)
Set value 1 continuous bonus ratio (cumulative) data (1 byte) ~ Set value 6 continuous bonus ratio (cumulative) data (1 byte)
Set value 1 accessory ratio (cumulative) data (1 byte) ~ Set value 6 accessory ratio (cumulative) data (1 byte)
Set value 1 Character instruction ratio (cumulative) data (1 byte) ~ Set value 6 Character instruction ratio (cumulative) data (1 byte)

Further, in the 31st embodiment, each bit of the blinking request flag (the bit corresponding to the address “F28D (H)” in FIG. 183 of the 26th embodiment) is as follows.
Blinking request flag of the 31st embodiment D7: 175000 times blinking flag D6: 6000 times blinking flag D5: Character indication ratio (cumulative) blinking flag D4: Character ratio (cumulative) blinking flag D3: Continuous character ratio (cumulative) Blinking flag D2: Character ratio (6000 times) blinking flag D1: Continuous character ratio (6000 times) blinking flag D0: Advantageous section ratio blinking flag

Further, as shown in FIG. 184 of the 26th embodiment, when the number of games used for calculating the ratio is less than the predetermined number of times and when the ratio is equal to or more than the predetermined value, the display blinks, but the 31st embodiment The same applies to the form.
For example, when the number of games used to calculate the accessory instruction ratio (cumulative) is less than 175,000, the display blinks. In addition, when the accessory instruction ratio (cumulative) is "70" or more, it blinks.
Further, since the ratio display is performed for each set value, it is determined whether or not the number of games and the ratio for each set value satisfy the blinking condition. Therefore, for example, the accessory instruction ratio (cumulative) at the set value 1 does not satisfy the blinking condition, but the accessory instruction ratio (cumulative) at the set value 6 may satisfy the blinking condition.

For example, when the set value is set to 1 and activated, the number of games is exhausted, the game is exhausted in the advantageous section, the medal is paid out, the medal is paid out by operating the accessory, the medal is paid out by operating the continuous character, and the instruction function is activated. The following storage areas are updated by paying out medals at.
Set value 1 Total payout ring buffer 0 to 14
Set value 1 Continuous accessory payout ring buffer 0 to 14
Set value 1 Accessory payout ring buffer 0 to 14
Set value 1 Total game count counter Set value 1 Advantageous section game count counter Set value 1 Total payout (6000 times) counter Set value 1 Continuous bonus payout (6000 times) counter Set value 1 bonus payout (6000 times) counter Set value 1 Total payout (cumulative) counter set value 1 Continuous bonus payout (cumulative) counter set value 1 bonus payout (cumulative) counter set value 1 bonus instruction payout (cumulative) counter set value 1 Advantageous section ratio data (1 byte)
Set value 1 Continuous character ratio (6000 times) Data (1 byte) (every 400 games)
Set value 1 Character ratio (6000 times) Data (1 byte) (every 400 games)
Set value 1 Continuous character ratio (cumulative) data (1 byte) (every 400 games)
Set value 1 Character ratio (cumulative) data (1 byte) (every 400 games)
Set value 1 Character instruction ratio (cumulative) data (1 byte) (every 400 games)

In addition, since the total number of games counter is updated, it is necessary to always determine each game and the set value. In the present embodiment, since the set value data is stored outside the used area, the set value at the present time can be determined without accessing the used area for each game.
Further, for example, even when a small winning combination is won and a medal is paid out, the set value at that time is read and the value is added to the ring buffer or counter corresponding to the set value.

At the set value 1, for example, when a medal is paid out due to the operation of the accessory, the set value 1 total payout ring buffer, the set value 1 continuous bonus payout ring buffer, the set value 1 bonus payout ring buffer, and the set value 1 continuous bonus payout. The paid medals are added to the (cumulative) counter, the set value 1 bonus payout (cumulative) counter, and the set value 1 bonus instruction payout (cumulative) counter. In this case, the values of the storage areas of the set values 2 to 6 do not change.
Further, for example, when a medal is paid out in the instruction function operating game, the total payout (cumulative) counter and the accessory instruction payout (cumulative) counter are updated.

Next, when the setting is changed, for example, the setting value is set to 2, and the setting value is started, the ring buffer, the counter, and the data value related to the above-mentioned setting value 1 are continuously stored as they are.
Then, until the next setting is changed to a value other than the setting value 2.
Set value 2 Total payout ring buffer 0 to 14
Set value 2 Continuous accessory payout ring buffer 0 to 14
Set value 2 Accessory payout ring buffer 0 to 14
Set value 2 Total game count counter Set value 2 Advantageous section game count counter Set value 2 Total payout (6000 times) counter Set value 2 Continuous bonus payout (6000 times) counter Set value 2 bonus payout (6000 times) counter Set value 2 Total payout (cumulative) counter set value 2 Continuous bonus payout (cumulative) counter set value 2 bonus payout (cumulative) counter set value 2 bonus instruction payout (cumulative) counter set value 2 Advantageous section ratio data (1 byte)
Set value 2 Consecutive character ratio (6000 times) Data (1 byte) (every 400 games)
Set value 2 Character ratio (6000 times) Data (1 byte) (every 400 games)
Set value 2 consecutive character ratio (cumulative) data (1 byte) (every 400 games)
Set value 2 Character ratio (cumulative) data (1 byte) (every 400 games)
Set value 2 Character instruction ratio (cumulative) data (1 byte) (every 400 games)
Is updated.

Further, in the 26th embodiment, the five ratios are displayed for 6 seconds each. Also in the 31st embodiment, as a general rule, the display time of one ratio of one set value is about 6 seconds. In the 31st embodiment, since the number of items to be displayed has increased from 5 to 6, the time required to display the item 6 is "about 6 seconds x 6 items = about 36 seconds". Further, since the settings 1 to 6 are displayed in sequence, the display completes in "about 36 seconds x 6 = about 216 seconds".

Examples of the display method include the following examples. The notation shown below is "(identification segment 2 digits) (ratio segment 2 digits)".
First, the display of the identification segment of the accessory instruction ratio (cumulative) is set to "7b.". “B” lights the segments C, D, E, F, and G in FIG.
Further, the display of the set value 1 to the set value 6 is set to "r1" to "r6", respectively. “R” lights segments E and G in FIG.
Furthermore, in the following, "*" indicates extinguishing, and "-" indicates an arbitrary number.

In this case, for example
"R1 **" (indicates the set value 1)
↓ (after 3 seconds have passed)
"7U .--" (indicates the advantageous section ratio)
↓ (after 6 seconds have passed)
"6y .--" (indicating a continuous accessory (6000 times))
↓ (after 6 seconds have passed)
"7y .--" (indicating a character (6000 times))
↓ (after 6 seconds have passed)
"6A .--" (indicates continuous characters (cumulative))
↓ (after 6 seconds have passed)
"7A .--" (indicates the character (cumulative))
↓ (after 6 seconds have passed)
"7b .--" (indicates the character instruction (cumulative))
↓ (after 6 seconds have passed)
"R2 **"
↓ (after 3 seconds have passed)
"7U ..."
:
"R6 **"
↓ (after 3 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
"6y ..."
↓ (after 6 seconds have passed)
"7y ..."
↓ (after 6 seconds have passed)
"6A .--"
↓ (after 6 seconds have passed)
"7A ..."
↓ (after 6 seconds have passed)
"7b .--"
↓ (after 6 seconds have passed)
"R1 **"
↓ (after 3 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
"6y ..."
: (Hereafter, repeat)
And repeat the display.
The display time of "r1" or the like indicating the set value is set to 3 seconds in the above example, but it may be set to any number of seconds as long as the set value can be easily read. Assuming that the time for displaying the set value is "x" seconds, the display ends in "36 + x" seconds per set value.

Further, for example, in the case of a gaming machine that has never been set to the set value 6 in the past, the ring buffer or counter at the set value 6 is "0".
"R6 **"
↓ (after 3 seconds have passed)
"7U.00"
↓ (after 6 seconds have passed)
"6y.00"
↓ (after 6 seconds have passed)
"7y.00"
↓ (after 6 seconds have passed)
"6A.00"
↓ (after 6 seconds have passed)
"7A.00"
↓ (after 6 seconds have passed)
"7b.00"
:
Is displayed.

As described above, when the ratios from the set value 1 to the set value 6 are sequentially displayed and repeatedly displayed, the ratio is always displayed regardless of whether the front door is opened or closed after the power is turned on.
However, in this way, when the front door is opened, there is a risk that the player will know (see) the ratio for each set value. Therefore, as a method of not knowing what the set value of the displayed ratio is, the following method can be mentioned.
As a first method, the ratio is not always displayed. For example, simply opening the front door does not display the ratio. Then, for example, the setting key is inserted, the setting key switch 12 is turned on (for example, in the setting change mode and / or the setting confirmation mode), the setting switch 13 is turned on, or a predetermined (or dedicated) setting switch is turned on. It is possible to start displaying the ratio only when the switch is turned on. The ratio is displayed when the setting key is removed, when the setting key switch 12 is turned off (for example, when the setting change mode / or setting confirmation mode ends), or when the setting switch 13 is turned on again. Alternatively, the ratio display may be terminated when a predetermined (or dedicated) switch is turned on / off again.

As the second method, the display related to the set value such as "r1 **" described above is not performed, and for example, the following display is performed.
"7U .--" (Ratio display start at set value 1): "A1"
↓ (after 6 seconds have passed)
"6y ..."
↓ (after 6 seconds have passed)
"7y ..."
↓ (after 6 seconds have passed)
"6A .--"
↓ (after 6 seconds have passed)
"7A .--": "A2"
↓ (after 6 seconds have passed)
"7b .--"
↓ (after 6 seconds have passed)
"7U .--" (Ratio display start at set value 2): "B1"
↓ (after 6 seconds have passed)
"6y ..."
↓ (after 6 seconds have passed)
"7y .--": "B2"
↓ (after 6 seconds have passed)
"6A .--"
↓ (after 6 seconds have passed)
"7A ..."
↓ (after 6 seconds have passed)
"7b .--"
↓ (after 6 seconds have passed)
"7U .--" (Ratio display start at set value 3): "C"
:

In such a continuous ratio display, for example, when one of the ratios is displayed, a switch (for example, a setting switch 13) capable of displaying the set value of the ratio is provided, and when the switch is operated, the ratio is changed. Displaying the corresponding setting value can be mentioned. The set value may be displayed, for example, by providing a dedicated 7-segment display or by using the set value display LED 73.
Specifically, when the setting switch 13 is operated at the time of the above "A1" or "A2", "1" is displayed on the setting value display LED 73. Further, when the setting switch 13 is operated at the time of the above "B1" and "B2", "2" is displayed on the setting value display LED 73. Furthermore, when the setting switch 13 is operated at the time of the above "C", "3" is displayed on the setting value display LED 73.
In this case, the setting value may be displayed only when the setting switch 13 is held down, or when the setting switch 13 is pressed once, the setting value is set until the setting value 1 to the setting value 6 is displayed in a cycle. The value may be displayed.

Alternatively, only the ratio display as described above is repeated (the information on the set value is not displayed on the role ratio monitor), and the set value corresponding to the currently displayed ratio is always set to the set value display LED73 or the setting value display LED73. It is also possible to display on a dedicated LED.
In addition, when the setting value of the currently displayed ratio is always displayed on the setting value display LED 73, when the mode is changed to the setting change mode or the setting confirmation mode, the setting value corresponding to the ratio is not set but is currently set. The set value is displayed on the set value display LED 73.

In addition, as a third method, when a medal-less error (hopper empty) or a medal jam (retention) error occurs in the medal selector, the ratio display is interrupted and the ratio is displayed until the error is recovered. There is no such thing. Therefore, when the above error occurs in the hall and the front door is opened by the hall clerk, the ratio display disappears at that time, so that the player cannot see it. For example, when a hall clerk replenishes medals (eliminates errors) and operates the release switch, the ratio display is restarted. When the release switch is provided inside the slot machine 10, a ratio may be seen in a short time from the operation of the release switch to the closing of the front door. For example, about 3 seconds have passed since the error was released. If the ratio display is resumed later, the ratio will not be seen by the player if the front door is closed within 3 seconds after the release switch is operated. Further, when the release switch also serves as the door open key, the player cannot see the ratio even if the ratio display is restarted immediately after the operation of the release switch.

It should be noted that no medal-less error or medal jam error has occurred, and there is no problem even if the ratio display is continued simply by opening the front door. In the hall, simply opening the front door is not a rare act (in rare cases, it is possible to check the vacant space to see if there are enough medals inside), but to open the hall. Most of the reasons for opening the front door inside are only when the above error occurs.

Furthermore, as a fourth method, there is a method of repeatedly displaying only the ratio of a specific set value. In this case, the player can see the displayed ratio itself, but cannot judge at a glance which set value the ratio belongs to.
For example, if the default setting value after the power is turned on is the setting value 1.
"R1 **"
↓ (after 3 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
"6y ..."
↓ (after 6 seconds have passed)
"7y ..."
↓ (after 6 seconds have passed)
"6A .--"
↓ (after 6 seconds have passed)
"7A ..."
↓ (after 6 seconds have passed)
"7b .--"
↓ (after 6 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
: (Hereafter, repeat)
In this way, the display of the ratio of 6 items with the set value 1 is repeated.
Then, regardless of the display timing of any ratio, if a predetermined switch (for example, setting switch 13 or the like) is operated once, from that point onward,
"R2 **"
↓ (after 3 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
"6y ..."
↓ (after 6 seconds have passed)
"7y ..."
↓ (after 6 seconds have passed)
"6A .--"
↓ (after 6 seconds have passed)
"7A ..."
↓ (after 6 seconds have passed)
"7b .--"
↓ (after 6 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
: (Hereafter, repeat)
The display is switched to, and the display of the ratio of 6 items with the set value 2 is repeated.
During the repeated display of the above ratio, if the predetermined switch is operated again at any timing, from that point onward,
"R3 **"
↓ (after 3 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
"6y ..."
:
And repeat.

With the above display, even if the player sees the ratio display in the hall, for example, by opening the front door when an error occurs or when replenishing medals to the hopper, which player is It is not possible to determine whether it is a ratio of set values.

Next, the skip function of the ratio display will be described.
As described above, if the ratios of 6 items from the set value 1 to the set value 6 are continuously displayed for 6 seconds each, it will take at least 216 seconds to complete the cycle (considering the 3 seconds of the set value display). If not). Therefore, it is preferable to operate a predetermined switch (for example, a setting switch 13 or a dedicated switch) so that the display content can be skipped.
As a method of skipping
(1) How to skip to the next item and
(2) There is a method of skipping at the beginning of the next set value.
In the method (1) above, for example, if the setting switch 13 is operated once while displaying one ratio, the next ratio is displayed even if 6 seconds have not passed. Further, if the setting switch 13 is operated once during the display, the next ratio is further displayed. By doing so, it is possible to immediately perform a predetermined display depending on the number of operations of the setting switch 13.
In particular,
"7U ..."
↓
When 2 seconds have passed since the display started, the setting switch 13 is turned on ↓
"6y ..."
↓
When 1 second has passed since the display started, the setting switch 13 is turned on ↓
"7y ..."
:
become that way.

Further, in the method (2) above, for example,
"7y .--" (value of set value 1)
↓ (6 seconds have passed)
"6A .--"
↓ (3 seconds after the display starts)
Setting switch 13 on ↓
"R2 **"
↓ (after 3 seconds)
"7U ..."
↓ (6 seconds have passed)
"6y ..."
:
Will be.

Further, in this case, when the setting switch 13 is pressed twice in succession,
"7y .--" (value of set value 1)
↓ (6 seconds have passed)
"6A .--"
↓
When 3 seconds have passed since the display started, the setting switch 13 is turned on ↓
"R2 **"
↓
When 1 second has passed since the display started, the setting switch 13 is turned on ↓
"R3 **"
↓ (after 3 seconds have passed)
"7U ..."
↓ (after 6 seconds have passed)
"6y ..."
:
Will be.

When the information about the set value is not displayed on the role ratio monitor such as "r1 **" and is displayed on the set value display LED 73 or the dedicated LED, for example, when skipping to the next set value, it is necessary. It is also possible to switch to the display of the same ratio that was displayed up to or the next ratio.
For example, first
"7U .--" (Set value "1" is displayed on other LEDs)
↓ (after 6 seconds have passed)
"6y ..."
↓ (Setting switch 13 is on before 6 seconds have passed)
"7y ..." (Set value "2" is displayed on other LEDs)
In some cases.
Secondly,
"7U .--" (Set value "1" is displayed on other LEDs)
↓ (after 6 seconds have passed)
"6y ..."
↓ (Setting switch 13 is on before 6 seconds have passed)
"6y .--" (Set value "2" is displayed on other LEDs)
In some cases.

With the method that does not skip the ratio display, if you keep watching the display contents for at least 216 seconds, you can see the total ratio of all the set values, but if you implement the method of skipping, when there is a ratio you want to check, that ratio If the setting switch 13 and the like are continuously operated until the display of is displayed, the ratio can be displayed at an early stage.

Although the 31st embodiment of the present invention has been described above, the present invention is not limited to the above description, and various modifications such as the following are possible.
(1) In the 31st embodiment, the ratio of the total of all set values (the same ratio as in the 26th embodiment) is not displayed. However, the ratio of the total of all set values may be displayed. To calculate the total ratio of all set values, the ratio should be calculated by summing all the set values of each counter. Then, the display of "r1"->"r2"->...->"r6"->"r0 (total of all settings)"->"r1"-> ... is repeated.

(2) In the 31st embodiment, the payout ratio of only the instruction function operating game is not displayed, but it is also possible to display the payout ratio of only the instruction function operating game. In this case, in addition to a method of providing a storage area for storing only the number of payouts of the instruction function operating game at a predetermined address of the RWM53, a method of subtracting the character payout (cumulative) counter from the character instruction payout number (cumulative) counter. There may be.
(3) In the instruction function operation game, when 9 cards are paid out in the correct answer pressing order, the stop switch 42 is operated in the incorrect answer pressing order in the game, and when the 1-card combination wins, it is handled as follows. It is possible.
a) Add "1" to each of the total payout (cumulative) counter and the accessory instruction payout (cumulative) counter.
b) "1" is not added to the accessory instruction payout (cumulative) counter, and "1" is added only to the total payout (cumulative) counter.

(4) According to the current rules, the instruction function is similar to the accessory but not the accessory itself, so the accessory ratio and the accessory instruction ratio are separated. However, if the instruction function is included in the concept of the accessory, the "accessory ratio" shall include the payout by the operation of the instruction function, and shall be performed by displaying five items as in the 26th embodiment. Is also possible. However, even in this case, it is displayed for each set value.
On the other hand, if the accessory ratio is displayed, the accessory ratio may not be displayed as long as the rules are satisfied without displaying the accessory ratio.

(5) In the embodiment, the number of payouts is counted and the ratio is calculated, but for example, the net increase number can be counted and the ratio can be calculated based on the count. In this case, for example, in the instruction function operation game, when 3 sheets are in and 9 sheets are out (when the push order is correct), a counter (specifically, a character instruction payout (cumulative) counter or an instruction function operation game) is used as the net increase number. Add "6" to the counter) that stores only the number of payouts. On the other hand, in the instruction function operation game, when the stop switch 42 is operated in an incorrect pressing order different from the pressing order displayed by the instruction function and a winning combination is won, 3 cards are in and 1 card is out. , "2" will be subtracted from the counter. Further, when the instruction function operation game is missed (non-winning of the role), 3 cards are in and 0 cards are out, so "3" is subtracted from the counter.
In this configuration, for example, when the counter is "0" and "2" or "3" is subtracted, a carry occurs. Specifically, when the counter is composed of 3 bytes and subtracting "2" from "0", the information "1677241" is stored in the counter. When a carry occurs in this way, it is possible to reduce the fact that a large erroneous ratio is calculated by controlling the counter to store "0".
(6) The ratio for each set value is displayed in the order of setting value 1 → setting value 2 → ... → setting value 6, but on the contrary, setting value 6 → setting value 5 → ... → setting. Each ratio may be displayed in the order of value 1.

(7) The ratio is always displayed, and when the setting switch 13 or the reset switch 14 (or the setting / reset switch that combines both) is operated, the ratio display item is switched, or the ratio of other set values is changed. It may be switched to the display of. In the case of such specifications, when a medal-less error or a medal jam error occurs and the above switch is operated after removing the error, the error display can be canceled. Then, after the error display is released, when the switch is operated again, the ratio display item or the like can be switched. With such a configuration, it is possible to suppress unintended behavior such as switching of ratio display items and the like, even though the switch operation is aimed at canceling an error. Further, the control process can be simplified by not executing the error cancellation control and the switching control of the ratio display item and the like at the same time.
(8) Further, in the case of the above specifications, even if the setting switch 13 or the reset switch 14 (or the setting / reset switch in which both are combined) is operated during the setting change mode, the display item of the ratio is displayed. Priority is given to the setting value update process without switching to the display of the ratio of other set values. With such a configuration, it is possible to suppress unintended behavior such as switching of ratio display items and the like, even though the switch operation is aimed at updating the set value. Further, the control process can be simplified by not executing the update process of the set value and the switching control of the display item of the ratio at the same time. On the other hand, when the above switch is operated during the setting confirmation mode, it is possible to switch the ratio display item or switch to the ratio display of another set value.

(9) When the setting is changed during the game, the data in the game is not stored in the RWM53.
For example, in the case where the set value is set to 4 and the instruction function is activated, the player operates the stop switch 42 in the pressing order displayed by the operation of the instruction function, and the power is cut off in the middle of the operation. The process is done.
After that, when the power is restored while the setting key switch 12 is on, the mode shifts to the setting change mode.
In this setting change mode, it is assumed that the setting value 4 is changed to the setting value 3.
In such a case, the data in the game in which the power is cut off is not stored in the RWM53.
Further, even when the set value 4 is maintained in the setting change mode (resetting the set value from the set value 4 to the set value 4), the data in the game in which the power is cut off is stored in the RWM53. Not done.
Further, the game after the setting change mode is not a game in which the instruction function is activated, but a game in a normal section (normal game).
On the other hand, when the power is restored while the setting key switch 12 is off after the power is turned off, the subsequent game in which the power is turned off is executed, and the game result of the game is stored in the RWM 53. .. In other words, the game after the power is turned off is an instruction function operating game.

(10) Without storing the set value data outside the used area, the set value data in the used area (address “F000 (H)” in FIG. 182 of the 26th embodiment) is referred to every game and set to the set value. The values of various counters may be updated accordingly. For example, in the ratio set processing of the 26th embodiment, the set value data stored in the address “F000 (H)” is stored in the register. Then, the address of the RWM to be updated can be specified based on the set value data stored in the register.

(11) The count upper limit flag described in the 26th embodiment is provided for each set value.
Therefore, for example, the payout number upper limit flag of the set value 1 may be "1", and the count upper limit flag of the set value 2 may be "0".
In other words, in the case of the set value 1 (when the set value data is "0"), the set value 1 continuous bonus payout (cumulative) counter (3 bytes), based on the payout number upper limit flag of the set value 1. Do not update the set value 1 accessory payout (cumulative) counter (3 bytes) and the set value 1 accessory instruction payout (cumulative) counter (3 bytes), and when the set value is 2 (the set value data is "1"). In the case), based on the set value 2 payout number upper limit flag, the set value 2 continuous bonus payout (cumulative) counter (3 bytes), the set value 2 bonus payout (cumulative) counter (3 bytes), and the set value 2 The character instruction payout (cumulative) counter (3 bytes) can be updated.
Among the count upper limit flags, the payout number upper limit flag is given as an example, but the same can be said for the game number upper limit flag. For example, when the game count upper limit flag of the set value 1 is "1", the set value 1 total game count counter (3 bytes) and the set value 1 advantageous section game count counter (3 bytes) are not updated. When the game count upper limit flag of the set value 2 is "0", the set value 2 total game count counter (3 bytes) and the set value 2 advantageous section game count counter (3 bytes) can be updated.
Here, the total payout (6000 times) counter (3 bytes), the continuous accessory payout (6000 times) counter (3 bytes), and the like can be updated regardless of the count upper limit flag.

