JP7125623B2 - game machine - Google Patents

Description

The present invention relates to a gaming machine such as a slot machine, a pachinko gaming machine, or the like, in which game media are inserted, the reels are rotated and then stopped, and a game result is determined by a combination of symbols drawn on the reels displayed at that time. .

2. Description of the Related Art Conventionally, a slot machine (rotary drum type game machine) is known as one of the game machines. In this slot machine, a player inserts game media such as game medals, and operates a start lever to rotate a plurality of reels on which patterns are drawn. After that, the player operates the stop button to stop each reel, and depending on the combination of stopped symbols (display results), it is possible to receive a predetermined number of game medals or the like paid out. In addition, in the slot machine, in addition to such basic games, various effects are performed to improve the fun as a whole.
JP 2019-195659 A

By the way, in this type of slot machine, a series of individual basic operations such as acceptance of insertion of game media (game medals, etc.), rotation of reels, performance control, stopping of reels, payout of game medals, etc. is repeated as the action of Although it is desirable that these operations are performed properly in any case, it is conceivable that an unexpected operation may be performed when various situations occur in combination. Therefore, it is effective to assume as many complex situations as possible and decide in advance what operations are to be performed in those situations. In recent years, there have been known slot machines of the type in which the number of wins can be gradually increased over an appropriate amount of time by repeatedly devising game characteristics. It is desirable to

The present invention has been made in view of these problems, and its object is to provide a gaming machine having more optimized functions.

In order to solve the above problems, the present invention provides a plurality of reels,
a start lever and
and a plurality of stop buttons,
A winning lottery can be executed according to a predetermined number of bets,
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) that is greater than the first number of bets;
A first bet number game (two bet game, etc.) in which the first bet number is set can be executed,
A second bet number game (three bet game, etc.) in which the second bet number is set can be executed,
In the next game when the first specific combination is won in the role lottery in the first bet number game, and there is no stop display of the predetermined symbol combination related to the first specific combination in the first bet number game, It becomes possible to execute a game in the first internal winning state (such as a game of "2 bet BB inside"),
In the next game when the second specific combination is won in the role lottery in the second bet number game, and there is no stop display of the specific symbol combination related to the second bet number game in the second bet number game, It becomes possible to execute a game in the second internal winning state (such as a game of "3 bet BB inside"),
When there is a stop display of the predetermined symbol combination related to the first specific combination, a game in the first bonus state (such as a game of "2 bet BB") can be executed,
When there is a stop display of the specific symbol combination for the second specific combination, a game in the second bonus state (such as a "3-bet BB" game) can be executed.
A game can be executed in a predetermined game state (such as "non-internal state") different from any of the first internal winning state, the first bonus state, the second internal winning state, and the second bonus state. can be,
Even if the setting is changed in the first internal contact state, the first internal contact state can be maintained,
Giving rate of the predetermined privilege in the game with the second number of bets in the second bonus state<Give rate of predetermined privilege in the game with the second number of bets in the predetermined gaming state,
The grant rate of the predetermined bonus in the game with the second number of bets in the second bonus state<the rate of grant of the predetermined bonus in the game with the second number of bets in the second internal winning state,
When there is no stop display of the predetermined symbol combination related to the first specific hand in the game in which the first specific hand is won in the hand lottery in the first bet number game in the predetermined game state, the last The display mode of the display means becomes the first mode at a predetermined timing after the stop button that has been operated to stop is released,
When there is no stop display of the specific symbol combination related to the second specific combination in the game in which the second specific combination is won in the combination lottery in the second bet number game in the predetermined game state, the last The display mode of the display means becomes a second mode different from the first mode at a predetermined timing after the stop button that has been operated to stop is released,
A situation in which predetermined BGM is continued to be output after all the reels are stopped in a game in which a predetermined combination other than the second specific combination is won in the combination lottery in the second bet number game in the predetermined gaming state. below, when the second bet number game is executed, the output of the predetermined BGM can be terminated,
The output of the predetermined BGM is continued after all the reels are stopped in the game in which the predetermined combination other than the second specific combination is won in the combination lottery in the second bet amount game in the predetermined gaming state. When the game with the first number of bets is executed under the condition that the first number of bets is played, the output of the predetermined BGM is continued even during the game with the first number of bets.
It is a gaming machine characterized by

According to the present invention, it is possible to provide a gaming machine with more optimized functions.