(12) If a power outage occurs while the predetermined ratio (item) is displayed on the role ratio monitor and then the power is restored, the ratio (item) when the power outage occurs is displayed. It may be restarted, or if the power is cut off while the ratio is displayed on the role ratio monitor and then the power is restored, all digits of the role ratio monitor are first (first embodiment). The segments of the digits 6 to 9 in FIG. 3 (segments A to G and DP in FIG. 4 of the first embodiment) may be turned on for 2 seconds, and then the display of the ratio may be resumed. In this way, after the power is restored, it is possible to determine whether or not a failure has occurred by lighting the digit segment constituting the role ratio monitor. The segment DP may or may not be a lighting target when the power is restored (it may be turned off). Further, the segment DP does not necessarily have to be provided, and the digits constituting the role ratio monitor may have segments A to G.

(13) In each of the above embodiments, a slot machine is illustrated as an example of a gaming machine, but it can also be applied to, for example, a casino machine or an enclosed gaming machine (medalless gaming machine).
(14) Further, the 31st embodiment and the various modified examples described above (including the contents of the 1st to 30th embodiments) are not limited to being carried out individually, but may be carried out in combination as appropriate. Is possible.

<Additional notes>
Examples of the inventions (initial inventions) described in the initial specification of the present application include the following initial inventions 1 to 69, which solve the problems to be solved by each initial invention and the problems related to the initial invention, respectively. The means for this and the effects of the original invention are as follows. However, the invention described in the present specification does not mean that the invention is limited to the initial inventions 1 to 69.

1. 1. Initial invention 1
(A) Problem to be Solved by Initial Invention 1 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed. Here, when an upper limit (for example, the upper limit number of games) is set in the advantageous section, the upper limit of the advantageous section may be exceeded as a result of adding the number of games during the advantageous section and AT. In such a case, it is required to perform appropriate control.
The problem to be solved by the initial invention is to prevent the player from giving the impression that the player can play the game beyond the upper limit when the instruction game section (AT) exceeds the upper limit of the advantageous section. be.

(B) Means for Solving the Problem of Initial Invention 1 (Note that the corresponding embodiment is described in parentheses.)
The first solution (third embodiment; Example 2 in FIG. 55) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) that controls the start and end of an advantageous section and the start and end of an instruction game section, and
It is equipped with an effect control means (sub control board 80) that outputs an effect related to the instruction game section.
The game control means
In the advantageous section, when the continuation upper limit (1500 games) of the advantageous section is reached, the advantageous section is terminated and the advantage section is terminated.
When the start condition of the designated game section is satisfied in the advantageous section, the designated game section is started and the designated game section is started.
In the designated game section, when the condition for extending the designated game section (adding the number of games) is satisfied, the designated game section can be extended.
Information about the indicated game section (AT counter value, additional counter value, upper limit counter value, etc.) is transmitted to the effect control means.
The effect control means
If the extension of the designated game section does not exceed the continuation upper limit of the advantageous section based on the information received from the game control means, predetermined information regarding the extension of the designated game section (AT remaining game after addition). (Number of times) is displayed,
Based on the information received from the game control means, when the instruction game section is extended to exceed the continuation upper limit of the advantageous section, or after the instruction game section reaches the continuation upper limit of the advantageous section, the extension of the instruction game section is extended. When it is decided, it is characterized by displaying specific information (“celebration”, “congratulations”, etc.) different from the predetermined information.

The second solution is, in the first solution,
The effect control means
As the predetermined information, information that can grasp how much the indicated game section has been extended is displayed (displays the specific number of games).
As the specific information, it is possible to grasp that some decision has been made regarding the extension of the designated game section, but it is not possible to grasp the degree of extension of the designated game section (displaying the specific number of games). do not)
It is characterized by that.

(C) Effect of Initial Invention 1 According to the original invention, when the instruction game section is extended to exceed the continuation upper limit of the advantageous section, or after the instruction game section reaches the continuation upper limit of the advantageous section, the instruction game section When the extension is decided, the predetermined information regarding the extension of the designated game section is not displayed, so that it is possible to prevent the player from misunderstanding if the designated game section continues beyond the continuation upper limit of the advantageous section. be able to.

2. Initial invention 2
(A) Problems to be solved by the original invention 2 Same as the original invention 1.
(B) Means for Solving the Problems of Initial Invention 2 (Note that the corresponding embodiments are described in parentheses.)
The original invention (third embodiment; Example 3 in FIG. 55)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) that controls the start and end of an advantageous section and the start and end of an instruction game section, and
It is equipped with an effect control means (sub control board 80) that outputs an effect related to the instruction game section.
The game control means
In the advantageous section, when the continuation upper limit (1500 games) of the advantageous section is reached, the advantageous section is terminated and the advantage section is terminated.
When the start condition of the designated game section is satisfied in the advantageous section, the designated game section is started and the designated game section is started.
In the designated game section, when the condition for extending the designated game section (adding the number of games) is satisfied, the designated game section can be extended.
Information about the indicated game section (AT counter value, additional counter value, upper limit counter value, etc.) is transmitted to the effect control means.
When the designated game section or the advantageous section reaches a predetermined threshold value (the total number of AT games is 1500 games), the directed game section becomes the advantageous section based on the information received from the game control means. The feature is that it is possible to output an effect (ending effect) that suggests that the upper limit of the continuation of is approaching.

(C) Effect of Initial Invention 2 According to the initial invention, since an effect suggesting that the indicated game section is approaching the continuation upper limit of the advantageous section is output, the indicated game section continues beyond the continuation upper limit of the advantageous section. You can tell the player not to do so.

3. 3. Initial invention 3
(A) Problems to be solved by the original invention 3 Same as the original invention 1.
(B) Means for Solving the Problems of Initial Invention 3 (Note that the corresponding embodiments are described in parentheses.)
The original invention (third embodiment; Example 1 in FIG. 55)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) that controls the start and end of an advantageous section and the start and end of an instruction game section, and
It is equipped with an effect control means (sub control board 80) that outputs an effect related to the instruction game section.
The game control means
In the advantageous section, when the continuation upper limit (1500 games) of the advantageous section is reached, the advantageous section is terminated and the advantage section is terminated.
When the start condition of the designated game section is satisfied in the advantageous section, the designated game section is started and the designated game section is started.
In the designated game section, when the conditions for extending the designated game section are satisfied, the designated game section can be extended.
Information about the indicated game section (AT counter value, additional counter value, upper limit counter value, etc.) is transmitted to the effect control means.
The effect control means
Based on the information received from the game control means, if the extension of the designated game section does not exceed the continuation upper limit of the advantageous section, the information regarding the extension of the designated game section (the number of remaining AT games after addition) is displayed. ,
Based on the information received from the game control means, when the instruction game section is extended to exceed the continuation upper limit of the advantageous section, or after the instruction game section reaches the continuation upper limit of the advantageous section, the extension of the instruction game section is extended. When it is decided, the information regarding the extension of the indicated game section (the number of remaining AT games after the addition) is not displayed.

(C) Effect of Initial Invention 3 According to the original invention, when the instruction game section is extended to exceed the continuation upper limit of the advantageous section, or after the instruction game section reaches the continuation upper limit of the advantageous section, the instruction game section When the extension is decided, the information regarding the extension of the designated game section is not displayed, so that it is possible to prevent the player from being misunderstood if the designated game section continues beyond the continuation upper limit of the advantageous section.

4. Initial invention 4
(A) Problems to be solved by the original invention 4 Same as the original invention 1.
(B) Means for Solving the Problem of Initial Invention 4 (Note that the corresponding embodiment is described in parentheses.)
The first solution (third embodiment; Example 4 in FIG. 55) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) that controls the start and end of an advantageous section and the start and end of an instruction game section, and
It is equipped with an effect control means (sub control board 80) that outputs an effect related to the instruction game section.
The game control means
In the advantageous section, when the continuation upper limit (1500 games) of the advantageous section is reached, the advantageous section is terminated and the advantage section is terminated.
When the start condition of the designated game section is satisfied in the advantageous section, the designated game section is started and the designated game section is started.
In the designated game section, when the conditions for extending the designated game section are satisfied, the designated game section can be extended.
Information about the indicated game section (AT counter value, additional counter value, upper limit counter value, etc.) is transmitted to the effect control means.
The effect control means is characterized in that it displays game information (such as "it will end in 10 more games") indicating that the instruction game section is not executed beyond the continuation upper limit of the advantageous section.

The second solution is, in the first solution,
The effect control means exceeds the continuation upper limit of the advantageous section when the instruction game section is extended based on the information received from the game control means, or after the instruction game section reaches the continuation upper limit of the advantageous section. When the extension of the designated game section is decided, the game information is displayed.

(C) Effect of Initial Invention 4 According to the initial invention, it is possible to prevent the player from being misunderstood if the indicated game section continues beyond the continuation upper limit of the advantageous section.

5. Initial invention 5
(A) Problem to be Solved by Initial Invention 5 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed. Here, when an upper limit (for example, the upper limit number of games) is set in the advantageous section, the upper limit of the advantageous section may be exceeded as a result of adding the number of games during the advantageous section and AT. Need to be eliminated.
The problem to be solved by the initial invention is to prevent the indicated game section (AT, etc.) from exceeding the upper limit of the advantageous section.

(B) Means for Solving the Problem of Initial Invention 5 (Note that the corresponding embodiments are described in parentheses.)
The original invention (third embodiment; FIGS. 44 to 46)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means
After starting the advantageous section, when the continuation upper limit (1500 games) of the advantageous section is reached (for example, when "Yes" in step S443 in FIG. 44), the advantageous section is ended.
When the start condition of the designated game section is satisfied in the advantageous section, the designated game section is started and the designated game section is started.
In the designated game section, it is possible to decide whether or not to extend the designated game section.
When it is decided to extend the designated game section and the designated game section has reached the continuation upper limit of the advantageous section before the decision of the extension (for example, when "Yes" in step S451 of FIG. 44), It is characterized by clearing the decision result related to the extension.

(C) Effect of Initial Invention 5 According to the original invention, even if it is decided to extend the indicated game section, if the continuation upper limit of the advantageous section is reached, the decision result relating to the extension is given. Since it is cleared, it is possible to prevent the indicated game section from exceeding the continuation upper limit of the advantageous section.

6. Initial invention 6
(A) Problem to be Solved by Initial Invention 6 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed. Here, when an upper limit (for example, the upper limit number of games) is set in the advantageous section, the upper limit of the advantageous section may be exceeded as a result of adding the number of games during the advantageous section and AT.
The problem to be solved by the initial invention is to make it difficult for the indicated game section or the advantageous section to reach the upper limit of the advantageous section.

(B) Means for Solving the Problem of Initial Invention 6 (Note that the corresponding embodiments are described in parentheses.)
The original invention (third embodiment; FIGS. 47 to 49)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means
After starting the advantageous section, when the continuation upper limit (1500 games) of the advantageous section is reached, the advantageous section is ended and the advantageous section is ended.
When the start condition of the designated game section is satisfied in the advantageous section, the designated game section is started and the designated game section is started.
In the designated game section, it is possible to decide whether or not to extend the designated game section.
It is equipped with an extension determination table (lottery table A or B) used when determining the degree of extension of the designated game section.
The extension decision table is
at least,
The first extension decision table (lottery table A in FIGS. 47 to 49) and
It has a second extension determination table (lottery table B in FIGS. 47 to 49) in which the expected value of the degree of extension (additional number) to be determined is smaller than that of the first extension determination table.
Until the designated game section or advantageous section reaches a predetermined threshold value (the number of AT games is 1000 games), the degree of extension is determined using the first extension determination table, and the designated game section or advantageous section is the predetermined threshold value. When it reaches, the degree of extension is determined using the second extension determination table.

(C) Effect of Initial Invention 6 According to the initial invention, when the indicated game section or the advantageous section reaches a predetermined threshold value, the degree of extension is determined using an extension determination table in which the expected value of the degree of extension is small. Therefore, it is possible to make it difficult for the indicated game section to reach the continuation upper limit of the advantageous section.

7. Initial invention 7
(A) Problems to be solved by the original invention 7 Same as the original invention 6.
(B) Means for Solving the Problem of Initial Invention 7 (Note that the corresponding embodiment is described in parentheses.)
The original invention (third embodiment; FIGS. 50 to 52)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means
Equipped with a role lottery means (61) for drawing a role
Based on the winning combination in the combination drawing by the combination lottery means, it is possible to decide whether or not to extend the designated game section.
When the first combination (for example, small combination E1) is won in the combination lottery by the combination lottery means, the degree of extension (additional number) determined compared to when the second combination (for example, small combination D) is won. Expected value is high,
If the designated game section or advantageous section does not reach a predetermined threshold value (the number of AT games is 1000 games) and the first combination is won, the instruction game section is extended based on the winning of the first combination. The degree is determined (step S541 in FIGS. 50 to 52), and the degree is determined.
When the designated game section or advantageous section has not reached the predetermined threshold and the second combination is won, the degree of extension of the designated game section is determined based on the winning of the second combination.
When the designated game section or the advantageous section has reached the predetermined threshold value and the first combination is won, the degree of extension of the designated game section is determined in the same manner as when the second combination is won (FIG. 50). ~ In FIG. 52, step S543)
It is characterized by that.

(C) Effect of Initial Invention 7 According to the original invention, when the indicated game section or advantageous section reaches a predetermined threshold value, the extension of the indicated game section is extended so that the expected value of the degree of extension determined becomes smaller. Since the degree is determined, it is possible to make it difficult for the indicated game section to reach the continuation upper limit of the advantageous section.

8. Initial invention 8
(A) Problem to be Solved by Initial Invention 8 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed, and further to set an upper limit (for example, the upper limit number of games) in the advantageous section.
Further, an external signal indicating AT is output during AT, and an external signal indicating special game is output during special game. These external signals and when the upper limit of the advantageous section is reached Therefore, it is necessary to prevent the on / off timing of the external signal from becoming unnatural.
The problem to be solved by the initial invention is to prevent the on / off of the external signal indicating the designated game section and the external signal indicating the special game from becoming unnatural when the upper limit of the advantageous section is reached.

(B) Means for Solving the Problems of the Initial Invention 8 (Note that the corresponding embodiments are described in parentheses).
The first solution (fourth embodiment; FIG. 57) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means
A role lottery means (61) for drawing a role including a special role (BB) for shifting to a special game (BB game), and
Equipped with an external signal transmission means (70)
A special game is executed based on winning a special role by the above-mentioned role lottery means,
The external signal transmitting means
When the designated game section is started, the first external signal (external signal 2) indicating the designated game section is turned on, and when the designated game section is finished, the first external signal is turned off.
When the special game is started, the second external signal (external signal 1) indicating the special game is turned on, and when the special game is finished, the second external signal is turned off.
When the continuation upper limit of the advantageous section is reached during the designated game section and not during the special game, the first external signal is turned off (Example 1 in FIG. 57).
When a special combination is won during the indicated game section and the continuation upper limit of the advantageous section is reached during the special game, the first external signal and the second external signal are turned off when the special game is completed (FIG. 57). Example 2)
It is characterized by that.

The second solution is, in the first solution,
Equipped with an advantageous section display device (advantageous section display LED77) indicating that the section is advantageous.
When the continuation upper limit of the advantageous section is reached, the display indicating that the advantageous section is an advantageous section by the advantageous section display device is terminated even during the special game (Example 2 in FIG. 57).
It is characterized by that.

(C) Effect of Initial Invention 8 According to the initial invention, even when the special game crosses the continuation upper limit of the advantageous section, the first external signal indicating the indicated game section can be turned off at a natural timing. ..

9. Initial invention 9
(A) Problem to be Solved by Initial Invention 9 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed, and further to set an upper limit (for example, the upper limit number of games) in the advantageous section.
Further, although an external signal indicating AT is output during AT, how to control the external signal indicating AT when AT is executed until the upper limit of the advantageous section is reached is a problem. It becomes.
The problem to be solved by the initial invention is to appropriately control an external signal indicating the designated game section when the designated game section is executed until the upper limit of the advantageous section is reached.

(B) Means for Solving the Problems of the Initial Invention 9 (Note that the corresponding embodiments are described in parentheses.)
The original invention (fourth embodiment; FIG. 58)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means includes an external signal transmission means (70).
The external signal transmitting means
When the designated game section is started, a predetermined external signal indicating the designated game section is turned on, and when the designated game section is finished, the predetermined external signal is turned off.
When the continuation upper limit of the advantageous section is reached during the indicated game section, the predetermined external signal is turned off.

(C) Effect of Initial Invention 9 According to the initial invention, it is possible to match the timing when the continuation upper limit of the advantageous section is reached and the timing when the predetermined external signal indicating the designated game section is turned off.

10. Initial invention 10
(A) Problem to be Solved by Initial Invention 10 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed, and further to set an upper limit (for example, the upper limit number of games) in the advantageous section.
Further, an external signal indicating AT is output during AT, but since the start and end of the special game and the time when the upper limit of the advantageous section is reached are mixed with this external signal, the external signal of the external signal It is necessary to prevent the on / off timing from becoming unnatural.
The problem to be solved by the initial invention is to prevent the on / off of the external signal indicating the designated game section from becoming unnatural when the upper limit of the advantageous section is reached, the start and end of the special game, and the instruction game section.

(B) Means for Solving the Problems of the Initial Invention 10 (Note that the corresponding embodiments are described in parentheses.)
The original invention (fourth embodiment; FIGS. 57 and 58)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means
A role lottery means (61) for drawing a role including a special role (BB) for shifting to a special game (BB game), and
Equipped with an external signal transmission means (70)
A special game is executed based on winning a special role by the above-mentioned role lottery means,
The external signal transmitting means
When the designated game section is started, a predetermined external signal (external signal 2) indicating the designated game section is turned on, and when the designated game section is ended, the predetermined external signal is turned off (Example 1 in FIG. 57). ,
When the continuation upper limit of the advantageous section is reached during the designated game section and not during the special game, the predetermined external signal is turned off (FIG. 58).
When a special combination is won during the designated game section and the continuation upper limit of the advantageous section is reached during the special game, the predetermined external signal is turned off when the special game is completed (Example 2 in FIG. 57).
It is characterized by that.

(C) Effect of Initial Invention 10 According to the initial invention, the timing of reaching the continuation upper limit of the advantageous section, the end of the special game, and the timing of turning off the predetermined external signal indicating the designated game section are matched. Can be done.

11. Initial invention 11
(A) Problem to be Solved by Initial Invention 11 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed.
When such an advantageous section is provided, the problem is what kind of trigger the AT starts and what kind of trigger the AT ends.
The problem to be solved by the initial invention is to enable a wide range of game playability design by giving a feature to the start and end triggers of the indicated game section in the advantageous section.

(B) Means for Solving the Problems of the Initial Invention 11 (Note that the corresponding embodiments are described in parentheses.)
The original invention (fifth embodiment; FIG. 60 (a)) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means includes a combination lottery means (61) for drawing a combination.
As a lottery state (RT) in which a combination is drawn by the combination lottery means, a first lottery state (for example, RT5) and a second lottery state (for example, RT2) in which the winning probabilities of at least one replaying combination are different are provided.
In the advantageous section and the first lottery state, the designated game section can be executed.
In the designated game section and the first lottery state, when the player shifts to the second lottery state by satisfying the predetermined conditions (digesting 50 games), both the advantageous section and the designated game section are terminated. It is a feature.

(C) Effect of Initial Invention 11 According to the initial invention, the advantageous section or the designated game section can be started or ended with the transition of the lottery state as an opportunity. This enables a wide range of playability designs.

12. Initial invention 12
(A) Problems to be solved by the original invention 12 Same as the original invention 11.
(B) Means for Solving the Problems of the Initial Invention 12 (Note that the corresponding embodiments are described in parentheses.)
The first solution (fifth embodiment; FIG. 61) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
As the states controlled by the game control means, at least a first control state (precursor, CZ, AT, etc.) and a second control state (normal) are provided.
It is possible to shift to the first control state (precursor) on condition that it is an advantageous section.
In the first control state (AT), the indicated game section is started and the instruction game section is started.
When the conditions for shifting to the second control state (normal) are satisfied in the advantageous section and the first control state (AT pullback period, CZ, CZ pullback period), the state shifts to the second control state and the advantageous section ends. It is characterized by doing.
The second solution is, in the first solution,
When the transition condition to the second control state is satisfied in the first control state which is the instruction game section, the transition to the second control state is performed, and both the advantageous section and the instruction game section are terminated. ..

(C) Effect of Initial Invention 12 According to the initial invention, the advantageous section or the designated game section can be started or ended with the transition of the control state as an opportunity. This enables a wide range of playability designs.

13. Initial invention 13
(A) Problems to be solved by the original invention 13 Same as the original invention 11.
(B) Means for Solving the Problems of Initial Invention 13 (Note that the corresponding embodiments are described in parentheses.)
The first solution (fifth embodiment; FIGS. 60 and 61) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
As a game state (RT (lottery state), AT, CZ, omen, normal (control state)) controlled by the game control means, at least a first game state and a second game state are provided.
In the first game state (RT5 and AT), the advantageous section can be executed and the indicated game section can be started.
It is characterized in that when the designated game section is started in the first game state and the predetermined number of games is exhausted, the game shifts to the second game state (RT2 and normal) and the designated game section ends.

The second solution is, in the first solution,
When the predetermined number of games is exhausted in the designated game section of the first game state, the player shifts to the second game state and ends both the advantageous section and the designated game section.

(C) Effect of Initial Invention 13 According to the initial invention, the designated gaming section can be started or ended with the transition of the gaming state as an opportunity. This enables a wide range of playability designs.

14. Initial invention 14
(A) Problem to be Solved by Initial Invention 14 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed, and further to set an upper limit (for example, the upper limit number of games) in the advantageous section.
However, the playability that only ends when the upper limit of the advantageous section is reached is not sufficient to differentiate from other models.
The problem to be solved by the initial invention is to execute a game that is not bound by the upper limit of the advantageous section by making the advantageous section intermittently feasible even in the advantageous section having an upper limit.

(B) Means for Solving the Problems of the Initial Invention 14 (Note that the corresponding embodiments are described in parentheses.)
The first solution (sixth embodiment; FIG. 62) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means includes a combination lottery means (61) for drawing a combination.
As the lottery state in which the combination is drawn by the combination lottery means, the first lottery state (RT3), the second lottery state (RT6), and the third lottery state (for example, RT2) in which the winning probabilities of at least one re-game combination are different are different. )
In the designated game section in the first lottery state, when a predetermined condition is satisfied before reaching the continuation upper limit of the advantageous section (when replay 06 is displayed), the game shifts to the second lottery state, and the advantageous section and the designated game section are entered. Finish both sides,
In the second lottery state, it is determined whether or not to start the normal section and shift to the advantageous section (execute the lottery of "1/32").
In the normal section of the second lottery state, when a specific condition for shifting to the advantageous section is satisfied (when the lottery of "1/32" is won), the section shifts to the advantageous section and shifts to the advantageous section. It is possible to start the instruction game section based on
In the normal section of the third lottery state, when the specific condition is satisfied, the section shifts to the advantageous section, but the designated game section is not started based on the shift to the advantageous section.

The second solution (sixth embodiment; FIG. 62) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, there is an instruction game section (AT) in which the instruction function operating game is always executed or the execution frequency is increased in the game having the advantageous operation mode of the stop switch.
A game control means (main control board 50) for controlling the start and end of an advantageous section and the start and end of an instruction game section is provided.
The game control means includes a combination lottery means (61) for drawing a combination.
As the lottery state in which the combination is drawn by the combination lottery means, the first lottery state (RT3), the second lottery state (RT6), and the third lottery state (non-RT) in which the winning probabilities of at least one re-game combination are different are different. )
In the designated game section in the first lottery state, when a predetermined condition is satisfied before reaching the continuation upper limit of the advantageous section (when replay 06 is displayed), the game shifts to the second lottery state, and the advantageous section and the designated game section are entered. Finish both sides,
In the second lottery state, it is determined whether or not to start the normal section and shift to the advantageous section (execute the lottery of "1/32").
In the second lottery state, when the end condition of the second lottery state is satisfied (when 50 games are exhausted), the process shifts to the third lottery state.
There is a case where it shifts to the third lottery state without going through the second lottery state,
Even in the normal section of the third lottery state, which has shifted without going through the second lottery state, it is decided whether or not to shift to the advantageous section.
When it is decided to shift to the advantageous section in the second lottery state, the designated game section can be started after that.
When it is decided to shift to the advantageous section without going through the second lottery state, the designated game section is not started.

(C) Effect of Initial Invention 14 According to the initial invention, the designated game section in the first lottery state is shifted to the second lottery state to end the advantageous section and the designated game section, and then the section is shifted to the advantageous section again. Since it is possible and the indicated game section can be started, it is possible to execute a game that is not bound by the upper limit of the advantageous section.
In addition, by adding a condition that allows the instruction game section to be started (the first solution means satisfying a specific condition in the second lottery state, and the second solution means go through the second lottery state). It is possible to prevent the designated game section from becoming more likely to be executed than necessary.

15. Initial invention 15
(A) Problem to be Solved by Initial Invention 15 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed. Further, it is proposed to indicate to the player that the advantageous section is an advantageous section during the advantageous section. Here, it is conceivable to provide a case where an advantageous section is started based on the winning of a special role. In this case, it is desired that the player's expectation is not lowered even during the special game.
The problem that the invention initially tries to solve is to be able to continue to give the player a sense of expectation even during the special game.

(B) Means for Solving the Problems of the Initial Invention 15 (Note that the corresponding embodiments are described in parentheses.)
The first solution (eighth embodiment; FIGS. 64 and 65) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Advantageous section display means (advantageous section display LED77) for displaying that it is an advantageous section, and
Means (setting key switch 12, setting switch 13, etc.) for determining one of a plurality of setting values (setting 1 to setting 6), and
The role lottery means (61) for drawing the role, and
It is equipped with an effect control means (sub control board 80) that controls the output of the effect.
The role lottery means draws a role so as to have a case where a special role (1BBA) for shifting to a special game (1BBA game) is won.
The winning probability of the special role is the same for all set values,
It is possible to start an advantageous section based on winning a special role,
After winning the special role, the game shifts to the special game based on the fact that the combination of symbols corresponding to the special role has stopped.
The advantageous section started based on winning the special role ends by the end of the special game (Example 1 or 2 in FIG. 64) and continues after the end of the special game (FIG. 65). Example 3) and
The effect control means is characterized in that it can output a continuous effect over a plurality of games with respect to the continuation of an advantageous section during a special game.

The second solution is, in the first solution,
The continuous production is characterized in that it suggests whether or not the advantageous section continues even after the end of the special game.

(C) Effect of Initial Invention 15 According to the initial invention, it is possible to give the player a sense of expectation as to whether or not the advantageous section will continue until the end of the special game.

16. Initial invention 16
(A) Problem to be Solved by Initial Invention 16 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed. Further, it is proposed to indicate to the player that the advantageous section is an advantageous section during the advantageous section. Here, it is conceivable to provide a case where an advantageous section is started based on the winning of a special role. In this case, it is desired that the player's expectation is not lowered even after the special game is completed.
The problem that the invention initially tries to solve is to be able to continue to give the player a sense of expectation even after the end of the special game.
(B) Means for Solving the Problems of the Initial Invention 16 (Note that the corresponding embodiments are described in parentheses.)
The first solution (eighth embodiment; FIG. 66) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Advantageous section display means (advantageous section display LED77) for displaying that it is an advantageous section, and
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
The role lottery means (61) for drawing the role, and
It is equipped with an effect control means (sub control board 80) that controls the output of the effect.
The role lottery means draws a role so as to have a case where a special role (1BBA) for shifting to a special game (1BBA game) is won.
The winning probability of the special role is the same for all set values,
It is possible to start an advantageous section based on winning a special role,
After winning the special role, the game shifts to the special game based on the fact that the combination of symbols corresponding to the special role has stopped.
The advantageous section started based on the winning of the special role ends in a predetermined number of games (5 games) after the end of the special game (Example 4), and continues beyond the predetermined number of games (Example 4). 5) and
The effect control means is characterized in that it is possible to output a predetermined effect regarding the continuation of an advantageous section in at least a part of the predetermined number of games after the end of the special game.

The second solution is, in the first solution,
The predetermined effect is an effect that suggests whether or not the advantageous section continues even if the predetermined number of games is exceeded after the end of the special game.

(C) Effect of Initial Invention 16 According to the initial invention, it is possible to give the player a sense of expectation as to whether or not the advantageous section will continue even after the end of the special game.

17. Initial invention 17
(A) Problem to be Solved by Initial Invention 17 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed. Here, it is conceivable to shift to an advantageous section based on the winning of a special role. In this case, the skill of the player cannot be demonstrated only by uniformly starting the advantageous section based on the winning of the special role.
The problem to be solved by the initial invention is to make a difference in the profit regarding the advantageous section depending on the skill of the player when shifting to the advantageous section based on the winning of the special role.

(B) Means for Solving the Problems of the Initial Invention 17 (Note that the corresponding embodiments are described in parentheses.)
The original invention (9th embodiment (FIG. 67)) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Means (setting key switch 12, setting switch 13, etc.) for determining one of a plurality of setting values (setting 1 to setting 6), and
It is equipped with a role lottery means (61) for drawing a role.
The winning combination lottery means draws a winning combination so as to have a specific winning (1BBA + small winning combination E1).
The specific winning is a winning including a special role (1BBA) in which the winning is carried over to the next game until the combination of the symbols is stopped, and a predetermined role (small role E1) in which the winning is not carried over to the next game.
The winning probability of a specific win is the same for all set values,
When it is decided to shift to an advantageous section in a specific winning game (“N” game), and the combination of symbols corresponding to the special role does not stop, and the winning of the special role is carried over to the next game. , The advantage section is started from the game (“N + 2” game) in which the combination of symbols corresponding to the special role carried over to the winning can be stopped.

(C) Effect of Initial Invention 17 According to the original invention, in the first game in which it is decided to shift to an advantageous section and the combination of symbols corresponding to the special combination can be stopped, the symbol corresponding to the special combination It is possible to make a difference in the profit obtained in the advantageous section between the player who stopped the combination and the player who could not stop the combination. As a result, the profit obtained in the advantageous section can be different depending on the skill of the player.

18. Initial invention 18
(A) Problem to be Solved by Initial Invention 18 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed. Here, it is possible to execute the addition of the AT based on the winning of the special role having no setting difference, but it is conceivable that the addition of the AT cannot be executed based on the winning of the special role having the setting difference. ing.
However, in this way, when a special role with a difference in setting is won during AT, there is a problem that the player cannot be expected to add AT.
The problem to be solved by the initial invention is to make it possible to add an instruction game section (AT) even when a special combination having a different setting is won.

(B) Means for Solving the Problems of the Initial Invention 18 (Note that the corresponding embodiments are described in parentheses.)
The original invention (10th embodiment (FIG. 22)) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, the instruction function operating game is always executed in the game having the advantageous operation mode of the stop switch, or the instruction game section (AT) in which the execution frequency is increased, and the instruction game section (AT).
Means (setting key switch 12, setting switch 13, etc.) for determining one of a plurality of setting values (setting 1 to setting 6), and
It is equipped with a role lottery means (61) for drawing a role.
The combination lottery means draws a combination so as to have a case where a special combination (for example, 1BBA) for shifting to a special game (for example, 1BBA game) is won.
After winning the special role, the game shifts to the special game based on the fact that the combination of symbols corresponding to the special role has stopped.
As a lottery state in which a combination is drawn by the combination lottery means, a first lottery state (RT2) and a second lottery state (RT3) in which the winning probabilities of at least one re-game combination are different are provided.
After the end of the special game, in order to shift to the second lottery state, it is necessary to go through the first lottery state.
When shifting to a special game based on winning a special role during the designated game section, the designated game section can be extended based on the transition from the first lottery state to the second lottery state after the end of the special game. year,
When the first lottery state is changed to the second lottery state without shifting to the special game during the designated game section, the designated game section is not extended based on that.

(C) Effect of Initial Invention 18 According to the initial invention, the designated game section can be extended when the state shifts from the first lottery state to the second lottery state, provided that the special game is executed. .. As a result, it is possible to extend the designated game section after the end of the special game regardless of whether or not the winning special combination has a setting difference. Further, it is possible to set so that the designated game section is not extended simply by shifting from the first lottery state to the second lottery state without going through the special game.

19. Initial invention 19
(A) Problem to be Solved by Initial Invention 19 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed. Here, it is desired to provide a new game property by using the instruction function operating game.
The problem to be solved by the initial invention is to provide a new playability by using the instruction function operating game.

(B) Means for Solving the Problems of the Initial Invention 19 (Note that the corresponding embodiments are described in parentheses.)
The first solution (11th embodiment; FIG. 68) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, the instruction function operating game is always executed in the game having the advantageous operation mode of the stop switch, or the instruction game section (AT) in which the execution frequency is increased, and the instruction game section (AT).
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
The role lottery means (61) for drawing the role, and
It is equipped with an effect control means (sub control board 80) that controls the output of the effect.
The combination lottery means draws a combination so as to have a case where a predetermined combination (small combination E1) is won.
The winning probability of a predetermined combination is the same for all set values,
When a predetermined combination is won in the combination lottery by the combination lottery means, the next game shifts to an advantageous section.
The advantageous section that shifts based on the winning of the prescribed role is
A first advantageous section (in FIG. 68, Example 1) in which the instruction function operating game is executed at least once but the instruction game section is not executed.
It has a second advantageous section (Example 2 in FIG. 68) for executing the indicated game section, and has.
The effect control means is characterized in that a continuous effect is output in an advantageous section shifted based on the winning of a predetermined combination.

The second solution is, in the first solution,
The effect control means is characterized in that the continuous effect is started after one instruction function operation game is executed.
The third solution is in the first or second solution.
The continuous effect is characterized in that it is an effect that suggests whether it is a first advantageous section or a second advantageous section.

(C) Effect of Initial Invention 19 According to the original invention, there are cases where the instruction game section is executed even after shifting to the advantageous section, and cases where the instruction function operation game is executed at least once but the instruction game section is not executed. Therefore, it is possible to give the player a sense of expectation even after shifting to the advantageous section. As a result, it is possible to prevent the game from being limited to the playability of shifting to / not shifting to the advantageous section.

20. Initial invention 20
(A) Problems to be Solved by the Initial Invention 20 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been considered to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed. Here, it is conceivable to set an upper limit on the advantageous section. On the other hand, even if the section shifts to the advantageous section, it is conceivable that the condition device (combination) having an advantageous operation mode of the stop switch is not won.
The problem to be solved by the initial invention is to balance the end condition (including the upper limit) of the advantageous section and the execution of the instruction function operating game.

(B) Means for Solving the Problems of the Initial Invention 20 (Note that the corresponding embodiments are described in parentheses.)
The original invention (11th embodiment; FIG. 69)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
It is equipped with a role lottery means (61) for drawing a role.
The combination lottery means draws a combination so as to have a case where a predetermined combination (small combination E1) is won.
The winning probability of a predetermined combination is the same for all set values,
When a predetermined combination is won in the combination lottery by the combination lottery means, the next game may shift to an advantageous section.
When the predetermined end condition of the advantageous section is reached in the advantageous section, the advantageous section is ended and the advantageous section is terminated.
When the upper limit of the advantageous section is reached in the advantageous section, the advantageous section is terminated and the advantage section is terminated.
In the advantageous section, if there is no game having an advantageous operation mode of the stop switch by the time the predetermined end condition is reached, the advantageous section is ended until at least one instruction function operation game is executed. However, when there is no game having an advantageous operation mode of the stop switch before reaching the upper limit of the advantageous section (Example 3 in FIG. 69), it is advantageous without executing the instruction function operating game. End the section (Example 4 in FIG. 69)
It is characterized by that.

(C) Effect of Initial Invention 20 According to the original invention, "execute at least one instruction function operating game" and "end the advantageous section when the upper limit of the advantageous section is reached" in the advantageous section. You can balance it with things.

21. Initial invention 21
(A) Problem to be Solved by Initial Invention 21 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed. Here, it is conceivable to set an upper limit in the advantageous section. Furthermore, it is conceivable that a special role will be won during the advantageous section and the game will shift to a special game. In this case, if the upper limit of the advantageous section is reached during the execution of the special game, the advantageous section ends at that point, which may give the player a sense of discomfort.
The problem to be solved by the initial invention is to prevent the player from feeling uncomfortable when the upper limit of the advantageous section is reached during the execution of the special game.

(B) Means for Solving the Problems of the Initial Invention 21 (Note that the corresponding embodiments are described in parentheses.)
The original invention (12th embodiment; FIG. 70)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
The role lottery means (61) for drawing the role, and
It is equipped with an effect control means (sub control board 80) that controls the output of the effect.
The combination lottery means draws a combination so as to have a case where a special combination (for example, 1BBA) for shifting to a special game (for example, 1BBA game) is won.
The effect control means
When a predetermined condition is satisfied in the advantageous section (for example, when the upper limit of the advantageous section is approached), a specific effect (ending effect) is started.
When the upper limit of the advantageous section (1500 games) is reached during the output of the specific effect, the advantageous section is terminated and the specific effect is terminated.
Even when a special role is won during the output of the specific effect and the game shifts to the special game, the specific effect is continued.
When the upper limit of the advantageous section is reached during the special game and during the output of the specific effect, the advantageous section is terminated, but the specific effect is continued until the special game is completed.

(C) Effect of Initial Invention 21 According to the initial invention, when the upper limit of the advantageous section is reached during the special game, the advantageous section is terminated, but the output is performed during the advantageous section until the special game is completed. Continue the specific production. As a result, it is possible to prevent the specific effect in the advantageous section from suddenly ending in the middle of the special game, and to prevent the player from feeling uncomfortable.

22. Initial invention 22
(A) Problems to be Solved by the Initial Invention 22 The initial invention relates to a slot machine having a plurality of lottery states in which at least one replaying combination has a different winning probability.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Further, for example, a slot machine that shifts RT (lottery state) in order to execute AT is known.
In the conventional technique, it is known that the RT transition is performed, for example, by winning a specific condition device and stopping the combination of a specific symbol. However, there is a problem that the ease of RT migration may differ depending on the set value.
The problem to be solved by the initial invention is to prevent the ease of migration of RT from being affected by the set value.

(B) Means for Solving the Problems of the Original Invention 22 (Note that the corresponding embodiments are described in parentheses.)
The first solution (13th embodiment; FIG. 71) is
Means (setting key switch 12, setting switch 13, etc.) for determining one of a plurality of setting values (setting 1 to setting 6), and
It is equipped with a role lottery means (61) for drawing a role.
As the lottery state in which the combination is drawn by the combination lottery means, the first lottery state (RT2), the second lottery state (RT3), and the third lottery state (RT4) in which the winning probabilities of at least one re-game combination are different are defined. Prepare,
In the first lottery state, the combination lottery means draws a combination so as to have a case where a specific combination (replay group B) is won.
When a specific combination is won in the first lottery state and the combination of predetermined symbols is stopped, the process shifts to the second lottery state.
The winning probability of a specific combination in the first lottery state is the same for all set values,
The combination lottery means draws a combination so as to have a case where a special combination (for example, 1BBB) for shifting to a special game (for example, 1BBB game) is won.
If a special role is won in any of the lottery states and the combination of symbols corresponding to the special role does not stop, the game shifts to the third lottery state.
The winning probability of a special role is characterized by being different depending on the set value.

The second solution is, in the first solution,
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, the instruction function operating game is always executed in the game having the advantageous operation mode of the stop switch, or the instruction game section (AT) in which the execution frequency is increased is provided.
The instruction game section can be executed at least in the second lottery state,
When a special role is won during the designated game section, it is necessary to go through the first lottery state in order to shift to the second lottery state after the end of the special game.
After the special game is completed, the designated game section can be extended based on the transition from the first lottery state to the second lottery state.

The third solution is in the first or second solution.
The instruction game section can be executed in the third lottery state,
When the designated game section is in the third lottery state, the designated game section is not extended.

(C) Effect of Initial Invention 22 According to the initial invention, the winning probability of a specific combination that triggers the transition from the first lottery state to the second lottery state is the same for all set values, so that from the first lottery state. The ease of transition to the second lottery state can be prevented from being affected by the set value.

23. Initial invention 23
(A) Problems to be solved by the original invention 23 Same as the original invention 22.
(B) Means for Solving the Problems of the Initial Invention 23 (Note that the corresponding embodiments are described in parentheses.)
The original invention (13th embodiment; FIG. 71)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
In the advantageous section, the instruction function operating game is always executed in the game having the advantageous operation mode of the stop switch, or the instruction game section (AT) in which the execution frequency is increased, and the instruction game section (AT).
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
It is equipped with a role lottery means (61) for drawing a role.
As a lottery state in which a combination is drawn by the combination lottery means, a first lottery state (RT2) and a second lottery state (RT3) in which the winning probabilities of at least one re-game combination are different are provided.
The instruction game section can be executed at least in the second lottery state,
The combination lottery means draws a combination so as to have a case where a specific replay combination (replay group C) is won in the second lottery state.
When a specific re-game combination is won in the second lottery state and the combination of predetermined symbols is stopped, the game shifts to the first lottery state.
The winning probability of a specific re-game combination in the second lottery state is the same for all set values.
In the second lottery state, the combination lottery means draws a lottery so as to have a case where a predetermined replay combination (replay A) is won.
Even if the predetermined re-game combination is won in the second lottery state and the combination of symbols corresponding to the predetermined re-game combination is stopped, the first lottery state is not entered.
The winning probability of the predetermined re-game combination in the second lottery state is characterized by being different depending on the set value.

(C) Effect of Initial Invention 23 According to the initial invention, the winning probability of a specific replaying combination that triggers the transition of the lottery state is the same for all the set values, so that the ease of transition of the lottery state is the set value. Can be unaffected by. Further, in the second lottery state, the winning probability of a predetermined re-game combination that does not trigger the transition to the lottery state is changed according to the set value. Therefore, for example, the higher the setting, the higher the ball output rate in the indicated game section. can do.

24. Initial invention 24
(A) Problems to be solved by the original invention 24 Same as the original invention 22.
(B) Means for Solving the Problems of the Initial Invention 24 (Note that the corresponding embodiments are described in parentheses.)
The first solution (13th embodiment; FIG. 71) is
The role lottery means (61) for drawing the role, and
It is equipped with means (setting key switch 12, setting switch 13, etc.) for determining one of a plurality of setting values.
As a lottery state in which a combination is drawn by the combination lottery means, a first lottery state (RT1) and a second lottery state (RT2) in which the winning probabilities of at least one re-game combination are different are provided.
When the predetermined conditions are met in the first lottery state, the process shifts to the second lottery state.
In the first lottery state, the combination lottery means draws a combination so as to have a case where the first combination (small combination B group) having the possibility of satisfying the predetermined condition is won.
The winning probability of the first winning combination in the first lottery state is the same for all set values.
In the first lottery state, the combination lottery means draws a combination so as to have a case where a second combination (small combination D) that does not have the possibility of satisfying the predetermined condition is won.
The winning probability of the second winning combination in the first lottery state differs depending on the set value.
In the first lottery state, the combination lottery means draws a combination so as to have a case where a third combination (small combination E1) that does not have the possibility of satisfying the predetermined condition is won.
The winning probability of the third winning combination in the first lottery state is the same for all set values.
The maximum payout when the combination of symbols corresponding to the first role is stopped is D1 (9 cards), and the maximum payout when the combination of symbols corresponding to the second role is stopped is D2 (15 cards), which is the third role. When the maximum payout when the combination of corresponding symbols is stopped is D3 (2 cards)
D2>D1> D3
It is characterized by satisfying.

The second solution is, in the first solution,
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, it is equipped with an advantageous section in which the instruction function operating game can be executed.
When the third combination is won in the combination lottery by the combination lottery means during the normal section, it is characterized by having a possibility of shifting to an advantageous section.

(C) Effect of Initial Invention 24 According to the initial invention, the winning probability of the first winning combination having the possibility of shifting to the second lottery state in the first lottery state is the same for all set values, so that the first lottery state It is possible to prevent the ease of transition from the second lottery state to the second lottery state from being affected by the set value.
Further, since the winning probability of the second winning combination with the largest payout is made different according to the set value, the payout rate can be greatly changed according to the set value.

25. Initial invention 25
(A) Problems to be Solved by the Initial Invention 25 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed. Here, it is conceivable to change the end condition of the advantageous section after starting the advantageous section. Further, in the advantageous section, it is considered necessary to execute the instruction function operating game at least once.
The problem to be solved by the initial invention is to make it possible to end the advantageous section at an intended timing while making it possible to change the end condition of the advantageous section.

(B) Means for Solving the Problems of the Initial Invention 25 (Note that the corresponding embodiments are described in parentheses.)
The original invention (14th embodiment; FIG. 72)
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, there is an advantageous section in which it is necessary to execute the instruction function operating game at least once.
When the conditions for transition to the advantageous section are satisfied in the normal section, the transition to the advantageous section is performed.
When a predetermined condition (extension condition of the advantageous section) is satisfied during the advantageous section, the end condition (30 games) of the advantageous section up to that point is changed (50 games are added).
When the end condition of the advantageous section is changed based on the condition that the predetermined condition is satisfied after the instruction function operation game is executed at least once in the advantageous section, the instruction function operation game is performed 1 after the end condition is changed. It is possible to finish the advantageous section without executing it many times (Example 1 in FIG. 72).
If the end condition of the advantageous section is changed based on satisfying the predetermined conditions after shifting to the advantageous section and before executing the first instruction function operating game, at least once after the change of the end condition. If the instruction function operation game is not executed, the advantageous section cannot be ended even if the end condition is satisfied (Example 2 in FIG. 72).
It is characterized by that.

(C) Effect of Initial Invention 25 According to the original invention, after starting the advantageous section, the end condition of the advantageous section up to that point can be changed. Therefore, the end condition of the advantageous section is not fixed and the advantageous section is not fixed. Can be prevented from becoming monotonous. In addition, while making it possible to change the end condition of the advantageous section, at the timing intended by the advantageous section because the instruction function operating game has not been executed even once even though the end condition of the advantageous section is satisfied. It is possible to suppress the inability to finish.

26. Initial invention 26
(A) Problem to be Solved by Initial Invention 26 The initial invention relates to a slot machine provided with an advantageous section capable of executing an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of a stop switch.
In a conventional slot machine, it is known that an AT is managed by a main control board in addition to managing an AT by a sub control board (see, for example, Japanese Patent Application Laid-Open No. 2014-161344).
Recently, it has been proposed to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed. Here, it is conceivable to execute a freeze at the end of the advantageous section. However, if the freeze is uniformly executed even when the advantageous section ends without giving a sufficient benefit to the player, the player may be uncomfortable.
The problem to be solved by the original invention is to properly execute the freeze at the end of the advantageous section.

(B) Means for Solving the Problems of the Initial Invention 26 (Note that the corresponding embodiments are described in parentheses.)
The first solution (15th embodiment; FIG. 73) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game for activating an instruction function for displaying the advantageous operation mode, and a game for operating the instruction function.
Of the game sections, the normal section in which the instruction function operation game is not executed and the normal section
Of the game sections, it is equipped with an advantageous section in which the instruction function operating game can be executed.
When the conditions for transition to the advantageous section are satisfied in the normal section, the transition to the advantageous section is performed.
As the end condition of the advantageous section, there are at least two types of first end condition and second end condition.
The advantageous section of the first end condition has a larger expected value of profit obtained during the advantageous section than the advantageous section of the second end condition.
Equipped with a freeze control means to control the freeze that temporarily stops the progress of the game,
The freeze control means does not execute freeze when the advantageous section ends under the second end condition (CZ end condition), and freezes when the advantageous section ends under the first end condition (AT end condition). It is characterized by executing.

The second solution is, in the first solution,
It is characterized in that during the freeze, the profit obtained during the advantageous section is displayed.