1 is a perspective view of a slot machine according to one embodiment of the present invention; FIG. 1 is a perspective view of a slot machine with its front door section opened; FIG. It is a rear view of a front door part. It is a front view which shows the inside of a housing|casing part. (a) is a block diagram schematically showing the electrical configuration of each control board, and (b) is an explanatory diagram showing the outline of the component configuration in the main control board. It is a perspective view showing a game medal selector. It is a perspective view showing an open game medal selector. (a) is a chart showing the detection mode of the insertion sensors 1 and 2 when game medals are inserted normally, (b) is a chart showing other detection modes of the insertion sensors 1 and 2 that are not regarded as an error, and (c) is 4 is a timing chart showing how a C0 error is detected; (a) is a timing chart showing a C1 error detection mode, and (b) is a timing chart showing a CH error detection mode. 4 is a timing chart showing how a CE error is detected; FIG. 4 is an explanatory diagram showing a memory map related to a main CPU; 4 is a flow chart showing processing in the main control board when the power is turned on. It is a flowchart which shows the setting change apparatus processing in a main control board. It is a flowchart which shows the game progress main process in a main control board. 10 is a flow chart showing processing for starting an internal lottery. Fig. 10 is a flow chart illustrating the processing of a conditional device command set; 9 is a flowchart showing display determination processing; It is a flowchart which shows the timer interrupt processing in a main control board. It is a flowchart which shows the power-off process in a main control board. 4 is a flowchart showing error management processing; 4 is a flowchart showing power recovery processing; It is a flowchart which shows a game medal reception start process. (a) is a flowchart showing blocker ON processing, (b) is a flowchart showing blocker OFF processing. 9 is a flowchart showing error display processing; 4 is a flowchart showing input error set processing; It is a flow chart which shows game medal management processing. It is a flowchart which shows a storage injection|throwing-in process. It is a flow chart which shows game medal settlement processing. 10 is a flowchart showing unrecoverable error processing; FIG. 10 is a flow chart showing processing of RWM initialization 2 in the second control; FIG. FIG. 11 is a flow chart showing processing of RWM initialization 3 in the second control; FIG. 9 is a flowchart showing processing for serial communication setting in the second control; It is a flow chart showing processing of the symbol stop signal output in the second control. It is a flow chart showing the process of the pattern stop signal set in the second control. 9 is a flow chart showing test signal output processing in the second control. It is a flowchart which shows the process of the input/discharge sensor abnormality set in 2nd control. It is a flowchart which shows the process of input/withdrawal sensor abnormality clear in 2nd control. 9 is a flowchart showing error check processing in the second control; 10 is a flow chart showing a set value error check process in the second control; FIG. 11 is a flowchart showing internal random number check processing in the second control; FIG. 9 is a flowchart showing processing of timer measurement 2 in the second control; FIG. 11 is a flow chart showing a game medal insertion check process in the second control; FIG. FIG. 43 is a flow chart showing the process of checking the insertion of game medals following FIG. 42; FIG. FIG. 11 is a flow chart showing processing for updating the state of passage of game medals in the second control; FIG. It is a flowchart which shows the process of the input/discharge sensor abnormality check in 2nd control. FIG. 46 is a flow chart showing the process of checking the abnormality of the input/discharge sensor following FIG. 45; FIG. 10 is a flow chart showing processing for clearing error display request data in the second control; FIG. FIG. 11 is a flow chart showing processing of an 8-bit random number check in the second control; FIG. FIG. 10 is a flowchart showing unrecoverable error processing 2 in the second control; FIG. It is a flowchart which shows the input/discharge sensor abnormality display process in 1st control. (a) is a chart showing the pattern arrangement of each reel relating to a slot machine of a type having a specified number changing function, and (b) is a chart showing the symbols used. (a) is a chart showing the relationship between the condition device numbers 0 and 1 and the corresponding hands in the same slot machine, and (b) is a chart showing the relationship between the condition device numbers 2 to 4 and the corresponding hands in the same slot machine. be. It is a chart showing the relationship between the condition device numbers 5 and 6 and the corresponding hand. It is a diagram for It is a chart showing the relationship between the condition device numbers 7 to 9 and the corresponding hand. It is a diagram for It is a chart showing the relationship between condition device numbers 10 to 12 and corresponding hands. It is a figure for doing. It is a chart showing the relationship between the condition device numbers 2, 11, 12 and the corresponding hand. FIG. 11 is a chart showing numbers entered for each lottery target in a role lottery; FIG. (a) is a chart showing the number of entries and the number of payouts for each lottery target in the lottery during BBA and BBB, and (b) is an explanatory diagram showing the transition of the game state, taking BBB as an example. (a) is an explanatory diagram showing an example of an effect related to the ending screen, and (b) is an explanatory diagram showing an example of the effect of "non-internal". (a) is an explanatory diagram showing an example of an effect related to a menu screen, (b) is an explanatory diagram showing an example of a volume setting screen, and (c) is an explanatory diagram showing an example of a light amount setting screen.