(C) Effect of Initial Invention 26 According to the initial invention, when the freeze is executed according to the expected value of the profit obtained during the advantageous section (when the expected value of the profit obtained during the advantageous section is large), By providing a case where the freeze is not executed (when the expected value of the profit obtained during the advantageous section is small), the freeze can be appropriately executed at the end of the advantageous section.

27. Original invention 27
(A) Problem to be Solved by Initial Invention 27 The initial invention includes an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed, and shifts to this advantageous section. It relates to a slot machine that determines the fact on the main control board side.
In a conventional slot machine, there is known a slot machine that draws a winning combination on the main control board side and determines whether or not to display an advantageous operation mode of a stop switch (for example, Japanese Patent Application Laid-Open No. 2014-1508881). See Gazette).
Here, if the main control board decides whether or not to display the advantageous operation mode of the stop switch, data or a program for performing processing related to this decision is required, and the memory on the main control board side is correspondingly required. Requires capacity.
On the other hand, the memory capacity on the main control board side has a certain limit.
The problem to be solved by the initial invention is to provide an advantageous section in which an instruction function operating game for operating an instruction function for displaying an advantageous operation mode of the stop switch can be executed, and to shift to this advantageous section on the main control board side. In the slot machine determined in the above, the process related to the determination to shift to the advantageous section is appropriately performed within a certain memory capacity range.

(B) Means for Solving the Problems of the Initial Invention 27 (Note that the corresponding embodiments are described in parentheses.)
The first solution (16th embodiment; FIG. 89) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, it has a specific winning number (for example, "44" number) indicating that it will be a specific winning (for example, duplicate winning of 1BBA and small winning combination D) and that it will shift to an advantageous section.
A predetermined storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section is provided.
When the winning number determined by the winning number determining means is a specific winning number and a value other than a predetermined value (“0”) is stored in the predetermined storage means, it is stored in the predetermined storage means. (If "No" in step S1044 of FIG. 89, step S1045 is skipped).
When the winning number determined by the winning number determining means is a specific winning number and a predetermined value is stored in the predetermined storage means, the value stored in the predetermined storage means can be updated. (When "Yes" is set in step S1044 of FIG. 89, the process proceeds to the next step S1045, and the data corresponding to the address indicated by the HL register is stored in the storage area "_NB_CND_AT" of the RWM53).
It is characterized by that.

The second solution is, in the first solution,
Equipped with a specific storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information.
When the winning number determined by the winning number determining means is a specific winning number and a value other than the specific value (“0”) is stored in the specific storage means, the predetermined value is stored in the predetermined storage means. Is stored, the value stored in the predetermined storage means is maintained (when "No" in step S1043 of FIG. 89, steps S1044 to S1046 are skipped, so that the value of "_NB_CND_AT" is ". Even with "0", the value of "_NB_CND_AT" will be maintained)
It is characterized by that.

(C) Effect of Initial Invention 27 According to the original invention, when the winning number is determined to be the specific winning number and a value other than the predetermined value is stored in the predetermined storage means, the value is maintained. When a predetermined value is stored, the value can be updated.
As a result, the winning number can be determined by the same process regardless of whether or not it is decided to shift to the advantageous section, so that the shift to the advantageous section is made within a certain memory capacity range. The processing related to the decision can be performed appropriately.

28. Original invention 28
(A) Problems to be solved by the original invention 28 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 28 (Note that the corresponding embodiments are described in parentheses.)
The first solution (16th embodiment; FIG. 89) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, it has a specific winning number (for example, "44" number) indicating that it will be a specific winning (for example, duplicate winning of 1BBA and small winning combination D) and that it will shift to an advantageous section.
A first storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section, and
It is equipped with a second storage means (RWM53 storage area "_NB_CND_BNS") that can store the winning information of the special role.
When the winning number determined by the winning number determining means is a specific winning number and a value other than a predetermined value (“0”) is stored in the second storage means, it is stored in the first storage means. (When "No" in step S1043 of FIG. 89, the value of "_NB_CND_AT" is maintained by skipping steps S1044 to S1046).
When the winning number determined by the winning number determining means is a specific winning number and a predetermined value is stored in the second storage means, the value stored in the first storage means can be updated. (If "Yes" in step S1043 of FIG. 89, the process proceeds to step S1044, and if "Yes" at this time, the process proceeds to step S1045, so that the value of "_NB_CND_AT" can be updated.)
It is characterized by that.

The second solution is, in the first solution,
When the winning number determined by the winning number determining means is a specific winning number and a value other than the specific value (“0”) is stored in the first storage means, a predetermined value is stored in the second storage means. Is stored, the value stored in the first storage means is maintained (“Yes” in step S1043 in FIG. 89, and even if the process proceeds to step S1044, if “No” in step S1044, step S1045 Will be skipped, so the value of "_NB_CND_AT" will be maintained)
It is characterized by that.

(C) Effect of Initial Invention 28 According to the initial invention, when the winning number is determined to be the specific winning number and a value other than the predetermined value is stored in the second storage means, the first storage means stores the winning number. The stored value is maintained, and when a predetermined value is stored in the second storage means, the value stored in the first storage means can be updated.
As a result, the winning number can be determined by the same process regardless of whether or not the special role has been won and whether or not it has been decided to shift to the advantageous section. Within the range, processing related to the decision to shift to the advantageous section can be appropriately performed.

29. Initial invention 29
(A) Problems to be solved by the original invention 29 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 29 (Note that the corresponding embodiments are described in parentheses.)
The first solution (16th embodiment; FIG. 89) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, it has a specific winning number (for example, "43") indicating that a special role (for example, 1BBA) will be won and that the section will shift to an advantageous section.
A first storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section, and
It is equipped with a second storage means (RWM53 storage area "_NB_CND_BNS") that can store the winning information of the special role.
When the winning number determined by the winning number determining means is a specific winning number, the information stored in the first storage means may be updated based on the information stored in the second storage means. (If it becomes "Yes" in step S1043 of FIG. 89 and becomes "Yes" in step S1044, the process proceeds to step S1045 and the value of "_NB_CND_AT" is updated).
After executing the process relating to the update of the information stored in the first storage means, the information stored in the second storage means is updated (after updating the value of "_NB_CND_AT" in step S1045, "_NB_CND_AT" is updated in step S1046. Update the value of "_NB_CND_BNS")
It is characterized by that.

The second solution (16th embodiment; FIG. 89) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, it has a specific winning number (for example, "44" number) indicating that it will be a specific winning (for example, duplicate winning of 1BBA and small winning combination D) and that it will shift to an advantageous section.
The specific winning is a duplicate winning including a special role (for example, 1BBA) and a specific role (for example, small role D).
A first storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section, and
A second storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information, and
It is equipped with a third storage means (RWM53 storage area "_NB_CND_NOR") that can store winning information of a specific combination.
When the winning number determined by the winning number determining means is a specific winning number, the information stored in the first storage means may be updated based on the information stored in the second storage means. (If it becomes "Yes" in step S1043 of FIG. 89 and becomes "Yes" in step S1044, the process proceeds to step S1045 and the value of "_NB_CND_AT" is updated).
After executing the process relating to the update of the information stored in the first storage means, the information stored in the second storage means and the third storage means is updated (after updating the value of "_NB_CND_AT" in step S1045). , The value of "_NB_CND_BNS" is updated in step S1046, and the value of "_NB_CND_NOR" is updated in step S1047).
It is characterized by that.

(C) Effect of Initial Invention 29 According to the initial invention, when the winning number is determined to be the specific winning number, it is stored in the first storage means based on the information stored in the second storage means. The process related to the update of the information is executed, and then the information stored in the second storage means is updated.
As a result, the winning number can be determined by the same processing regardless of whether or not the special role has been won and whether or not the player has decided to move to the advantageous section.
Further, even if the flag indicating whether or not the winning information of the special role is carried over is not provided, it is possible to determine whether the special role was won in this game or whether the special role was won before the previous game.
Therefore, within the range of a certain memory capacity, it is possible to appropriately perform the process related to the determination of the transition to the advantageous section.

30. Initial invention 30
(A) Problems to be solved by the original invention 30 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 30 (Note that the corresponding embodiments are described in parentheses.)
The first solution (a modified example of the 16th embodiment; FIG. 92) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, it has a specific winning number (for example, "43") indicating that a special role (for example, 1BBA) will be won and that the section will shift to an advantageous section.
When a special role is won, the winning information of the special role is carried over until the combination of symbols corresponding to the special role is stopped.
A first storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section, and
A second storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information, and
It is equipped with a third storage means (RWM53 storage area "_FL_PRD_LOT") that can store carry-over information indicating that the special role winning information has been carried over.
There is a case where the information stored in the second storage means is updated based on the winning number determined by the winning number determining means being the specific winning number (when "Yes" in step S1073, there is a case. Update the value of "_NB_CND_BNS" in step S1074),
When a predetermined value (“0”) is stored in the third storage means after executing the process for updating the information stored in the second storage means, the information stored in the first storage means is stored. There is a case of updating (after determining whether or not the value of "_NB_CND_BNS" is "0" in step S1073 and updating the value of "_NB_CND_BNS" in step S1074, "0" is stored in "_FL_PRD_LOT" in step S1078. If so, the value of "_NB_CND_AT" is updated in step S1079).
It is characterized by that.

The second solution (a modified example of the 16th embodiment; FIG. 92) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, it has a specific winning number (for example, "44" number) indicating that it will be a specific winning (for example, duplicate winning of 1BBA and small winning combination D) and that it will shift to an advantageous section.
The specific winning is a duplicate winning including a special role (for example, 1BBA) and a specific role (for example, small role D).
When a special role is won, the winning information of the special role is carried over until the combination of symbols corresponding to the special role is stopped.
A first storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section, and
A second storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information, and
A third storage means (RWM53 storage area "_FL_PRD_LOT") capable of storing carry-over information indicating that the special role winning information has been carried over, and
It is equipped with a fourth storage means (RWM53 storage area "_NB_CND_NOR") that can store winning information of a specific combination.
There is a case where the information stored in the second storage means and the fourth storage means is updated based on the winning number determined by the winning number determining means being the specific winning number ("Yes" in step S1073. In the case of ", the value of" _NB_CND_BNS "is updated in step S1074, and the value of" _NB_CND_NOR "is updated in step S1075).
When a predetermined value is stored in the third storage means after executing the process related to the update of the information stored in the second storage means and the fourth storage means, the information stored in the first storage means is stored. There is a case of updating (after determining whether or not the value of "_NB_CND_BNS" is "0" in step S1073, updating the value of "_NB_CND_BNS" in step S1074, and updating the value of "_NB_CND_NOR" in step S1075. When "0" is stored in "_FL_PRD_LOT" in step S1078, the value of "_NB_CND_AT" is updated in step S1079).
It is characterized by that.

The third solution is in the first or second solution.
When the winning number determined by the winning number determining means is a specific winning number and a value other than the specific value (“0”) is stored in the second storage means, it is stored in the second storage means. It is characterized by maintaining the value that is set.

(C) Effect of Initial Invention 30 According to the initial invention, based on the fact that the winning number is determined to be the specific winning number, a process relating to the update of the information stored in the second storage means is executed, and then the process is executed. When a predetermined value is stored in the third storage means, the information stored in the first storage means is updated.
As a result, the winning number can be determined by the same process regardless of whether or not the special role has been won and whether or not it has been decided to shift to the advantageous section. Within the range, processing related to the decision to shift to the advantageous section can be appropriately performed.
In addition, after executing the process relating to the update of the information stored in the second storage means, the register storing the winning information of the special combination can be used for other processes.

31. Initial invention 31
(A) Problems to be solved by the original invention 31 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 31 (Note that the corresponding embodiments are described in parentheses.)
The first solution (17th embodiment; FIG. 99) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "38" to "42") capable of executing a transition lottery (two-stage lottery in FIG. 100 and a lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
A predetermined storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section is provided.
When the winning number determined by the winning number determining means is a specific winning number and a value other than a predetermined value (“0”) is stored in the predetermined storage means, the transition lottery is not executed (FIG. If "No" in step S1114 of 99, the two-step lottery is not executed by skipping steps S1115 and S1116).
It is characterized by that.

The second solution (17th embodiment; FIG. 99) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "38" to "42") capable of executing a transition lottery (two-stage lottery in FIG. 100 and a lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
A predetermined storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section is provided.
When the winning number determined by the winning number determining means is a specific winning number and a value other than the predetermined value (“0”) is stored in the predetermined storage means, even if the transition lottery is executed. , The value stored in the predetermined storage means is maintained.

(C) Effect of Initial Invention 31 According to the initial invention, when the winning number is determined to be the specific winning number and a value other than the predetermined value is stored in the predetermined storage means, is the transition to an advantageous section? Do not run the transition lottery to decide whether or not.
As a result, the winning number can be determined by the same process regardless of whether or not it is decided to shift to the advantageous section, so that the shift to the advantageous section is made within a certain memory capacity range. The processing related to the decision can be performed appropriately.

32. Original invention 32
(A) Problems to be solved by the original invention 32 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 32 (Note that the corresponding embodiments are described in parentheses).
The first solution (17th embodiment; FIG. 99) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "38" to "42") capable of executing a transition lottery (two-stage lottery in FIG. 100 and a lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
A specific storage means (RWM53 storage area "_NB_CND_BNS") capable of storing winning information of a special role (for example, 1BBA) is provided.
When the winning number determined by the winning number determining means is a specific winning number and a value other than the specific value (“0”) is stored in the specific storage means, the transition lottery is not executed (FIG. If "No" in step S1113 of 99, the two-step lottery is not executed by skipping steps S1114 to S1116).
It is characterized by that.

The second solution (17th embodiment; FIG. 99) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "38" to "42") capable of executing a transition lottery (two-stage lottery in FIG. 100 and a lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
A first storage means (RWM53 storage area "_NB_CND_AT") capable of storing information regarding the transition to the advantageous section, and
It is provided with a second storage means (RWM53 storage area "_NB_CND_BNS") capable of storing winning information of a special role (for example, 1BBA).
When the winning number determined by the winning number determining means is a specific winning number and a value other than the specific value (“0”) is stored in the second storage means, even if the transition lottery is executed. , It is characterized in that the value stored in the first storage means is maintained.

(C) Effect of Initial Invention 32 According to the initial invention, when the winning number is determined to be the specific winning number, if a value other than the specific value is stored in the specific storage means, is the transition to an advantageous section? Do not run the transition lottery to decide whether or not.
As a result, the winning number can be determined including the specific winning number that can execute the transition lottery regardless of whether or not the special role has been won. Therefore, within a certain memory capacity, an advantageous section It is possible to appropriately perform the process related to the decision to move to.

33. Initial invention 33
(A) Problems to be solved by the original invention 33 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 33 (Note that the corresponding embodiments are described in parentheses.)
The first solution (17th embodiment; FIG. 99) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "38" to "40") capable of executing a transition lottery (two-stage lottery in FIG. 100 and a lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
The specific winning number is a winning number indicating that a special role (for example, 1BBA) has been won.
Equipped with a predetermined storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information.
There is a case where a transition lottery is executed based on the winning number determined by the winning number determining means being a specific winning number (when the winning number is determined to be "38" to "40"). , "Yes" in step S1113, "Yes" in step S1114, and "No" in step S1115, a two-step lottery is executed in step S1116).
After executing the process related to the transition lottery, the winning information of the special combination is stored in the predetermined storage means (after executing the two-step lottery in step S1116, the value of "_NB_CND_BNS" is updated in step S1117).
It is characterized by that.

The second solution (17th embodiment; FIG. 99) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "39" or "40") capable of executing a transition lottery (two-stage lottery in FIG. 100 and lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
The specific winning number is a winning number indicating that a special combination (for example, 1BBA) and a specific combination (small combination D) have been won more than once.
A predetermined storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information, and
It is equipped with a specific storage means (RWM53 storage area "_NB_CND_NOR") that can store winning information of a specific combination.
There is a case where a transition lottery is executed based on the winning number determined by the winning number determining means being a specific winning number (when the winning number is determined to be "39" or "40"). , "Yes" in step S1113, "Yes" in step S1114, and "No" in step S1115, a two-step lottery is executed in step S1116).
After executing the process related to the transition lottery, the winning information of the special combination is stored in the predetermined storage means, and the winning information of the specific combination is stored in the specific storage means (after executing the two-step lottery in step S1116, the step Update the value of "_NB_CND_BNS" in S1117, and update the value of "_NB_CND_NOR" in step S1119)
It is characterized by that.

The third solution is in the first or second solution.
When the winning number determined by the winning number determining means is a specific winning number and the winning information of the special combination is stored in the predetermined storage means, the transition lottery is not executed (in step S1113 of FIG. 99). When "No", steps S1114 to S1117 are skipped, so the two-stage lottery in step S1116 is not executed.)
It is characterized by that.

The fourth solution is the first to third solutions.
Equipped with an advantageous section information storage means (RWM53 storage area "_NB_CND_BNS") capable of storing information regarding the transition to the advantageous section.
When the winning number determined by the winning number determining means is a specific winning number and the information regarding the transition to the advantageous section is stored in the advantageous section information storage means, the transition lottery is not executed (FIG. 99). If "No" in step S1114 of the above, steps S1115 and S1116 are skipped, so the two-stage lottery of step S1116 is not executed.)
It is characterized by that.

(C) Effect of Initial Invention 33 According to the initial invention, when the winning number is determined to be the specific winning number, the transition lottery can be executed. Then, after executing the process related to the transition lottery, the winning information of the special combination is stored in the predetermined storage means.
As a result, even if there is no flag indicating whether or not the winning information of the special role is carried over, it is determined whether the special role was won in this game or the special role was won before the previous game, and the transition is made. It is possible to decide whether or not to execute the lottery.
Therefore, within the range of a certain memory capacity, it is possible to appropriately perform the process related to the determination of the transition to the advantageous section.

34. Original invention 34
(A) Problems to be solved by the original invention 34 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 34 (Note that the corresponding embodiments are described in parentheses.)
The first solution (a modified example of the 17th embodiment; FIG. 103) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "38" to "40") capable of executing a transition lottery (two-stage lottery in FIG. 100 and a lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
The specific winning number is a winning number indicating that a special role (for example, 1BBA) has been won.
When a special role is won, the winning information of the special role is carried over until the combination of symbols corresponding to the special role is stopped.
A first storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information, and
It is equipped with a second storage means (RWM53 storage area "_FL_PRD_LOT") that can store the carry-over information indicating that the special role winning information is carried over.
Based on the fact that the winning number determined by the winning number determining means is the specific winning number, the information stored in the first storage means is updated (the winning number is determined to be "38" to "40". When this is done, the value becomes “Yes” in step S1153 of FIG. 103, and the value of “_NB_CND_BNS” is updated in step S1154).
Based on the information stored in the second storage means, there is a case where the transition lottery is executed and a case where the transition lottery is not executed. If "Yes" is set in step S1158, step S1116 is skipped, so the two-stage lottery in step S1116 is not executed.)
It is characterized by that.

The second solution (a modified example of the 17th embodiment; FIG. 103) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
It is provided with a winning number determining means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining a winning number based on a random number value.
As the winning number, a specific winning number (for example, "39" or "40") capable of executing a transition lottery (two-stage lottery in FIG. 100 and lottery without setting difference in FIG. 101) for determining whether or not to shift to an advantageous section can be executed. Number)
The specific winning number is a winning number indicating that a special combination (for example, 1BBA) and a specific combination (small combination D) have been won more than once.
When a special role is won, the winning information of the special role is carried over until the combination of symbols corresponding to the special role is stopped.
A first storage means (RWM53 storage area "_NB_CND_BNS") capable of storing special role winning information, and
A second storage means (RWM53 storage area "_FL_PRD_LOT") capable of storing carry-over information indicating that the special role winning information has been carried over, and
It is equipped with a third storage means (RWM53 storage area "_NB_CND_NOR") that can store winning information of a specific combination.
Based on the fact that the winning number determined by the winning number determining means is the specific winning number, the information stored in the first storage means and the third storage means is updated (the winning numbers are "38" to "38". When the number is determined to be "40", it becomes "Yes" in step S1153 of FIG. 103, the value of "_NB_CND_BNS" is updated in step S1154, and the value of "_NB_CND_NOR" is updated in step S1155).
Based on the information stored in the second storage means, there is a case where the transition lottery is executed and a case where the transition lottery is not executed. If "Yes" is set in step S1158, step S1116 is skipped, so the two-stage lottery in step S1116 is not executed.)
It is characterized by that.

The third solution is in the first or second solution.
When the winning number determined by the winning number determining means is a specific winning number and the winning information of the special combination is stored in the first storage means, the information stored in the first storage means is maintained. (When "No" in step S1153 of FIG. 103, the value of "_NB_CND_BNS" is maintained by skipping step S1154).
It is characterized by that.

(C) Effect of Initial Invention 34 According to the initial invention, when the winning number is determined to be the specific winning number, the information stored in the first storage means is updated. Then, based on the information stored in the second storage means, there are cases where the transition lottery is executed and cases where the transition lottery is not executed.
As a result, the winning number can be determined including the specific winning number that can execute the transition lottery regardless of whether or not the special role has been won. Therefore, within a certain memory capacity, an advantageous section It is possible to appropriately perform the process related to the decision to move to.
In addition, after updating the information stored in the first storage means, the register storing the winning information of the special combination can be used for other processing.

35. Initial invention 35
(A) Problems to be solved by the original invention 35 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 35 (Note that the corresponding embodiments are described in parentheses.)
The first solution (18th embodiment; FIGS. 105 to 108) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Winning number determination means (internal lottery 1 in FIG. 87 and lottery determination in FIG. 88) for determining the winning number based on a random number value, and
A lottery data table (lottery table common to all RTs in FIG. 105 (8) to lottery table common to all RTs in FIG. 108 (11)) used when determining a winning number is provided.
The lottery data table is
Winning number data indicating the winning number (for example, "@BBA" = "38"), probability data indicating the winning probability (for example, "10"), and advantageous section data indicating the transition to the advantageous section (for example, "@ LT_AT1"). ”) And the first data group (for example, 1BBA condition device lottery data in FIG. 106) and
A second data group (for example, 1BBA condition device lottery in FIG. 105) in which the winning number data (for example, "@BBA" = "38") and the probability data (for example, "10") are associated and the advantageous section data is not associated. Data)
The first data group and the second data group are characterized in that the same winning number data is defined.

(C) Effect of Initial Invention 35 According to the original invention, the same winning number is determined when either the first data group or the second data group is used, but when the first data group is used, the same winning number is determined. , It is determined to shift to the advantageous section, and when the second data group is used, it is determined not to shift to the advantageous section.
As a result, the winning number can be determined and whether or not to shift to the advantageous section can be determined by performing the lottery using one lottery data table, so that the memory capacity is within a certain range. Therefore, the process related to the decision to shift to the advantageous section can be appropriately performed.

36. Initial invention 36
(A) Problems to be solved by the original invention 36 Same as the original invention 27.
(B) Means for Solving the Problems of the Initial Invention 36 (Note that the corresponding embodiments are described in parentheses.)
The first solution (19th embodiment; FIG. 121) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Random number generation means and
A combination lottery means (internal lottery 2 in FIG. 119 and a condition device number set 6 in FIG. 120) for performing a lottery so as to have a case where a predetermined combination (for example, replay A) is won based on a random number value acquired from the random number generation means. )When,
It is provided with a transition lottery means (advantageous section transition lottery in FIG. 121) for determining whether or not to shift to an advantageous section based on a random number value obtained from the random number generation means.
It has a first gaming state (for example, RT1) and a second gaming state (for example, RT2) in which the probabilities of winning a predetermined combination in the lottery by the combination lottery means are different.
When the predetermined condition is satisfied, the transition lottery means executes the transition lottery (not when the accessory is activated (“No” in step S1323 of FIG. 120) and not inside (“Yes” in step S1324). ”), And when it is not an advantageous section (“Yes” in step S1325), the process proceeds to step S1326 to execute the advantageous section transition lottery).
In the transition lottery, when the random number value belongs to the predetermined range, it is decided to shift to the advantageous section (when the random number value belongs to the range of "0" to "177", it is decided to shift to the advantageous section 2. However, when the random number value belongs to the range of "178" to "344", it is decided to shift to the advantageous section 1).
When the random number value belongs to a predetermined range, the winning combination by the winning combination lottery means is the same in the first gaming state and the second gaming state (when the random number value belongs to the range of "0" to "344", the winning combination is the same. , All RT common lottery table (12) of FIG. 114 to all RT common lottery table (14) of FIG. It is the same for any of RT4)
It is characterized by that.

The second solution (a modified example of the 19th embodiment; FIG. 121) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode (displays push order instruction information on the acquired number display LED 78), and
Of the game sections, the normal section in which the instruction function operating game is not executed and the normal section
Of the game sections, the advantageous section in which the instruction function operating game can be executed, and
Random number generation means and
A combination lottery means (internal lottery 2 in FIG. 119 and a condition device number set 6 in FIG. 120) for performing a lottery so as to have a case where a predetermined combination (for example, replay A) is won based on a random number value acquired from the random number generation means. )When,
A transition lottery means for determining whether or not to shift to an advantageous section based on a random number value acquired from the random number generation means (advantageous section transition lottery in FIG. 121) and a predetermined storage means capable of storing information regarding the transition to the advantageous section. (RWM53 storage area "_NB_CND_AT")
It has a first gaming state (for example, RT1) and a second gaming state (for example, RT2) in which the probabilities of winning a predetermined combination in the lottery by the combination lottery means are different.
The transition lottery means determines to shift to the advantageous section when the random number value belongs to a predetermined range (when the random number value belongs to the range of "0" to "177", shifts to the advantageous section 2. When the random number value belongs to the range of "178" to "344", it is decided to shift to the advantageous section 1),
When the transition lottery is executed under the condition that the specific condition is satisfied, the information stored in the predetermined storage means is maintained (when the accessory is operating (“Yes” in step S1356 of FIG. 123). When), when the internal middle flag is on (when “Yes” in step S1357 of FIG. 123), and when the advantageous section number is not “0” (when “No” in step S1358 of FIG. 123). The advantageous section transition lottery may be executed. In this case, even if the advantageous section transition lottery is executed, the advantageous section number is maintained by skipping step S1338 of FIG. 121 (the value of "_NB_CND_AT" is maintained). ),
When the random number value belongs to a predetermined range, the winning combination by the winning combination lottery means is the same in the first gaming state and the second gaming state (when the random number value belongs to the range of "0" to "344", the winning combination is the same. , All RT common lottery table (12) of FIG. 114 to all RT common lottery table (14) of FIG. It is the same for any of RT4)
It is characterized by that.

(C) Effect of Initial Invention 36 According to the initial invention, a winning combination lottery is performed by the winning combination lottery means based on one random number value obtained from the random number generating means, and the transitional lottery means shifts to an advantageous section. It is decided whether or not to let it. Then, when it is determined by the transition lottery means to shift to the advantageous section, the same combination is won in the first game state and the second game state by the combination lottery means.
In this way, the winning combination can be drawn using one random value, and it can be determined whether or not to shift to the advantageous section. Therefore, within a certain memory capacity, the advantageous section can be selected. The process related to the decision to migrate can be appropriately performed.

37. Initial invention 37
(A) Problems to be Solved by Initial Invention 37 The initial invention relates to a technique for outputting LED digit signals and segment signals from an output port in a gaming machine.
Conventionally, it has been known about the dynamic lighting of a 7-segment display (7-segment display) (for example, Japanese Patent Application Laid-Open No. 09-22509).
For example, the above publication describes the allocation of output ports between digit signals and segment signals.
Recently, it is being considered to mount a 7-segment display capable of displaying an advantageous section ratio, etc. on the main control board of a gaming machine (slot machine).
On the other hand, conventionally, the gaming machine is provided with a 7-segment display for displaying the number of stored machines, a 7-segment display for displaying the acquired number, and the like.
When the number of 7-segments increases in this way, the problem is how to design the digit signal and segment signal of each 7-segment and the output port.
The problem to be solved by the original invention is to properly design the digit (drive) signal, the segment signal, and the output port, and to execute efficient signal output processing.

(B) Means for Solving the Problems of the Initial Invention 37 (Note that the corresponding embodiments are described in parentheses.)
The first solution (20th embodiment; FIG. 128) is
A display unit that has a plurality of segments (segments A to P) that can be lit and displays predetermined information (number of stored items, number of acquired items, error information, push order instruction number, game status, or set value) by lighting the segments. A first display means (stored number display LED76, acquired number display LED78, status display LED79, or set value display LED73) having one or more (digits).
A second display means (management information display LED74) having one or more of the display units,
A first output port (output port 2) capable of outputting a drive signal (digit signal) to the display unit of the first display means,
A second output port (output port 4) capable of outputting a drive signal to the display unit of the second display means,
A third output port (output port 3) capable of outputting a segment signal is provided in the segment of the display unit of the first display means and the second display means.
The first output process (LED display control; FIG. 134) in which a drive signal is output from the first output port to the display unit of the first display means and a segment signal is output from the third output port to the segment.
A second output process (ratio display process; FIG. 135) that outputs a drive signal from the second output port to the display unit of the second display means and outputs a segment signal from the third output port to the segment.
Prior to the first output processing and the second output processing, the clear signal output processing (step S1431 and step S1432 in FIG. 134) for outputting a clear signal from the first output port, the second output port, and the third output port. And
The time from the output timing of the clear signal to the output timing of the drive signal and the segment signal in the first output process (time from step S1431 and step S1432 to step S1458) is set to "t1", and the second output is performed from the output timing of the clear signal. When the time to the output timing of the drive signal and the segment signal in the process (time from step S1431 and step S1432 to step S1487) is set to "t2", the process is executed so that "t1 <t2". And.

The second solution is, in the first solution,
A display counter (LED display counter; FIG. 132) that is updated at a predetermined timing is provided.
When the display counter has the first value, the first output process is executed, and when the display counter has the second value (second value ≠ first value), the second output process is executed. do.

(C) Effect of Initial Invention 37 According to the original invention, since the segment signal is output using the output port common to the first display means and the second display means, the IC cost is reduced and the drive signal (digit) is efficiently used. Signal) and segment signal can be output.
Further, when the first display means is a display means visible to the player and the second display means is a display means invisible to the player, the output process of the first display means is performed before the second display means. Therefore, the prevention of flicker of the first display means can be prioritized.
Further, according to the second solution means, one display counter can be used to execute the output process to the first display means and the output process to the second display means.

38. Initial invention 38
(A) Problems to be solved by the original invention 38 Same as the original invention 37.
(B) Means for Solving the Problems of the Initial Invention 38 (Note that the corresponding embodiments are described in parentheses.)
The first solution (21st embodiment; FIG. 138) is
A display unit (digit) that has a plurality of segments (segments A to P) that can be lit and displays predetermined information (number of stored items, number of acquired items, error information, push order instruction number, or game status) by lighting the segments. 1st display means (stored number display LED76, acquired number display LED78, or status display LED79)
A second display means (management information display LED74) having one or more of the display units,
A first output port (output port 3) capable of outputting a drive signal (digit signal) to the display unit of the first display means and the display unit of the second display means, and
A second output port (output port 4) capable of outputting a segment signal is provided in the segment of the display unit of the first display means and the segment of the display unit of the second display means.
The first output process (LED display control; FIG. 140) in which a drive signal is output from the first output port to the display unit of the first display means and a segment signal is output from the second output port to the segment.
A second output process (ratio display process; FIG. 141) in which a drive signal is output from the first output port to the display unit of the second display means and a segment signal is output from the second output port to the segment.
Prior to the first output process and the second output process, a clear signal output process (step S1531 in FIG. 140) for outputting a clear signal from the first output port and the second output port is executed.
The time from the output timing of the clear signal to the output timing of the drive signal and the segment signal in the first output process (time from step S1531 to step S1534) is set to "t1", and the drive in the second output process is performed from the output timing of the clear signal. When the time until the output timing of the signal and the segment signal (time from step S1531 to step S1487) is set to "t2", the process is executed so that "t1 <t2".

The second solution is, in the first solution,
A display counter (LED display counter; FIG. 139 (B)) that is updated at a predetermined timing is provided.
When the display counter has the first value, the first output process is executed, and when the display counter has the second value (second value ≠ first value), the second output process is executed. do.

(C) Effect of Initial Invention 38 In addition to the effect of Initial Invention 37, the number of output ports of the drive signal can be one and the number of output ports of the segment signal can be one, so that the number of output ports can be reduced. can.

39. Original invention 39
(A) Problems to be solved by the original invention 39 Same as the original invention 37.
(B) Means for Solving the Problems of the Initial Invention 39 (Note that the corresponding embodiments are described in parentheses.)
The first solution (22nd embodiment; FIG. 144) is
A display unit that has a plurality of segments (segments A to P) that can be lit and displays predetermined information (number of stored items, number of acquired items, error information, push order instruction number, game status, or set value) by lighting the segments. A first display means having one or more (digits) (stored number display LED76, acquired number display LED78, or status display LED79) and
A second display means (management information display LED74) having one or more of the display units,
A first output port (output port 2) capable of outputting a drive signal (digit signal) to the display unit of the first display means and the display unit of the second display means, and
A second output port (output port 3) capable of outputting a segment signal (segments 1A to 1P signals) to the segment of the display unit of the first display means, and
The segment of the display unit of the second display means is provided with a third output port (output port 4) capable of outputting a segment signal (segments 2A to 2P signals).
The first output process (LED display control; FIG. 149) that outputs a drive signal from the first output port to the display unit of the first display means and outputs a segment signal from the second output port to the segment.
A second output process (ratio display process; FIG. 150) that outputs a drive signal from the first output port to the display unit of the second display means and outputs a segment signal from the third output port to the segment.
Prior to the first output processing and the second output processing, the clear signal output processing (step S1541 and step S1542 in FIG. 149) for outputting a clear signal from the first output port, the second output port, and the third output port. And
The time from the output timing of the clear signal to the output timing of the drive signal and the segment signal in the first output process (time from step S1541 and step S1542 to step S1554 and step S1555) is set to "t1", and from the output timing of the clear signal. When the time until the output timing of the drive signal and the segment signal in the second output process (time from step S1541 and step S1542 to step S1561) is set to "t2", the process is executed so that "t1 <t2". It is characterized by that.

The second solution is, in the first solution,
A display counter (LED display counter; FIG. 148) that is updated at a predetermined timing is provided.
When the display counter has the first value, the first output process is executed, and when the display counter has the second value (second value ≠ first value), the second output process is executed. do.
(C) Effect of the original invention 39 Same as the original invention 37.

40. Initial invention 40
(A) Problems to be solved by the original invention 40 Same as the original invention 37.
(B) Means for Solving the Problems of the Initial Invention 40 (Note that the corresponding embodiments are described in parentheses.)
The first solution (24th embodiment; FIG. 154) is
A display unit that has a plurality of segments (segments A to P) that can be lit and displays predetermined information (number of stored items, number of acquired items, error information, push order instruction number, game status, or set value) by lighting the segments. A first display means (stored number display LED76, acquired number display LED78, status display LED79, or set value display LED73) having one or more (digits).
A second display means (management information display LED74) having one or more of the display units,
A first output port (output port 3) capable of outputting a drive signal (digit signal) to the display unit of the first display means,
A second output port (output port 6) capable of outputting a drive signal (digit signal) to the display unit of the second display means,
A third output port (output port 4) capable of outputting a segment signal to the segment of the display unit of the first display means, and
A fourth output port (output port 7) capable of outputting a segment signal is provided in the segment of the display unit of the second display means.
The first output process (LED display control; FIG. 158), which outputs a drive signal from the first output port to the display unit of the first display means and outputs a segment signal from the third output port to the segment,
A second output process (ratio display process; FIG. 159) that outputs a drive signal from the second output port to the display unit of the second display means and outputs a segment signal from the fourth output port to the segment.
Before the first output process and the second output process, the clear signal output process for outputting a clear signal from the first output port, the second output port, the third output port, and the fourth output port (in FIG. 158, step S1571). And step S1572) and
The time from the output timing of the clear signal to the output timing of the drive signal and the segment signal in the first output process (time from step S1571 and step S1572 to step S1576 and step S1577) is set to "t1", and from the output timing of the clear signal. When the time until the output timing of the drive signal and the segment signal in the second output process (time from step S1571 and step S1572 to step S1581) is set to "t2", the process is executed so that "t1 <t2". It is characterized by that.

The second solution is, in the first solution,
A display counter (LED display counter; FIG. 156) that is updated at a predetermined timing is provided.
When the display counter has the first value, the first output process is executed, and when the display counter has the second value (second value ≠ first value), the second output process is executed. do.
(C) Effect of the original invention 40 Same as the original invention 37.

41. Initial invention 41
(A) Problems to be Solved by Initial Invention 41 The initial invention relates to a technique for outputting LED digit signals and segment signals from an output port in a gaming machine.
Conventionally, it has been known about the dynamic lighting of a 7-segment display (7-segment display) (for example, Japanese Patent Application Laid-Open No. 09-22509).
For example, the above publication describes the allocation of output ports between digit signals and segment signals.
Recently, it is being considered to mount a 7-segment display capable of displaying an advantageous section ratio, etc. on the main control board of a gaming machine (slot machine).
On the other hand, conventionally, the gaming machine is provided with a 7-segment display for displaying the number of stored machines, a 7-segment display for displaying the acquired number, and the like.
When the number of 7-segments is increased in this way, the program becomes complicated because the lighting control of each 7-segment is performed.
The problem to be solved by the initial invention is to efficiently store and execute a program for controlling LED lighting.

(B) Means for Solving the Problem of Initial Invention 41 (Note that the corresponding embodiment is described in parentheses.)
The original invention was
A display unit that has a plurality of segments (segments A to P) that can be lit and displays predetermined information (number of stored items, number of acquired items, error information, push order instruction number, game status, or set value) by lighting the segments. A first display means (stored number display LED76, acquired number display LED78, status display LED79, or set value display LED73) having one or more (digits).
A second display means (management information display LED74) having one or more of the display units,
A first program (LED display control) for outputting a drive signal (digit signal) to the display unit of the first display means and outputting a segment signal to a segment of the display unit of the first display means is stored. 1 For outputting a drive signal (digit signal) to the storage area (within the used area of the ROM 54) and the display unit of the second display means, and outputting a segment signal to the segment of the display unit of the second display means. A storage means (ROM54) having a second storage area (outside the used area of the ROM 54) for storing the second program (ratio display processing) is provided.
After executing the first program, execute the second program,
A clear signal is output to the first display means and the second display means before the drive signal is output to the display unit of the first display means and the segment signal is output to the segment of the display unit of the first display means. It is characterized by including a clear signal output process (for example, step S1431 and step S1432 during the LED display control of FIG. 134).

(C) Effect of Initial Invention 41 According to the initial invention, the programs of the first display means and the second display means are stored separately, and the second program is executed after the execution of the first program. And can be executed efficiently.
Further, since the clear signal output process is executed when the first program is executed, afterimages can be prevented.

42. Initial invention 42
(A) Problems to be Solved by Initial Invention 42 The initial invention relates to a technique for outputting LED digit signals and segment signals from an output port in a gaming machine.
Conventionally, it has been known about the dynamic lighting of a 7-segment display (for example, Japanese Patent Application Laid-Open No. 09-22509).
For example, the above publication describes the allocation of output ports between digit signals and segment signals.
Recently, it is being considered to mount a 7-segment (management information display LED) capable of displaying an advantageous section ratio or the like on the main control board of a gaming machine (slot machine).
On the other hand, although the 7-segment is composed of segments A to G, a segment P (also referred to as a segment DP), which is a dot segment, may be further provided.
Then, when the management information display LED has a dot segment, how to use the dot segment becomes a problem.
The problem that the invention initially tries to solve is to display specific information using dot segments.

(B) Means for Solving the Problem of the Original Invention 42 (Note that the corresponding embodiment is described in parentheses.)
The first solution is
A first display unit (digit 7) and a second display unit (digit) that have a plurality of lightable segments (segments A to P) and display predetermined information (management information such as advantageous section ratio) by lighting the segments. 6,8,9) and
Equipped with a display counter (LED display counter) that is updated at a predetermined timing,
When it is time to turn on the first display unit by the display counter, the segment including the specific segment (segment P) is turned on.
At any timing of the display counter, the specific segment of the second display unit is not turned on.
When a specific error (unrecoverable error 2) occurs, the update (interrupt) of the display counter is stopped, and the specific error process (unrecoverable error process 2) for lighting the specific segment of the second display unit is performed. It is characterized by executing.

The second solution is, in the first solution,
The specific error processing is characterized in that processing for lighting the specific segment of all the display units including the first display unit and the second display unit is executed.
The third solution is in the first or second solution.
The specific error processing is executed in the first storage area (within the used area of the ROM 54) for storing the program (for example, the main processing) for executing the control processing in the game and the storage area divided from the first storage area. A storage means (ROM 54) having a second storage area (outside the used area of the ROM 54) for storing the program (non-recoverable error processing 2) is provided.

(C) Effect of Initial Invention 42 According to the original invention, different information can be displayed between the specific segment of the first display unit and the specific segment of the second display unit. In particular, information delimiters can be displayed by lighting a specific segment of the first display unit. On the other hand, the occurrence of a specific error can be notified by lighting a specific segment of the second display unit.

43. Initial invention 43
(A) Problems to be Solved by Initial Invention 43 The initial invention is provided with an advantageous section in which an instruction function for displaying an advantageous operation mode of the stop switch can be operated, and the main control board side indicates that the transition to this advantageous section is performed. It is about the slot machine to decide.
In a conventional slot machine, there is known a slot machine that draws a winning combination on the main control board side and determines whether or not to display an advantageous operation mode of a stop switch (for example, Japanese Patent Application Laid-Open No. 2014-161344). See Gazette).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed, and when the user shifts to the advantageous section, the advantageous section display device indicates that the section is advantageous.
Here, when the rare role is won, if a time of shifting to the advantageous section and a time of not shifting to the advantageous section are provided, the game that wins the rare role shifts to the advantageous section depending on the content of the display by the advantageous section display device. The player knows whether or not to do it. In this case, it is not possible to maintain the player's expectation for AT execution by winning the rare role.
On the other hand, if the AT is always executed when the rare role is won, the rare role winning means the AT execution, and the game becomes monotonous.
The problem to be solved by the initial invention is that when a lottery result (rare winning combination) that allows the combination of specific symbols to be stopped is obtained, the expectation for the transition to the designated game section (AT) is raised over multiple games. To give to the person.

(B) Means for Solving the Problems of the Initial Invention 43 (Note that the corresponding embodiments are described in parentheses.)
The first solution (25th embodiment) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function for displaying the advantageous operation mode and
Of the game sections, the normal section where the instruction function is not activated and the normal section
Of the game sections, the advantageous section where the instruction function can be activated and
In the advantageous section, the instruction game section (AT) in which the instruction function is always activated or the operation frequency is increased in the game having the advantageous operation mode of the stop switch, and
An advantageous section display device (advantageous section display LED77) indicating that the section is advantageous, and
When a lottery result (small winning combination D is won) that a predetermined combination of symbols (combination of symbols in which "watermelons" are aligned in a straight line in the diagonally upward direction) can be stopped, or a combination of specific symbols (left reel) A lottery means (role lottery means 61) for drawing a lottery so that the lottery result (small winning combination E1 winning) can be stopped (combination of symbols in which "cherry" stops in the middle left when 31 is stopped) Prepare,
When the lottery result is such that the combination of the predetermined symbols can be stopped by the lottery means, the section shifts to the advantageous section and the advantageous section display device indicates that the section is advantageous, and the advantageous section. There is a case where the section does not shift to the above and the advantageous section display device does not indicate that the section is advantageous.
Whenever the lottery result results in a lottery in which the combination of the specific symbols can be stopped by the lottery means, the section is always shifted to the advantageous section, and the advantageous section display device indicates that the section is advantageous.
When the lottery result is such that the combination of the specific symbols can be stopped by the lottery means, the section shifts to the advantageous section, and the advantageous section display device indicates that the section is advantageous, the indicated game section is displayed. It is characterized by having a time when it shifts to and a time when it does not shift to the designated game section.

(C) Effect of Initial Invention 43 According to the initial invention, whenever a lottery result is obtained in which a combination of specific symbols can be stopped, the section shifts to an advantageous section, and the advantageous section display device provides an advantageous section. Display that. Then, in this case, since there are a time when the player shifts to the designated game section and a time when the game does not shift to the designated game section, the game shifts to the designated game section when the lottery result is such that the combination of specific symbols can be stopped. It is possible to give a player a sense of expectation for a plurality of games.

44. Original invention 44
(A) Problems to be Solved by the Initial Invention 44 The initial invention is provided with an advantageous section in which an instruction function for displaying an advantageous operation mode of the stop switch can be operated, and the main control board side indicates that the interval is shifted to this advantageous section. It is about the slot machine to decide.
In a conventional slot machine, there is known a slot machine that draws a winning combination on the main control board side and determines whether or not to display an advantageous operation mode of a stop switch (for example, Japanese Patent Application Laid-Open No. 2014-161344). See Gazette).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed.
Here, each time the advantageous section ends, the ease of transition from the normal section to the advantageous section is changed, or when the advantageous section ends and when the set value is changed, the advantageous section from the normal section Different ease of transition to may impair fairness among players.
The problem to be solved by the initial invention is that each time the advantageous section ends, the ease of transition from the normal section to the advantageous section is made the same, and when the advantageous section ends and the set value is changed. Therefore, the ease of transition from the normal section to the advantageous section should be the same.

(B) Means for Solving the Problems of the Initial Invention 44 (Note that the corresponding embodiments are described in parentheses.)
The first solution (25th embodiment) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function for displaying the advantageous operation mode and
Of the game sections, the normal section where the instruction function is not activated and the normal section
Of the game sections, the advantageous section where the instruction function can be activated and
A first storage means (predetermined storage area of RWM53) for storing information about an advantageous section, and
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
A second storage means for storing the set value (set value data storage area (_NB_RANK) on the RWM53) and
A combination lottery means (61) for drawing a combination so as to have a case where a re-game combination is won, and
A plurality of lottery states (RT states (non-RT, RT1, RT2, RT3, or RT4)) having different winning probabilities of at least one re-game combination are provided.
When the advantageous section ends, the first initialization process (initialization process at the end of the advantageous section) is executed.
When the set value stored in the second storage means is changed, the second initialization process (initialization process at the time of setting change) is executed.
In the first initialization process, the process shifts to the normal section while maintaining the lottery state at the end of the advantageous section.
In the second initialization process, the process shifts to a predetermined specific lottery state (non-RT) and shifts to the normal section.
In the first initialization process and the second initialization process, when the first initialization process is executed and the second initialization process is performed by clearing the information about the advantageous section stored in the first storage means. The feature is that the information about the advantageous section shifts to the normal section, which is in the same state as when it is executed.

(C) Effect of Initial Invention 44 According to the initial invention, the information regarding the advantageous section is cleared in both the first initialization process executed at the end of the advantageous section and the second initialization process executed at the time of setting change. As a result, it is possible to make the ease of transition from the normal section to the advantageous section the same each time the advantageous section ends, and it is normal when the advantageous section ends and when the set value is changed. Since the ease of transition from the section to the advantageous section can be made the same, fairness among the players can be ensured.

45. Initial invention 45
(A) Problems to be Solved by the Initial Invention 45 The initial invention is provided with an advantageous section in which an instruction function for displaying an advantageous operation mode of the stop switch can be operated, and the main control board side indicates that the interval is shifted to this advantageous section. It is about the slot machine to decide.
In a conventional slot machine, there is known a slot machine that draws a winning combination on the main control board side and determines whether or not to display an advantageous operation mode of a stop switch (for example, Japanese Patent Application Laid-Open No. 2014-161344). See Gazette).
Recently, it has been proposed to provide an advantageous section which is a game section in which AT can be executed.
Here, in slot machines, the higher the set value, the higher the probability of winning a special role.
However, if it is possible to shift to an advantageous section when a special role is won, there is a possibility that the difference in the advantage of the player becomes too large between the low setting and the high setting.
The problem to be solved by the initial invention is to prevent the difference in the advantage of the player from becoming too large between the low setting and the high setting.

(B) Means for Solving the Problems of the Initial Invention 45 (Note that the corresponding embodiments are described in parentheses.)
The first solution (25th embodiment) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function for displaying the advantageous operation mode and
Of the game sections, the normal section where the instruction function is not activated and the normal section
Of the game sections, the advantageous section where the instruction function can be activated and
Means for determining one of a plurality of set values (setting key switch 12, setting switch 13, etc.) and
As a special role (1BB) for shifting to a special game, a role lottery means (61) for drawing a role so as to have a case where the first special role (1BBA) and the second special role (1BBB) are won. Prepare
When the first special combination is won by the combination lottery means, it is possible to shift to an advantageous section.
When the second special role is won by the combination lottery means, the section does not shift to the advantageous section and the section is not changed to the advantageous section.
The winning probability of the first special role is set to be the same for all set values,
Since the winning probability of the second special combination is set to increase as the set value increases, the set value of the transition probability to the advantageous section at the time of winning the special combination (total of 1BBA and 1BBB) is set. It is characterized by increasing as it decreases.

(C) Effect of Initial Invention 45 According to the initial invention, the winning probability of the first special winning combination that can be transferred to the advantageous section is the same for all set values, and the winning probability of the second special winning combination that does not shift to the advantageous section is , The higher the set value, the higher the value. As a result, the winning probability of the special combination (the sum of the first special combination and the second special combination) increases as the set value increases, and the transition probability to the advantageous section at the time of winning the special combination is low. Since it becomes higher as it becomes, it is possible to prevent the difference in the player's advantage from becoming too large between the low setting and the high setting.

46. Initial invention 46
(A) Problems to be Solved by the Initial Invention 46 The initial invention is provided with an advantageous section in which an instruction function for displaying an advantageous operation mode of the stop switch can be operated, and the main control board side indicates that the interval is shifted to this advantageous section. It is about the slot machine to decide.
In a conventional slot machine, there is known a slot machine that draws a winning combination on the main control board side and determines whether or not to display an advantageous operation mode of a stop switch (for example, Japanese Patent Application Laid-Open No. 2014-161344). See Gazette).
Recently, it is possible to provide an advantageous section in which the instruction function for displaying the advantageous operation mode of the stop switch can be operated, and further, in the advantageous section, provide an instruction game section in which the instruction function is always operated or the operation frequency is increased. Proposed.
Here, an advantageous section having an instruction game section and an advantageous section not having an instruction game section can be provided, but from the viewpoint of ball ejection design, as many game media as possible can be used in the advantageous section having the instruction game section. In order to pay out, it is preferable to suppress the payout of the game medium as much as possible in the advantageous section that does not have the designated game section.
The problem to be solved by the initial invention is to suppress the payout of the game medium as much as possible in the advantageous section having no designated game section.

(B) Means for Solving the Problems of the Initial Invention 46 (Note that the corresponding embodiments are described in parentheses.)
The first solution (25th embodiment) is
A game having an advantageous operation mode (correct answer pressing order) of the stop switch (42) (for example, a game when the small role B group is won) and
In a game having an advantageous operation mode of the stop switch, an instruction function for displaying the advantageous operation mode and
Of the game sections, the normal section where the instruction function is not activated and the normal section
Of the game sections, the advantageous section where the instruction function can be activated and
It is provided with a role lottery means (61) for drawing a role so as to have a case where a special role (1BBA or 1BBB) for shifting to a special game is won.
When the instruction function is activated at least once in the advantageous section, it is possible to end the advantageous section.
In the advantageous section, if a special combination is won by the combination lottery means before the first operation of the instruction function, the advantageous section can be ended without operating the instruction function.
After shifting to the advantageous section, the instruction function is not activated even if the game has an advantageous operation mode of the stop switch until a specific condition is satisfied (one instruction operation condition is satisfied: 15 games are digested). It is characterized by that.

(C) Effect of Initial Invention 46 According to the initial invention, the instruction function is not activated even if the game has an advantageous operation mode of the stop switch until a specific condition is satisfied after the transition to the advantageous section. It is possible to increase the probability of winning a special role before the first operation of the instruction function. As a result, the probability that the advantageous section can be ended without activating the instruction function can be increased, and by extension, the payout of the game medium can be suppressed as much as possible in the advantageous section that does not have the instruction game section. ..

47. Initial invention 47
(A) Problems to be Solved by the Initial Invention 47 The initial invention relates to a gaming machine capable of switching and displaying a plurality of types of gaming information at predetermined time intervals.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the number of payouts (balls paid out) of the gaming machine and determine whether or not to play the game. It was not possible to determine whether or not the predetermined ratio was within the range of the predetermined design value.
The problem to be solved by the initial invention is to display game information capable of determining whether or not a predetermined ratio regarding ball ejection and the like is within a predetermined design value range. Furthermore, when displaying the display, it is necessary not to misunderstand that the product is out of order.

(B) Means for Solving the Problems of the Original Invention 47 (Note that the corresponding embodiments are described in parentheses.)
The original invention (26th embodiment) is
Multiple types (5 items) of game information (advantageous section ratio, continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), bonus ratio (cumulative)) for a predetermined time ( Equipped with a display unit (management information display LED74 (digits 6 to 9)) that can be switched and displayed every 5 seconds)
In the display of the game information for the predetermined time, when the game information is lit and displayed (for example, in the case of displaying the advantageous section ratio, the number of games is "175,000" or more and the ratio is less than "70". When) and when at least a part of the game information is blinked (for example, when displaying the advantageous section ratio, when the number of games is less than "175000", the identification segment is blinked and the ratio is When it is "70" or more, the ratio segment is blinked and displayed).
When blinking at least a part of the game information, it is turned on and off alternately at specific time (about 0.3 seconds).
In the case of displaying the next game information after displaying the game information for the predetermined time, when at least a part of the information of the next game information is blinking and displayed, the count of the predetermined time (interrupt count "2144") (Count) is started (step S2511 in FIG. 209), and counting of the specific time (counting the number of interrupts “134”) is started (step S2518 in FIG. 209).
It is characterized by that.

(C) Effect of Initial Invention 47 According to the original invention, the timing of switching the display of the game information to the next game information and the blinking start timing of blinking the game information can be matched with each other. As a result, it is possible to prevent the game information from turning on for a moment or turning off the game information for a moment, and it is possible to prevent the display unit from being mistaken for a failure.

48. Initial invention 48
(A) Problems to be solved by the original invention 48 Same as the original invention 47.
(B) Means for Solving the Problems of the Initial Invention 48 (Note that the corresponding embodiments are described in parentheses.)
The original invention (26th embodiment) is
Multiple types (5 items) of game information (advantageous section ratio, continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), bonus ratio (cumulative)) for a predetermined time ( Equipped with a display unit (management information display LED74 (digits 6 to 9)) that can be switched and displayed every 5 seconds)
In the display of the game information for the predetermined time, when the game information is lit and displayed (for example, in the case of displaying the advantageous section ratio, the number of games is "175,000" or more and the ratio is less than "70". When) and when at least a part of the game information is blinked (for example, when displaying the advantageous section ratio, when the number of games is less than "175000", the identification segment is blinked and the ratio is When it is "70" or more, the ratio segment is blinked and displayed).
When blinking at least a part of the game information, it is turned on and off alternately at specific time (about 0.3 seconds).
Interrupt processing (Fig. 190) can be executed at regular intervals (2.235 ms).
When the number of interrupts becomes "Y" (2144), it is determined that the predetermined time has elapsed ("Yes" in step S2512 in FIG. 209).
When the number of interrupts becomes "X" (134), it is determined that the specific time has elapsed ("Yes" in step S2519 in FIG. 209).
Y = 2 × n × X (“n” is a natural number) (2144 = 2 × 8 × 134)
It is characterized in that it is set to satisfy.
(C) Effect of the original invention 48 Same as the original invention 47.

49. Original invention 49
(A) Problems to be Solved by the Initial Invention 49 The initial invention relates to a gaming machine capable of displaying a plurality of types of gaming information by switching them in a predetermined order at predetermined time intervals.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the number of payouts (balls paid out) of the gaming machine and determine whether or not to play the game. It was not possible to determine whether or not the predetermined ratio was within the range of the predetermined design value.
The problem to be solved by the initial invention is to display whether or not a predetermined ratio regarding ball ejection and the like is within a predetermined design value range. Further, it is necessary to execute appropriate processing for displaying the game information at the time of normal power-on and at the time of shifting to the setting change state.

(B) Means for Solving the Problems of the Initial Invention 49 (Note that the corresponding embodiments are described in parentheses.)
The original invention (26th embodiment) is
Multiple types (5 items) of game information ("1" advantageous section ratio, "2" continuous character ratio (6000 times), "3" character ratio (6000 times), "4" continuous character ratio (cumulative) , "5" accessory ratio (cumulative)) in a predetermined order ("1" → "2" → ... → "5" → "1" → "2" → ...) for a predetermined time (about 5) Display unit (management information display LED74 (digits 6 to 9)) that can be switched and displayed every second)
It is equipped with a counter (display switching time of the address "F290 (H)") that counts the predetermined time.
The power is turned off while the "n" (n ≧ 2) th game information is being displayed (for example, when "n = 2" is being displayed, the continuous accessory ratio (6000 times) is being displayed), and the setting key switch is used. When the power is turned on in the state of being off (initialization of the unused area in step S2158 in FIG. 187), the display of the "n" th game information and the counting of the predetermined time can be restarted.
When the power is turned off while the "n" th game information is being displayed and the power is turned on while the setting key switch is on (when the setting change process of FIG. 186 is advanced), the counter is displayed. After clearing the value (step S2130 in FIG. 186), the display of the first game information (“1” advantageous section ratio) is started (step S2517 in FIG. 209), and the counting of the predetermined time is started. (Step S2511 in FIG. 209)
It is characterized by that.

(C) Effect of Initial Invention 49 According to the initial invention, the counter value is not initialized at the time of normal power-on (start-up) without shifting to the setting change state, so that the game information is displayed from the state immediately before the power-off. Can be resumed. On the other hand, when the setting is changed, the counter value is cleared, so that the display of the first game information can be started. In this way, it is possible to appropriately perform the processing for displaying the game information when the power is turned on normally and when the setting is changed.

50. Initial invention 50
(A) Problems to be Solved by the Initial Invention 50 The initial invention relates to a gaming machine capable of displaying a plurality of types of gaming information by switching and displaying them in a predetermined order at predetermined time intervals.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the number of payouts (balls paid out) of the gaming machine and determine whether or not to play the game. It was not possible to determine whether or not the predetermined ratio was within the range of the predetermined design value.
The problem to be solved by the initial invention is to display game information capable of determining whether or not a predetermined ratio regarding ball ejection and the like is within a predetermined design value range. Further, in the case of shifting to the setting change state, appropriate processing for displaying the game information is executed according to whether or not the specific conditions are satisfied.

(B) Means for Solving the Problems of the Initial Invention 50 (Note that the corresponding embodiments are described in parentheses.)
The original invention (26th embodiment) is
Multiple types (5 items) of game information ("1" advantageous section ratio, "2" continuous character ratio (6000 times), "3" character ratio (6000 times), "4" continuous character ratio (cumulative) , "5" accessory ratio (cumulative)) in a predetermined order ("1" → "2" → ... → "5" → "1" → "2" → ...) for a predetermined time (about 5) Equipped with a display unit (management information display LED74 (digits 6 to 9)) that can be switched and displayed every second)
The game information has identification information (identification segment) and numerical information (ratio segment).
Numerical information storage area for storing numerical information in game information (advantageous section ratio data of address "F285 (H)" to accessory ratio (cumulative) data of address "F289 (H)")
It is equipped with a counter (display switching time of the address "F290 (H)") that counts the predetermined time.
The power is turned off while the "n" (n ≧ 2) th game information is being displayed (for example, when "n = 2" is being displayed, the continuous accessory ratio (6000 times) is being displayed), and the setting key switch is used. When the power is turned on while the power is on, when a specific condition is satisfied (in FIG. 185, the checksum in step S2104 is normal and the power is turned off and restored normally (FIG. 185). In 186, in step S2128, when “Yes”)), the “n” th game information is displayed and the predetermined time is counted based on the value stored in the numerical information storage area and the value of the counter. (Without initializing the ratio display number of the address "F28E (H)" and the display switching time of the address "F290 (H)"),
When the power is turned off while the "n" th game information is being displayed and the power is turned on while the setting key switch is on, a specific condition is not satisfied (step in FIG. 185). When the checksum of S2104 is abnormal and / or when the power supply / disconnection / recovery is abnormal (when “No” in step S2128 in FIG. 186), the value stored in the numerical information storage area. After clearing the values of the counters (steps S2129 and S2130 in FIG. 186), the display of the first game information with the numerical information as the initial value is started (step S2517 in FIG. 209), and the predetermined time (Step S2511 in FIG. 209)
It is characterized by that.

(C) Effect of Initial Invention 50 According to the original invention, when the setting is changed, the processing for displaying the game information is appropriate depending on whether or not the specific conditions are satisfied. Can be done. In addition, even under the situation where the specific condition is not satisfied, the display of the first game information with the numerical information as the initial value is started, so that the fact that the specific condition is not satisfied (error) is not displayed. It is possible to immediately shift to the display of game information.

51. Initial invention 51
(A) Problems to be Solved by the Initial Invention 51 The initial invention relates to a gaming machine capable of displaying a plurality of types of gaming information.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the number of payouts (balls paid out) of the gaming machine and determine whether or not to play the game. It was not possible to determine whether or not the predetermined ratio was within the range of the predetermined design value.
The problem to be solved by the initial invention is to display game information capable of determining whether or not a predetermined ratio regarding ball ejection and the like is within a predetermined design value range. Further, when it is necessary to blink the game information, an appropriate process for displaying the blinking game information is executed according to the situation when the power is turned on.

(B) Means for Solving the Problems of the Initial Invention 51 (Note that the corresponding embodiments are described in parentheses.)
The first solution (26th embodiment) is
Multiple types (5 items) of game information (advantageous section ratio, continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), bonus ratio (cumulative)) can be displayed. Equipped with a display unit (management information display LED74 (digits 6 to 9))
When the game information is lit and displayed, and when at least a part of the game information is blinked (see FIG. 184. For example, when displaying the advantageous section ratio, when the number of games is less than "175000", (Blinks the identification segment) and has
When blinking at least a part of the game information, it is turned on and off alternately at specific time (about 0.3 seconds).
A counter for counting the specific time (blinking switching time of the address "F292 (H)") is provided.
The power was turned off when at least some of the specific game information was flashing and the at least some of the information was off, and the power was turned on when the setting key switch was on. At the time (at the time of transition to the setting change state), the counting of the specific time is started, and at least a part of the specific game information is blinked and displayed so that at least a part of the information starts from lighting. (Initialize the address "F292 (H)" of RWM53 in step S2130 of FIG. 186, and set the initial value "134 (D)" in step S2520 of FIG. 209).
It is characterized by that.

The second solution (26th embodiment) is
Multiple types (5 items) of game information (advantageous section ratio, continuous bonus ratio (6000 times), bonus ratio (6000 times), continuous bonus ratio (cumulative), bonus ratio (cumulative)) can be displayed. Equipped with a display unit (management information display LED74 (digits 6 to 9))
The game information has identification information (identification segment) and numerical information (ratio segment).
When both the identification information and the numerical information are lit and displayed, and when at least one of the identification information or the numerical information is blinking (see FIG. 184. For example, when displaying the advantageous section ratio, the number of games played is "175000". When the number of times is less than, the identification segment is blinked, and when the ratio is "70" or more, the ratio segment is blinked).
When at least one of the identification information and the numerical information is blinked and displayed, it is turned on and off alternately at specific time (about 0.3 seconds).
A counter for counting the specific time (blinking switching time of the address "F292 (H)") is provided.
When the power is turned off when at least one of the identification information or the numerical information is blinking and the at least one of the information is off, and the power is turned on while the setting key switch is on. (At the time of transition to the setting change state), the counting of the specific time is started, and at least one of the identification information or the numerical information is blinked and displayed so that at least one of the information starts from lighting (FIG. 186). The address “F292 (H)” of the RWM 53 is initialized in step S2130 of FIG. 209, and the initial value “134” is set in step S2520 of FIG. 209).
It is characterized by that.

(C) Effect of Initial Invention 51 According to the initial invention, game information can be confirmed more quickly. In addition, the count of the specific time before the power is turned off is carried over to the setting change state, and when the display of the game information is started in the setting change state, it is possible to prevent the game information from being turned on for a moment and then turned off. .. As a result, it is possible to prevent the display unit from being mistaken for a failure.

52. Original invention 52
(A) Problems to be Solved by the Initial Invention 52 The initial invention relates to a gaming machine that stores a total number of games and a value corresponding to the number of games played in a predetermined game section.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the number of payouts (balls paid out) of the gaming machine and determine whether or not to play the game, and is used for determining whether or not to play the game. Therefore, it was not possible to determine the ratio (ratio) of the number of games played in a predetermined game section.
The problem to be solved by the initial invention is to make it possible to determine the ratio of the number of games played in a predetermined game section to the total number of games played. Further, when the ratio is calculated, it is controlled so that it becomes a correct value.

(B) Means for Solving the Problems of the Initial Invention 52 (Note that the corresponding embodiments are described in parentheses.)
The first solution (26th embodiment) is
A first storage area (counter for the total number of games played at the address "F26D (H)") that stores a value corresponding to the total number of games played.
A second storage area (counter for the number of advantageous section games at the address "F270 (H)") that stores a value corresponding to the number of games played in a predetermined game section (advantageous section),
Count upper limit flag in the third storage area (address "F28B (H)"" that stores information indicating whether or not the value stored in the first storage area has reached a specific value (3 bytes full (FFFFFF (H))). With (D0th bit) of
It is determined whether or not the value stored in the first storage area has reached the specific value (step S2255 in FIG. 192).
When the value stored in the first storage area reaches the specific value, information indicating that the specific value has been reached is stored in the third storage area (step S2256, step S2259).
When the information indicating that the specific value has been reached is stored in the third storage area (when it is determined as "Yes" in step S2236 in FIG. 191), even during the predetermined game section. , Do not update the values stored in the first storage area and the second storage area (do not execute the processing of steps S2237 and S2238).
It is characterized by that.
The second solution is, in the first solution,
The specific value is an upper limit value (“FFFFFF (H)”) of a storage capacity (3 bytes) that can be stored in the first storage area.

(C) Effect of Initial Invention 52 According to the initial invention, it is possible to prevent the storage capacity of the first storage area from being exceeded and the value being updated even after an overflow occurs. In particular, when the value stored in the first storage area reaches a specific value, the value in the second storage area is not updated, so that unnecessary updating can be eliminated. Furthermore, by updating the value of the second storage area when the first storage area overflows, it is possible to prevent the number of games in a predetermined game section from being unable to be calculated correctly with respect to the total number of games. can do.

53. Original invention 53
(A) Problems to be Solved by Initial Invention 53 The initial invention relates to a gaming machine that stores a total number of games and a value corresponding to the number of games played in a predetermined game section.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the payout number (ball payout) of the gaming machine and determine whether or not to play the game, and is used as a material for determining whether or not to play the game. Therefore, it was not possible to judge the ratio of the number of payouts during the special game.
The problem to be solved by the initial invention is to make it possible to determine the ratio of the number of payouts during the special game to the total number of payouts of the game medium. Further, when the ratio is calculated, it is controlled so that it becomes a correct value.

(B) Means for Solving the Problem of Initial Invention 53 (Note that the corresponding embodiment is described in parentheses.)
The first solution (26th embodiment) is
A first storage area (total payout (cumulative) counter of address "F27C (H)") that stores a value corresponding to the total number of payouts of the game medium, and
A second storage area (address "F27F (H)" continuous bonus payout (cumulative) counter) that stores a value corresponding to the number of game media payouts during the special game (when the bonus is activated or when the continuous bonus is activated). Or, the character payout (cumulative) counter at the address "F282 (H)") and
Count upper limit flag in the third storage area (address "F28B (H)"" that stores information indicating whether or not the value stored in the first storage area has reached a specific value (3 bytes full (FFFFFF (H))). D1 bit) and
It is determined whether or not the value stored in the first storage area has reached the specific value (step S2255 in FIG. 192).
When the value stored in the first storage area reaches the specific value, information indicating that the specific value has been reached is stored in the third storage area (step S2256, step S2259).
When the information indicating that the specific value has been reached is stored in the third storage area, even if the game medium is paid out during the special game, it is stored in the first storage area and the second storage area. The value is not updated (in FIG. 196, when "Yes" is determined in step S2301, the processing of steps S2302 to S2304 is not performed. In FIG. 199, when "Yes" is determined in step S2342, the value is not updated. , Steps S2343 to S2345 are not performed.)
It is characterized by that.
The second solution is, in the first solution,
The specific value is an upper limit value (“FFFFFF (H)”) of a storage capacity (3 bytes) that can be stored in the first storage area.

(C) Effect of Initial Invention 53 According to the initial invention, it is possible to prevent the value from being updated even after the storage capacity of the first storage area is exceeded and an overflow occurs. In particular, when the value stored in the first storage area reaches a specific value, the value in the second storage area is not updated, so that unnecessary updating can be eliminated. Furthermore, by updating the value of the second storage area when the first storage area overflows, it is possible to prevent the number of payouts during the Tobetsu game from being unable to be calculated correctly with respect to the total number of payouts. be able to.

54. Original invention 54
(A) Problems to be Solved by the Initial Invention 54 The initial invention relates to a gaming machine capable of reading the number of payouts of a gaming medium at a timing required for control processing.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
A method of simply updating the cumulative value of the number of payouts of the game medium as in the above-mentioned conventional technique is easy in terms of control.
On the other hand, in the gaming machine, when a small winning combination is won, the number of payouts corresponding to the small winning combination is stored in the RWM, and the number of payouts of the RWM is subtracted by "1" for each one payout (including one-card storage addition). There are cases where control is performed.
In the case of performing such control, when all the game media are paid out, the number of payouts stored in the RWM becomes "0". Therefore, after the payout of the game medium is completed, the number of payouts in the game cannot be read. Therefore, after the payout of the game medium is completed, there is a problem that it is not possible to read the payout number in the game and calculate the ratio or the like related to the payout number of the game medium.
The problem to be solved by the initial invention is to enable arithmetic processing such as a ratio regarding the number of payouts of the game medium even after the payout of the game medium is completed.

(B) Means for Solving the Problems of the Initial Invention 54 (Note that the corresponding embodiments are described in parentheses.)
The original invention (26th embodiment) is
The first storage area (data on the number of medals paid out at the address "F040 (H)") and the second storage area (the number of medals paid out at the address "F041 (H)") for storing the number of medals paid out when the small winning combination is won. With a buffer)
The number of payouts stored in the first storage area is subtracted as the game medium is paid out.
The number of payouts stored in the second storage area is maintained without being subtracted even when the game medium is paid out (FIG. 189, step S2213).
After executing the payout of the game medium (step S2189 in FIG. 188), a predetermined calculation related to the game (step S2193 in FIG. 188, and steps S2239 to S2241 in FIG. 191) is performed using the number of payouts of the game medium in the game. , S2243)
When executing the predetermined operation, the number of payouts stored in the second storage area is used (FIG. 197).
It is characterized by that.

(C) Effect of Initial Invention 54 According to the original invention, when a predetermined operation after the payout process is executed, the number of payouts stored in the second storage area is used. It can be executed at different timings. Further, even when a predetermined calculation is executed, the payout process is not affected.

55. Initial invention 55
(A) Problems to be Solved by the Initial Invention 55 The initial invention relates to a gaming machine that displays a payout ratio of a gaming medium.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the payout number of the gaming machine and determine whether or not to play the game. For example, the payout number is a predetermined design value. It was not possible to judge whether or not it was within the range of.
The problem to be solved by the initial invention is to display the payout ratio that can determine whether or not it is within the range of the predetermined design value. Further, as a result of calculating the payout ratio, for example, when a value that cannot be displayed is obtained, the calculated payout ratio can be corrected.

(B) Means for Solving the Problems of the Initial Invention 55 (Note that the corresponding embodiments are described in parentheses.)
The first solution (26th embodiment) is
A first storage area (total payout (cumulative) counter of address "F27C (H)") that stores a value corresponding to the total number of payouts of the game medium, and
It is provided with a second storage area (for example, a character payout (cumulative) counter at the address "F282 (H)") that stores a value corresponding to the number of payouts of the game medium during the special game.
Based on the values stored in the first storage area and the second storage area, it is possible to calculate the payout ratio indicating the number of payouts of the game medium during the special game to the total number of payouts of the game medium.
A third storage area (for example, the accessory ratio (cumulative) data of the address "F289 (H)") that stores the value corresponding to the calculated payout ratio, and
It is equipped with a display unit (management information display LED74 (digits 6 to 9)) capable of displaying the payout ratio based on the value stored in the third storage area.
When the result of calculating the payout ratio is a specific value (100%), the specific value is changed to a correction value (99%) (step S2405 in FIG. 202), and the correction value is stored in the third storage area. It is characterized in that the payout ratio can be displayed on the display unit based on the correction value stored in the storage (step S2406) and stored in the third storage area.

The second solution is
Display unit (management information display LED74 (digits 6-9)) and
A first storage area (total payout (cumulative) counter of address "F27C (H)") that stores a value corresponding to the total number of payouts of the game medium, and
It is provided with a second storage area (for example, a character payout (cumulative) counter at the address "F282 (H)") that stores a value corresponding to the number of payouts of the game medium during the special game.
When it is determined that the value stored in the first storage area and the value stored in the second storage area match and the value stored in the first storage area is not "0", the third storage area ( For example, the correction value (99 (H)) is stored in the accessory ratio (cumulative) data of the address “F289 (H)”, and the payout ratio is displayed on the display unit based on the correction value stored in the third storage area. The feature is that it can be displayed on.

The third solution is
Display unit (management information display LED74 (digits 6-9)) and
A first storage area (total payout (cumulative) counter of address "F27C (H)") that stores a value corresponding to the total number of payouts of the game medium, and
It is provided with a second storage area (for example, a character payout (cumulative) counter at the address "F282 (H)") that stores a value corresponding to the number of payouts of the game medium during the special game.
When it is determined that the value stored in the first storage area and the value stored in the second storage area match and the value stored in the second storage area is not "0", the third storage area ( For example, the correction value (99 (H)) is stored in the accessory ratio (cumulative) data of the address “F289 (H)”, and the payout ratio is displayed on the display unit based on the correction value stored in the third storage area. The feature is that it can be displayed on.

(C) Effect of Initial Invention 55 According to the initial invention, the payout ratio indicating the number of payouts during the special game is displayed with respect to the total number of payouts, so it is easy to determine whether or not the payout ratio is an appropriate value. be able to.
Further, when the calculated payout ratio is a specific value, the payout ratio is changed to the correction value, so that the payout ratio can be set to a value suitable for display.
Further, according to the second solution or the third solution, when the value stored in the first storage area or the second storage area is "0", it is prevented from being changed to the correction value. be able to.

56. Initial invention 56
(A) Problems to be Solved by Initial Invention 56 The initial invention relates to a gaming machine that stores a value capable of calculating a payout ratio of a gaming medium.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the payout number of the gaming machine and determine whether or not to play the game. For example, the payout number is a predetermined design value. It was not possible to judge whether or not it was within the range of.
Further, the cumulative value of the number of payouts cannot be stored infinitely, and the storage capacity of the RWM is finite, so that the upper limit value will be reached someday. However, when the upper limit is reached, if no processing is performed, the storage area overflows and the correct value cannot be stored.
The problem to be solved by the initial invention is to store a value that can calculate a payout ratio that can determine whether or not it is within a predetermined design value range. Further, depending on whether or not the number of memorized payouts has reached the upper limit of the storage capacity of the storage area, it is possible to memorize a more correct value even after reaching the upper limit. ..

(B) Means for Solving the Problems of the Initial Invention 56 (Note that the corresponding embodiments are described in parentheses.)
The original invention (26th embodiment) is
A first storage area (total payout (cumulative) counter of address "F27C (H)") that stores a value corresponding to the total number of payouts of the game medium, and
It is provided with a second storage area (for example, a character payout (cumulative) counter at the address "F282 (H)") that stores a value corresponding to the number of payouts of the game medium during the special game.
When the game medium is paid out during the special game, the values of the first storage area and the second storage area are updated.
If the upper limit of the storage capacity of the first storage area is not exceeded even if the value corresponding to the number of payouts in the game is added to the value stored in the first storage area, it corresponds to the number of payouts in the game. When the value is added to the value stored in the first storage area (in FIG. 197, when the process proceeds to step S2322, the process proceeds to FIG. 194, and in FIG. 194, when the value is “No” in step S2282 or “No” in step S2284, Finish counting up),
When the value corresponding to the number of payouts in the game is added to the value stored in the first storage area and exceeds the upper limit of the storage capacity of the first storage area (when "Yes" in step S2284 in FIG. 194). Calculates a correction value (in FIG. 194, the upper limit buffer value of the number of payouts in step S2286) that becomes the upper limit of the storage capacity of the first storage area when the value is added to the value stored in the first storage area. The correction value is added to the first storage area and the second storage area (step S2287).
It is characterized by that.

(C) Effect of Initial Invention 56 According to the initial invention, since the total number of payouts and the value corresponding to the number of payouts during the special game are stored, the ratio of the number of payouts during the special game to the total number of payouts is calculated. And can be displayed. Further, when the value corresponding to the total number of payouts exceeds the upper limit value of the storage capacity of the first storage area, the upper limit value is stored, so that the overflow of the digits of the first storage area is prevented and a more correct value is stored. Can be kept.

57. Original invention 57
(A) Problems to be Solved by the Initial Invention 57 The initial invention relates to a gaming machine that displays a payout ratio of a gaming medium.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the payout number of the gaming machine and determine whether or not to play the game. For example, the payout number is a predetermined design value. It was not possible to judge whether or not it was within the range of.
Furthermore, even if the number of payouts is an abnormal value between a specific number of games, it cannot be easily determined only from the graph showing the transition of the cumulative value of the number of payouts.
The problem to be solved by the initial invention is to store a value capable of calculating a payout ratio capable of determining whether or not the game is within a predetermined design value range during a predetermined number of games.

(B) Means for Solving the Problem of the Original Invention 57 (Note that the corresponding embodiments are described in parentheses.)
The first solution (26th embodiment) is
"X" (400) With a first payout number storage area (total payout ring buffers of addresses "F213 (H)" to "F22F (H)") that stores a value corresponding to the number of payouts of the game medium during the number of games. ,
A second payout number storage area (for example, address “F24F (H)” to “F26B (H)” character payout that stores a value corresponding to the number of payouts of the game medium during the special game during the “X” number of games. Ring buffer) and
A third payout number storage area (total payout (6000 times) counter of the address "F273 (H)") that stores a value corresponding to the number of payouts of the game medium during the "XY" (6000) games.
A fourth payout number storage area (for example, a character payout (6000 times) counter at the address "F279 (H)") that stores a value corresponding to the number of payouts of the game medium during the special game during the "XY" number of games. )When,
Payout ratio storage area (for example, the character ratio (6000 times) data of the address "F287 (H)") that stores a value corresponding to the payout ratio indicating the number of payouts of the game medium during the special game with respect to the total number of payouts of the game medium. ) And
The first payout number storage area and the second payout number storage area are each provided with "Y" (15) pieces.
The value corresponding to the number of payouts of the game medium during the "X" number of games is the "n"("n" = 1 to Y) th first payout storage area (for example, total payout ring buffer 0) and the second payout storage. When stored in the area (for example, the accessory payout ring buffer 0), the value corresponding to the number of payouts of the game medium during the next "X" number of games is "n + 1" (where "n" = Y). Is stored in the first payout storage area (for example, total payout ring buffer 1) and the second payout storage area (for example, accessory payout ring buffer 1) of the "n + 1" = 1.) th.
For each "X" number of games, the number of payouts during the special game is calculated based on the values stored in the third payout number storage area and the fourth payout number storage area with respect to the total number of payouts during the "XX" number of games. A value corresponding to the indicated payout ratio is calculated (steps S2385 to S2400 in FIG. 202), and the value stored in the payout ratio storage area is updated based on the calculation result (step S2406).
In the game in which the value stored in the payout ratio storage area is updated after the "XY" game,
a) A value corresponding to the number of payouts during the number of "X" games from "X x Y-1" before the game (5999 before the game) to "X x Y-X" before the game (before the 5600 game) is stored. The value stored in the third payout number storage area by subtracting the value "Z1" of the one payout number storage area from the value stored in the third payout number storage area (steps S2450 and S2452 in FIG. 205). Is updated (step S2454),
b) A value corresponding to the number of payouts during the number of "X" games from "X x Y-1" (before 5999 games) to "X x Y-X" before games (before 5600 games) is stored. 2 The value stored in the 4th payout number storage area by subtracting the value “Z2” of the payout number storage area from the value stored in the 4th payout number storage area (steps S2450 and S2452 in FIG. 205). Is updated (step S2454)
It is characterized by that.

The second solution is, in the first solution,
In the game in which the value stored in the payout ratio storage area is updated after the "XY" game, the value "Z1" in the first payout number storage area and the value "Z2" in the second payout number storage area are cleared. (Step S2453 in FIG. 205),
In the "X" game counts starting from the next game of the game in which the value stored in the payout ratio storage area is updated after the "X x Y" game,
a) A value corresponding to the number of payouts of the game medium is stored in the first payout number storage area that clears the value "Z1".
b) The second payout number storage area that clears the value "Z2" is characterized in that a value corresponding to the payout number of the game medium during the special game is stored.

(C) Effect of Initial Invention 57 According to the original invention, using "Y" first storage areas and second storage areas, for each "X" number of games, between "XXY" number of games The payout ratio can be stored. This makes it possible to display the payout ratio by reading the payout ratio.

58. Initial invention 58
(A) Problems to be Solved by the Initial Invention 58 The initial invention relates to a gaming machine that displays a payout ratio of a gaming medium.
Conventionally, there have been known gaming machines that store the cumulative value of the number of payouts and display a graph (so-called slump graph) showing the transition of the cumulative value of the number of payouts (see, for example, Japanese Patent Application Laid-Open No. 2007-125121).
However, the above-mentioned display in the conventional technique is used as a material for the player to confirm the payout number of the gaming machine and determine whether or not to play the game. For example, the payout number is a predetermined design value. It was not possible to judge whether or not it was within the range of.
Similarly, with respect to the so-called AT, it is not possible to determine whether or not the AT section for the entire game section is within the range of the predetermined design value.
On the other hand, when calculating the ratio that can determine whether the number of payouts or AT is within the range of the predetermined design value, if it is executed by the 1-chip microprocessor peculiar to the gaming machine, the calculation may take time. However, if the calculation time is long, there may be a problem that other processing may be affected.
The problem to be solved by the initial invention is to use a one-chip microprocessor peculiar to a gaming machine to simply calculate a ratio capable of determining whether or not it is within a predetermined design value in a short time. Is.

(B) Means for Solving the Problems of the Initial Invention 58 (Note that the corresponding embodiments are described in parentheses.)
The first solution (26th embodiment, etc.) is
A first storage area (counter for the total number of games played at the address "F26D (H)") that stores a value corresponding to the total number of games played.
It is provided with a second storage area (counter for the number of advantageous section games at the address "F270 (H)") that stores a value corresponding to the number of games played in a predetermined game section (advantageous section).
The value stored in the first storage area is "X",
The value stored in the second storage area is "Y".
When
a) Calculate "10 x Y" by multiplying "Y" by 10 (calculated value set in step S2389 in FIG. 202 (steps S2411 to S2413 in FIG. 203)).
b) Subtract "X" from "10 x Y", and when the value after subtraction is "X" or more, repeat subtracting "X" from the value after subtraction.
0 ≦ (10 × YX × R1) <X
"R1" that satisfies the condition is calculated (in FIG. 202, step S2391 (FIG. 204; ratio calculation execution)).
c) When "10 x YX x R1 = Y'" is set, "10 x Y'" is calculated by multiplying "Y'" by 10 (in FIG. 202, the calculated value set in step S2399 (FIG. 203). Middle, steps S2411 to S2413)),
d) Subtract "X" from "10 x Y'", and when the value after subtraction is "X" or more, repeat subtracting "X" from the value after subtraction.
0 ≦ (10 × Y'−X × R2) <X
"R2" that satisfies the condition is calculated (in FIG. 202, step S2400 (FIG. 204; ratio calculation execution)).
e) Calculate a specific ratio with the tens digit as "R1" and the ones digit as "R2" (step S2401 in FIG. 202).
It is characterized by that.

The second solution (26th embodiment, etc.) is
A first storage area (counter for the total number of games played at the address "F26D (H)") that stores a value corresponding to the total number of games played.
It is provided with a second storage area (counter for the number of advantageous section games at the address "F270 (H)") that stores a value corresponding to the number of games played in a predetermined game section.
The value stored in the first storage area is "X",
The value stored in the second storage area is "Y".
When
a) Calculate "10 x Y" by multiplying "Y" by 10 (calculated value set in step S2389 in FIG. 202 (steps S2411 to S2413 in FIG. 203)).
b) Subtract "X" from "10 x Y", and when the value after subtraction is "X" or more, repeat subtracting "X" from the value after subtraction.
0 ≦ (10 × YX × R1) <X
"R1" that satisfies the condition is calculated (in FIG. 202, step S2391 (FIG. 204; ratio calculation execution)).
c) When "10 x Y-X x R1 = Y'" and "Y'= 0", the tens digit is "R1" and the ones digit is "0". It is characterized by calculating.

The third solution is in the first or second solution.
Equipped with a display unit (management information display LED74 (digits 6 to 9)) capable of displaying the calculated specific ratio.
When the result of calculating the specific ratio is a specific value (100%) (when “Yes” in step S2404 in FIG. 202), the specific value is changed to a correction value (99%) (step S2405). , The correction value can be displayed on the display unit as a specific ratio.

(C) Effect of Initial Invention 58 According to the initial invention, the ratio can be calculated by dividing into tens and ones digits and repeating subtraction for each. As a result, the subtraction can be performed up to 20 times, so that the calculation time (processing time) can be shortened and the calculation can be simplified.

59. Initial invention 59
(A) Problems to be Solved by the Initial Invention 59 The initial invention relates to a slot machine provided with a display unit having a plurality of segments and displaying operation information of a stop switch advantageous to the player on the display unit. ..
In a conventional slot machine, the main control board decides whether or not to notify the operation information of the stop switch which is advantageous to the player, and when it is decided to notify, the operation information is connected to the main control board. A slot machine for displaying on a 7-segment display is known (see, for example, Japanese Patent Application Laid-Open No. 2014-150881).
Here, the operation information of the stop switch, which is advantageous to the player, is important information related to whether or not the medal is paid out.
However, if the segment of the 7-segment display is out of order or the signal line that transmits the signal to the segment is defective, the operation information of the stop switch, which is advantageous to the player, is not correctly displayed on the 7-segment display. , This may give a disadvantage to the player.
Therefore, the problem to be solved by the initial invention is in a slot machine provided with a display unit (7-segment display) having a plurality of segments and displaying operation information of a stop switch which is advantageous to the player on the display unit. It is to make it possible to confirm whether or not there is a failure in the segment and whether or not there is a failure in the signal line that transmits a signal to the segment.

(B) Means for Solving the Problems of the Initial Invention 59 (Note that the corresponding embodiments are described in parentheses.)
The first solution (28th embodiment) is
It has at least seven segments (segments A to G) that can be lit, and includes a first display unit (digit 3) and a second display unit (digit 4) that display predetermined information by lighting the segments.
Under the situation where the information regarding the number of acquired game media (the number of acquired medals) is displayed (when the process proceeds to the medal payout process by winning in step S4015 in the main process of FIG. 227), the first interrupt process (LED display counter value). (Interrupt processing when is "00100000 (B)"), the first digit (upper digit) of the information regarding the number of acquired game media is displayed on the first display unit, and the second interrupt processing (LED display counter value is In the interrupt processing at the time of "01000000 (B)"), the second digit (lower digit) of the information regarding the number of acquired game media is displayed on the second display unit.
Under the situation where the operation information (push order instruction information) of the stop switch (42), which is advantageous to the player, is displayed (when the process proceeds to the push order instruction number set process in step S4012 in the main process of FIG. 227), at least In the first interrupt process, at least a part of the operation information is displayed on the first display unit, and the operation information is displayed on the first display unit.
Under the situation where the set value related to the player's advantage can be changed (when the process proceeds to steps S4001 and S4002 in the setting change process of FIG. 226), at least 7 of the first display unit in the first interrupt process. It is characterized by lighting individual segments.

The second solution is
It has at least 7 segments that can be lit, and has a first display unit and a second display unit that display predetermined information by illuminating the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a segment signal is output so that at least a part of the operation information is displayed on the first display unit in the first interrupt processing.
Under the situation where the set value related to the player's advantage can be changed, at least the segment signal is output so as to light at least seven segments of the second display unit in the second interrupt process. And.

The third solution is
It has at least 7 segments that can be lit, and has a first display unit and a second display unit that display predetermined information by illuminating the segments.
Under the situation where the information regarding the acquired number of game media is displayed, the first digit of the information regarding the acquired number of game media is displayed on the first display unit in the first interrupt process, and the game medium is displayed in the second interrupt process. The second digit of the information about the number of acquisitions is displayed on the second display.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a part of the operation information is displayed on the second display unit in the second interrupt process.
Under a situation where the set value related to the player's advantage can be changed, at least seven segments of the second display unit are lit in the second interrupt process.

The fourth solution is
It has at least 7 segments that can be lit, and has a first display unit and a second display unit that display predetermined information by illuminating the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a segment signal is output so that at least a part of the operation information is displayed on the second display unit in the second interrupt processing.
Under the situation where the set value related to the player's advantage can be changed, at least the segment signal is output so as to light at least seven segments of the first display unit in the first interrupt process. And.

The fifth solution is
It has at least 7 segments that can be lit, and has a first display unit and a second display unit that display predetermined information by illuminating the segments.
Under the situation where the information regarding the acquired number of game media is displayed, the first digit of the information regarding the acquired number of game media is displayed on the first display unit in the first interrupt process, and the game medium is displayed in the second interrupt process. The second digit of the information about the number of acquisitions is displayed on the second display.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, a part of the operation information is displayed on the first display unit in the first interrupt processing, and the operation information is displayed in addition to the operation information in the second interrupt processing. Is displayed on the second display,
Under the situation where the set value related to the player's advantage can be changed, at least seven segments of the first display unit are lit in the first interrupt processing, and the second display unit has the second interrupt processing. It is characterized by lighting at least 7 segments.

(C) Effect of Initial Invention 59 According to the initial invention, the first display unit is checked by confirming whether or not the seven segments of the first display unit are lit under the condition that the set value can be changed. It is possible to confirm whether or not there is a failure in the seven segments of the first display unit and whether or not there is a failure in the signal line that transmits a signal to the seven segments of the first display unit.

60. Original invention 60
(A) Problems to be solved by the original invention 60 Same as the original invention 59.
(B) Means for Solving the Problems of the Initial Invention 60 (Note that the corresponding embodiments are described in parentheses.)
The first solution (29th embodiment) is
It has a plurality of lightable segments (segments A to G), and includes a first display unit (digit 3) and a second display unit (digit 4) that display predetermined information by lighting the segments.
In the first display unit and the second display unit, segment signals (segments A to G signals) indicating which segment is to be lit are also used.
Under the situation where the information regarding the number of acquired game media (the number of acquired medals) is displayed (when the process proceeds to the medal payout process by winning in step S4015 in the main process of FIG. 227), the first interrupt process (LED display counter value). The segment signal is output so that the first digit (upper digit) of the information regarding the number of acquired game media is displayed on the first display unit in the interrupt processing when is "000000100 (B)"), and the second digit is output. A segment signal so that the second digit (lower digit) of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt processing (interrupt processing when the LED display counter value is "00001000 (B)"). Output,
Under the situation where the operation information (push order instruction information) of the stop switch (42), which is advantageous to the player, is displayed (when the process proceeds to the push order instruction number set process in step S4012 in the main process of FIG. 227), at least In the first interrupt process, a segment signal is output so that at least a part of the operation information is displayed on the first display unit.
Under the situation where the set value related to the player's advantage can be changed (when the process proceeds to steps S4101 and S4102 in the setting change process of FIG. 234), at least the information regarding the set value (set value " It is characterized in that a segment signal is output so that any one of "1" to "6") is displayed on the second display unit.

The second solution is
It has a plurality of segments that can be lit, and includes a first display unit and a second display unit that display predetermined information by lighting the segments.
Under the situation where the information regarding the acquired number of game media is displayed, the first digit of the information regarding the acquired number of game media is displayed on the first display unit in the first interrupt process, and the game medium is displayed in the second interrupt process. The second digit of the information about the number of acquisitions is displayed on the second display.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a part of the operation information is displayed on the second display unit in the second interrupt process.
In a situation where the set value related to the player's advantage can be changed, at least in the second interrupt process, the information about the set value is displayed on the second display unit.

The third solution is
It has a plurality of segments that can be lit, and includes a first display unit and a second display unit that display predetermined information by lighting the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, the segment signal is output so that a part of the operation information is displayed on the first display unit in the first interrupt processing, and the second interrupt processing is performed. In the interrupt processing, a segment signal is output so that the other part of the operation information is displayed on the second display unit.
In a situation where the set value related to the player's advantage can be changed, at least the segment signal is output so that the information on the set value is displayed on the second display unit in the second interrupt process. ..

(C) Effect of Initial Invention 60 According to the initial invention, the segment signal is also used in the first display unit and the second display unit. Therefore, by confirming whether or not the segments of the first display unit and the second display unit are lit, the first display of the signal lines for transmitting signals to the segments of the first display unit and the second display unit is displayed. It is possible to confirm the presence or absence of a failure in the common part between the unit and the second display unit.
In addition, by displaying the first digit of the information regarding the number of acquired game media on the first display unit, it is confirmed whether or not the segment of the first display unit is lit, and the segment of the first display unit fails. It is possible to confirm whether or not there is an obstacle in the signal line that transmits a signal to the segment of the first display unit.

61. Initial invention 61
(A) Problems to be solved by the original invention 61 Same as the original invention 59.
(B) Means for Solving the Problems of the Initial Invention 61 (Note that the corresponding embodiments are described in parentheses).
The first solution (28th embodiment) is
A first display unit (digit 1), a second display unit (digit 2), and a third display unit (digit) that have a plurality of lightable segments (segments A to G) and display predetermined information by lighting the segments. 3) and a fourth display unit (digit 4)
In the first display unit, the second display unit, the third display unit, and the fourth display unit, segment signals (segments A to G signals) indicating which segment is to be lit are also used.
Under the condition of displaying the information (the number of medals stored) regarding the number of stored game media (when proceeding to the main processing of FIG. 227), at least the first interrupt processing (LED display counter value is "00001000 (B)"". The segment signal is output so that the first digit (upper digit) of the information regarding the number of stored game media is displayed on the first display unit in the interrupt processing at the time of), and the second interrupt processing (LED display counter value) Is (interrupt processing when is “00010000 (B)”), a segment signal is output so that the second digit (lower digit) of the information regarding the number of stored game media is displayed on the second display unit.
Under the situation where the information regarding the number of acquired game media (the number of acquired medals) is displayed (when the process proceeds to the medal payout process by winning in step S4015 in the main process of FIG. 227), at least the third interrupt process (LED display). The segment signal is output so that the first digit (upper digit) of the information regarding the number of acquired game media is displayed on the third display unit in the interrupt processing when the counter value is “00100000 (B)”). In the interrupt processing of 4 (interrupt processing when the LED display counter value is "01000000 (B)"), the second digit (lower digit) of the information regarding the number of acquired game media is displayed on the fourth display unit. Outputs a segment signal and
Under the situation where the operation information (push order instruction information) of the stop switch (42), which is advantageous to the player, is displayed (when the process proceeds to the push order instruction number set process in step S4012 in the main process of FIG. 227), at least The third interrupt process is characterized in that a segment signal is output so that at least a part of the operation information is displayed on the third display unit.

The second solution is
It has a plurality of segments that can be lit, and includes a first display unit, a second display unit, a third display unit, and a fourth display unit that display predetermined information by lighting the segments.
In the first display unit, the second display unit, the third display unit, and the fourth display unit, a segment signal indicating which segment is to be lit is also used.
Under the situation where the information regarding the number of stored game media is displayed, at least in the first interrupt process, the segment signal is output so that the first digit of the information regarding the number of stored game media is displayed on the first display unit. , A segment signal is output so that the second digit of the information regarding the number of stored game media is displayed on the second display unit in the second interrupt process.
Under the situation of displaying the information regarding the acquired number of game media, a segment signal is output so that at least the first digit of the information regarding the acquired number of game media is displayed on the third display unit in the third interrupt process. , A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the fourth display unit in the fourth interrupt process.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a segment signal is output so that at least a part of the operation information is displayed on the fourth display unit in the fourth interrupt process. It is characterized by.

The third solution is
It has a plurality of segments that can be lit, and includes a first display unit, a second display unit, a third display unit, and a fourth display unit that display predetermined information by lighting the segments.
In the first display unit, the second display unit, the third display unit, and the fourth display unit, a segment signal indicating which segment is to be lit is also used.
Under the situation where the information regarding the number of stored game media is displayed, at least in the first interrupt process, the segment signal is output so that the first digit of the information regarding the number of stored game media is displayed on the first display unit. , A segment signal is output so that the second digit of the information regarding the number of stored game media is displayed on the second display unit in the second interrupt process.
Under the situation of displaying the information regarding the acquired number of game media, a segment signal is output so that at least the first digit of the information regarding the acquired number of game media is displayed on the third display unit in the third interrupt process. , A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the fourth display unit in the fourth interrupt process.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a segment signal is output so as to display a part of the operation information on the third display unit in the third interrupt process, and the third is performed. The interrupt processing of No. 4 is characterized in that a segment signal is output so that the other part of the operation information is displayed on the fourth display unit.

(C) Effect of Initial Invention 61 According to the initial invention, segment signals are also used in the first display unit to the fourth display unit. Therefore, by confirming whether or not the segments of the first display unit to the fourth display unit are lit, the first display of the signal lines for transmitting the signal to the segments of the first display unit to the fourth display unit is displayed. It is possible to confirm the presence or absence of a failure in the parts common to the parts to the fourth display part.
In addition, by displaying the first digit of the information regarding the number of acquired game media on the third display unit, it is confirmed whether or not the segment of the third display unit is lit, and the segment of the third display unit fails. It can be confirmed whether or not there is a failure of the signal line that transmits a signal to the segment of the third display unit.

62. Original invention 62
(A) Problems to be solved by the original invention 62 Same as the original invention 59.
(B) Means for Solving the Problem of Initial Invention 62 (Note that the corresponding embodiments are described in parentheses.)
The first solution (28th embodiment) is
It has a plurality of lightable segments (segments A to G), and includes a first display unit (digit 3) and a second display unit (digit 4) that display predetermined information by lighting the segments.
In the first display unit and the second display unit, segment signals (segments A to G signals) indicating which segment is to be lit are also used.
Under the situation where the information regarding the number of acquired game media (the number of acquired medals) is displayed (when the process proceeds to the medal payout process by winning in step S4015 in the main process of FIG. 227), the first interrupt process (LED display counter value). Is "interrupt processing when" 00100000 (B) "), a segment signal is output so that the first digit (upper digit) of the information regarding the number of acquired game media is displayed on the first display unit, and the second digit is output. A segment signal so that the second digit (lower digit) of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt processing (interrupt processing when the LED display counter value is "01000000 (B)"). Output,
Under the situation where the operation information (push order instruction information) of the stop switch (42), which is advantageous to the player, is displayed (when the process proceeds to the push order instruction number set process in step S4012 in the main process of FIG. 227), at least In the first interrupt process, a segment signal is output so that at least a part of the operation information is displayed on the first display unit.
Under the situation where specific error information (“E1” error) is displayed (when an unrecoverable error occurs), a part of the specific error information is displayed on the first display unit without executing interrupt processing. The process of outputting the segment signal (the error high-order digit display output process of step S1497 in the unrecoverable error process 1 of FIG. 136) and the other part of the specific error information are displayed on the second display unit. As described above, the process of outputting the segment signal (the error lower digit display output process of step S1502 in the unrecoverable error process 1 of FIG. 136) is repeatedly executed.

The second solution is
It has a plurality of segments that can be lit, and includes a first display unit and a second display unit that display predetermined information by lighting the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a segment signal is output so that at least a part of the operation information is displayed on the second display unit in the second interrupt processing.
Under the situation where specific error information is displayed, a process of outputting a segment signal so as to display a part of the specific error information on the first display unit without executing interrupt processing, and the specific error information. It is characterized in that the process of outputting a segment signal is repeatedly executed so that the other part is displayed on the second display unit.

The third solution is
It has a plurality of segments that can be lit, and includes a first display unit and a second display unit that display predetermined information by lighting the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, the segment signal is output so that a part of the operation information is displayed on the first display unit in the first interrupt processing, and the second interrupt processing is performed. In the interrupt processing, a segment signal is output so that the other part of the operation information is displayed on the second display unit.
Under the situation where specific error information is displayed, a process of outputting a segment signal so as to display a part of the specific error information on the first display unit without executing interrupt processing, and the specific error information. It is characterized in that the process of outputting a segment signal is repeatedly executed so that the other part is displayed on the second display unit.

(C) Effect of Initial Invention 62 According to the original invention, the segment signal is also used in the first display unit and the second display unit. Therefore, by confirming whether or not the segments of the first display unit and the second display unit are lit, the first display of the signal lines for transmitting signals to the segments of the first display unit and the second display unit is displayed. It is possible to confirm the presence or absence of a failure in the common part between the unit and the second display unit.
In addition, by displaying the first digit of the information regarding the number of acquired game media and a part of the specific error information on the first display unit, it is possible to confirm whether or not the segment of the first display unit is lit. , It is possible to confirm whether or not there is a failure in the segment of the first display unit and whether or not there is a failure in the signal line that transmits a signal to the segment of the first display unit.

63. Initial invention 63
(A) Problems to be solved by the original invention 63 Same as the original invention 59.
(B) Means for Solving the Problem of Initial Invention 63 (Note that the corresponding embodiments are described in parentheses.)
The first solution (28th embodiment) is
It has a plurality of lightable segments (segments A to G), and includes a first display unit (digit 3) and a second display unit (digit 4) that display predetermined information by lighting the segments.
In the first display unit and the second display unit, segment signals (segments A to G signals) indicating which segment is to be lit are also used.
Under the situation where the information regarding the number of acquired game media (the number of acquired medals) is displayed (when the process proceeds to the medal payout process by winning in step S4015 in the main process of FIG. 227), the first interrupt process (LED display counter value). Is "interrupt processing when" 00100000 (B) "), a segment signal is output so that the first digit (upper digit) of the information regarding the number of acquired game media is displayed on the first display unit, and the second digit is output. A segment signal so that the second digit (lower digit) of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt processing (interrupt processing when the LED display counter value is "01000000 (B)"). Output,
Under the situation where the operation information (push order instruction information) of the stop switch (42), which is advantageous to the player, is displayed (when the process proceeds to the push order instruction number set process in step S4012 in the main process of FIG. 227), at least In the first interrupt process, a segment signal is output so that at least a part of the operation information is displayed on the first display unit.
Under the situation where the predetermined error information (“dE” error) is displayed (when a recoverable error occurs), a part of the predetermined error information is displayed on the first display unit in the first interrupt process. , The segment signal is output, and the segment signal is output so that the other part of the predetermined error information is displayed on the second display unit in the second interrupt process.

The second solution is
It has a plurality of segments that can be lit, and includes a first display unit and a second display unit that display predetermined information by lighting the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, at least a segment signal is output so that at least a part of the operation information is displayed on the second display unit in the second interrupt processing.
Under the situation where the predetermined error information is displayed, the segment signal is output so that a part of the predetermined error information is displayed on the first display unit in the first interrupt processing, and the predetermined error information is displayed in the second interrupt processing. It is characterized in that a segment signal is output so that the other part of the error information of is displayed on the second display unit.

The third solution is
It has a plurality of segments that can be lit, and includes a first display unit and a second display unit that display predetermined information by lighting the segments.
In the first display unit and the second display unit, a segment signal indicating which segment is to be turned on is also used.
Under the situation where the information regarding the number of acquired game media is displayed, the segment signal is output so as to display the first digit of the information regarding the number of acquired game media in the first interrupt process on the first display unit. A segment signal is output so that the second digit of the information regarding the number of acquired game media is displayed on the second display unit in the interrupt process of 2.
Under the situation where the operation information of the stop switch which is advantageous to the player is displayed, the segment signal is output so that a part of the operation information is displayed on the first display unit in the first interrupt processing, and the second interrupt processing is performed. In the interrupt processing, a segment signal is output so that the other part of the operation information is displayed on the second display unit.
Under the situation where the predetermined error information is displayed, the segment signal is output so that a part of the predetermined error information is displayed on the first display unit in the first interrupt processing, and the predetermined error information is displayed in the second interrupt processing. It is characterized in that a segment signal is output so that the other part of the error information of is displayed on the second display unit.

(C) Effect of Initial Invention 63 According to the initial invention, the segment signal is also used in the first display unit and the second display unit. Therefore, by confirming whether or not the segments of the first display unit and the second display unit are lit, the first display of the signal lines for transmitting signals to the segments of the first display unit and the second display unit is displayed. It is possible to confirm the presence or absence of a failure in the common part between the unit and the second display unit.
In addition, by displaying the first digit of the information regarding the number of acquired game media and a part of the predetermined error information on the first display unit, it is confirmed whether or not the segment of the first display unit is lit. , It is possible to confirm whether or not there is a failure in the segment of the first display unit and whether or not there is a failure in the signal line that transmits a signal to the segment of the first display unit.

64. Original invention 64
(A) Problem to be Solved by Initial Invention 64 In the conventional technique, a counter is required to count the advantageous mode. Therefore, it is necessary to execute a process of determining whether or not the game (current state) is in the advantageous mode, and a process of updating the counter when it is determined that the game is in the advantageous mode.
The problem to be solved by the initial invention is to simplify information processing by updating the advantageous section counter without determining whether or not it is an advantageous section.

(B) Means for Solving the Problems of the Initial Invention 64 (Note that the corresponding embodiments are described in parentheses.)
The original invention (30th embodiment) is
An advantageous mode display means (acquired number display LED78) for displaying an advantageous operation mode (correct answer pressing order) of the stop switch (42), and
A normal section (including a standby section) in which an advantageous operation mode cannot be displayed by the advantageous mode display means, and
An advantageous section in which an advantageous operation mode may be displayed by the advantageous mode display means, and an advantageous section.
Advantageous section information storage means (RWM53) capable of storing information indicating an advantageous section (D0th bit of the advantageous section type flag), and
Equipped with an advantageous section counter (advantageous section clear counter)
When starting the advantageous section, a specific value (1500 (D)) is stored in the advantageous section counter.
Regardless of whether or not it is an advantageous section, "1" can be subtracted from the advantageous section counter at a predetermined timing based on the progress of the game (step S2742 in FIG. 246).
After starting the advantageous section, when the value of the advantageous section counter becomes "0" (when it becomes "Yes" in step S2744 in FIG. 246), the advantageous section ends (step in FIG. 246). S2746),
When a carry occurs as a result of subtracting "1" from the advantageous section counter, "0" is stored in the advantageous section counter (step S2761 in FIG. 247), and the advantageous section information storage means is used to store the advantageous section. When the indicated information is not stored (“No” in step S2747 in FIG. 246), the value of the advantageous section counter is not changed from “0”.

(C) Effect of Initial Invention 64 According to the initial invention, the advantageous section counter can be updated without determining whether or not the section is advantageous.

65. Initial invention 65
(A) Problems to be solved by the original invention 65 Same as the original invention 64.
(B) Means for Solving the Problems of the Initial Invention 65 (Note that the corresponding embodiments are described in parentheses.)
The original invention (30th embodiment) is
An advantageous mode display means (acquired number display LED78) for displaying an advantageous operation mode (correct answer pressing order) of the stop switch (42), and
A normal section (including a standby section) in which an advantageous operation mode cannot be displayed by the advantageous mode display means, and
An advantageous section in which an advantageous operation mode may be displayed by the advantageous mode display means, and an advantageous section.
Advantageous section information storage means (RWM53) capable of storing information indicating an advantageous section (D0th bit of the advantageous section type flag), and
Equipped with an advantageous section counter (advantageous section clear counter)
Regardless of whether or not it is an advantageous section, "1" can be subtracted from the advantageous section counter at a predetermined timing based on the progress of the game (step S2742 in FIG. 246).
When a carry occurs as a result of subtracting "1" from the advantageous section counter, "0" is stored in the advantageous section counter (step S2761 in FIG. 247), and the advantageous section information storage means is used to store the advantageous section. When the indicated information is stored (“Yes” in step S2747 in FIG. 246), a specific value (1500 (D)) is stored in the advantageous section counter.
After starting the advantageous section, when the value of the advantageous section counter becomes "0" (when it becomes "Yes" in step S2744 in FIG. 246), the advantageous section is terminated.
(C) Effect of the original invention 65 Same as the original invention 64.

66. Initial invention 66
(A) Problems to be solved by the original invention 66 Same as the original invention 64.
(B) Means for Solving the Problems of the Initial Invention 66 (Note that the corresponding embodiments are described in parentheses.)
The first solution (30th embodiment) is
An advantageous mode display means (acquired number display LED78) for displaying an advantageous operation mode (correct answer pressing order) of the stop switch (42), and
A normal section (including a standby section) in which an advantageous operation mode cannot be displayed by the advantageous mode display means, and
An advantageous section in which an advantageous operation mode may be displayed by the advantageous mode display means, and an advantageous section.
When it is decided to shift to the advantageous section in the normal section, the waiting section that can be shifted before shifting to the advantageous section and the waiting section
A standby section information storage means (RWM53) capable of storing information indicating a standby section (D1 bit of the advantageous section type flag) and
Equipped with an advantageous section counter (advantageous section clear counter)
When starting the advantageous section, a specific value (1500 (D)) is stored in the advantageous section counter.
Regardless of whether or not it is an advantageous section, "1" can be subtracted from the advantageous section counter at a predetermined timing based on the progress of the game (step S2742 in FIG. 246).
After starting the advantageous section, when the value of the advantageous section counter becomes "0" (when it becomes "Yes" in step S2744 in FIG. 246), the advantageous section ends.
When a carry occurs as a result of subtracting "1" from the advantageous section counter, "0" is stored in the advantageous section counter (step S2761 in FIG. 247), and the waiting section is stored in the waiting section information storage means. When the indicated information is stored, the value of the advantageous section counter is not changed from "0"("No" in step S2747 in FIG. 246).
It is characterized by that.
The second solution is, in the first solution,
It is provided with an advantageous section information storage means (RWM53) capable of storing information indicating an advantageous section (D0th bit of the advantageous section type flag).
When a carry occurs as a result of subtracting "1" from the advantageous section counter, "0" is stored in the advantageous section counter (step S2761 in FIG. 247), and the advantageous section information storage means is used to store the advantageous section. When the indicated information is not stored, the value of the advantageous section counter is not changed from "0"("No" in step S2747 in FIG. 246).
It is characterized by that.
(C) Effect of the original invention 66 Same as the original invention 64.

67. Original invention 67
(A) Problems to be solved by the original invention 67 Same as the original invention 64.
(B) Means for Solving the Problem of Initial Invention 67 (Note that the corresponding embodiment is described in parentheses.)
The original invention (30th embodiment) is
An advantageous mode display means (acquired number display LED78) for displaying an advantageous operation mode (correct answer pressing order) of the stop switch (42), and
A normal section (including a standby section) in which an advantageous operation mode cannot be displayed by the advantageous mode display means, and
An advantageous section in which an advantageous operation mode may be displayed by the advantageous mode display means, and an advantageous section.
Advantageous section information storage means (RWM53) capable of storing information indicating an advantageous section (D0th bit of the advantageous section type flag), and
Equipped with an advantageous section counter (advantageous section clear counter)
When starting the advantageous section, a specific value (1500 (D)) is stored in the advantageous section counter.
Regardless of whether or not it is an advantageous section, "1" can be subtracted from the advantageous section counter at a predetermined timing based on the progress of the game (step S2742 in FIG. 246).
When "0" is obtained as a result of subtracting "1" from the advantageous section counter ("Yes" in step S2744 in FIG. 246), at least the information stored in the advantageous section information storage means is cleared (in FIG. 246, "Yes"). In FIG. 246, step S2746) is characterized by ending the advantageous section.
(C) Effect of Initial Invention 67 According to the initial invention, the advantageous section counter can be updated without determining whether or not the section is advantageous. In addition, the information stored in the advantageous section information storage means can be cleared at an appropriate timing when the advantageous section ends.

68. Initial invention 68
(A) Problems to be solved by the original invention 68 Same as the original invention 64.
(B) Means for Solving the Problems of the Initial Invention 68 (Note that the corresponding embodiments are described in parentheses.)
The original invention (30th embodiment) is
An advantageous mode display means (acquired number display LED78) for displaying an advantageous operation mode (correct answer pressing order) of the stop switch (42), and
A normal section (including a standby section) in which an advantageous operation mode cannot be displayed by the advantageous mode display means, and
An advantageous section in which an advantageous operation mode may be displayed by the advantageous mode display means, and an advantageous section.
Advantageous section information storage means (RWM53) capable of storing information indicating an advantageous section (D0th bit of the advantageous section type flag), and
Equipped with an advantageous section counter (advantageous section clear counter)
When starting the advantageous section, a specific value (1500 (D)) is stored in the advantageous section counter.
Regardless of whether or not it is an advantageous section, "1" can be subtracted from the advantageous section counter at a predetermined timing based on the progress of the game (step S2742 in FIG. 246).
There is a case where the end condition of the advantageous section is satisfied before the value of the advantageous section counter becomes "0".
When the end condition of the advantageous section is satisfied before the value of the advantageous section counter becomes "0", "1" is stored in the advantageous section counter (step S2823 in FIG. 252), and then the advantageous section is performed. "1" was subtracted from the advantageous section counter based on the execution of the game (step S2742 in FIG. 246), and the advantageous section counter became "0"("Yes" in step S2744 in FIG. 246). Based on the above, at least the information stored in the advantageous section information storage means is cleared (step S2746 in FIG. 246), and the advantageous section is terminated.

(C) Effect of Initial Invention 68 According to the initial invention, the advantageous section counter can be updated without determining whether or not the section is advantageous. Further, even when the advantageous section is terminated when the advantageous section counter is not "0", the advantageous section counter can be set to "0" and the information stored in the advantageous section information storage means can be cleared at an appropriate timing.

69. Original invention 69
(A) Problems to be solved by the original invention 69 In the initial invention, the ratio of "(total number of payouts when the accessory is activated and the number of payouts when the instruction function is activated) / total number of payouts" is used for each set value. It relates to a gaming machine displayed on a ratio monitor.
In a conventional gaming machine, four 7-segments provided on the main control board provide an advantageous section ratio, a continuous bonus ratio (6000 times), a bonus ratio (6000 times), a continuous bonus ratio (cumulative), and a combination. There are known gaming machines equipped with a so-called "combination ratio monitor" that sequentially displays the object ratio (cumulative) (see, for example, FIGS. 3 and 38 of Japanese Patent No. 6112524).
However, in the above-mentioned conventional technique, although it is possible to confirm the ratio of the accessory such as 1BB, it is not possible to confirm how many medals have been paid out when the non-commentary instruction function (ART) is activated. rice field.
In particular, the instruction function is not the accessory itself, but can be said to be a function similar to the accessory. However, since it is not possible to know how many medals have been paid out by the operation of the instruction function, it is not possible to judge from the role ratio monitor whether or not there is a risk of remarkably intriguing gambling.
Also, since the displayed ratio is the total of all the set values, it is not possible to check the ratio for each set value, so for each set value, whether or not the ratio is within the design range is checked. I couldn't judge.
The problem to be solved by the initial invention is to make it possible to confirm the ratio of "(total number of payouts when the accessory is activated and the number of payouts when the instruction function is activated) / total number of payouts".
Furthermore, it is possible to confirm the ratio for each set value.

(B) Means for Solving the Problems of the Original Invention 69 (Note that the corresponding embodiments are described in parentheses.)
The original invention (31st embodiment) is
In a game having an advantageous operation mode of the stop switch, an instruction function operating game that activates an instruction function for displaying the advantageous operation mode, and a game in which the instruction function is activated.
A means to determine one of the multiple setting values,
A first storage means for storing the total number of game media paid out for each set value,
A second storage means for storing the total of the number of game media paid out during the special game and the number of game media paid out in the instruction function operating game for each set value.
For each set value, based on the values stored in the first storage means and the second storage means, "(total of the number of payouts of the game medium during the special game and the number of payouts in the instruction function operating game) / total number of payouts. And the calculation means to calculate the predetermined ratio corresponding to
Each set value is characterized by being provided with a means for displaying the predetermined ratio when the condition for displaying the predetermined ratio is satisfied based on the values stored in the first storage means and the second storage means. do.

(C) Effect of Initial Invention 69 According to the original invention, the ratio of "(total number of payouts when the accessory is activated and the number of payouts when the instruction function is activated) / total number of payouts" can be confirmed for each set value. , It is possible to confirm whether or not the ratio is within the design range for each set value.
Further, it is possible to confirm not only the payout ratio when the accessory is activated but also the payout ratio including the number of payouts when the instruction function is activated.

1 Base part 10 Slot machine 11 Power switch 12 Setting key switch 13 Setting switch 14 Reset switch 15 Door switch 16 Board case 16a Caulking part 17 Display window 21 Direction lamp 22 Speaker 23 Image display device 24 Cross key 25 Menu button 31 Reel 32 Motor 33 Reel sensor 35 Hopper 36 Hopper motor 37 Payout sensor 40a 1-bet switch 40b 3-bet switch 41 Start switch 42 Stop switch 43 Medal insertion slot 43a Passage sensor 44 Input sensor 45 Blocker 46 Settlement switch 50 (50A, 50B) Main control board (50A, 50B) Main control means)
51 Input port 52 Output port 53 RWM
54 ROM
55 Main CPU
61 Winning flag control means 62 Winning flag control means 63 Push order instruction number selection means 64 Production group number selection means 65 Reel control means 66 Winning judgment means 67 Payout means 68 RT control means 69 Advantageous section control means 69a Advantageous section counter 69b Upper limit counter 70 External signal transmission means 71 Control command transmission means 72 Management information control means 73 Set value display LED
74 Management information display LED
75 Display board 76 Storage number display LED
77 Advantageous section display LED
78 Number of acquisitions 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 display LED
79f replay display LED
79g production display LED
80 Sub control board (sub control means)
81 Input port 82 Output port 83 RWM
84 ROM
85 sub CPU
91 Production output control means 100 External centralized terminal board 200 Hall computer

Claims (1)

First display means and
Second display means and
A first storage means that can store the value of the total number of game media granted,
Grant number of game media in the gaming that character object is activated, and a second memory means capable of storing a total value of the granted number of game media in the gaming who informed advantageous operation mode of the stop switch to the second display means With
In a predetermined situation where the value stored in the first storage means does not reach a predetermined upper limit value, the game is a game in which the accessory does not operate, and the second display means is provided with an advantageous operation mode of the stop switch. In the game that did not notify, the value stored in the second storage means is not updated regardless of whether or not the game medium is attached.
A gaming machine characterized in that predetermined ratio information based on a value stored in a first storage means and a value stored in a second storage means can be displayed on the first display means.

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