<Overview of slot machine according to the present embodiment>

A slot machine according to an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows the appearance of a slot machine 10 according to this embodiment from the front. The slot machine 10 is configured by combining a front door section 11 shown in FIGS. 1 to 3 and a housing section 12 shown in FIG. The front door portion 11 is supported by the housing portion 12 via a hinge device, and can be locked in a closed state with respect to the housing portion 12 .

On the front side (front side) of the front door portion 11, as shown in FIG. 1, an operation portion 14 is arranged in the middle in the vertical direction, and a reel display portion 15 is arranged above the operation portion 14. . Furthermore, at the lower part of the front door portion 11, a game medal payout opening 16 having a rectangular opening and a receiving tray 17 for receiving the game medals discharged from the game medal payout opening 16 are arranged. A production unit 18 is arranged above the . Further, below the operation unit 14, a translucent lower panel 19 on which a model-specific name, a design image, and the like are drawn is provided.

Of these, the operating portion 14 is provided with a game medal slot 21, a game medal return button 22, a lock portion 23 (also referred to as a lock portion), a stop button portion (stop button portion) 24, a start lever 25, and the like. . Further, a main input section 26 and a sub-input section 27 are provided on the upper portion of the operation section 14. The main input section 26 includes a checkout button 74, a 1-bet button (so-called 1BET button) 75, and a 3-bet button. A button (so-called MAXBET button) 76 is provided. Further, the sub-input unit 27 is provided with a cross key 77, a sub-input switch 78, and the like.

The game medal slot 21 is for inserting game medals as game media via a guide, and the game medal return button 22 is for returning game medals retained in a game medal selector (to be described later). is used for The lock portion 23 is used by inserting a predetermined key when unlocking the front door portion 11, and the stop button portion 24 is used for three drums (first drum 51L, It is used to stop the rotation of the second drum 51C and the third drum 51R).

The stop button section 24 is provided with three stop buttons (a first stop button 24L, a second stop button 24C, and a third stop button 24R, which are three stop buttons). These stop buttons 24L, 24C, 24R are associated with the respective spinning drums 51L, 51C, 51R. By individually pressing the stop buttons 24L, 24C, 24R, the corresponding spinning drums 51L, 51C, 51R are activated. is set to stop. In the present embodiment, the first to third drums 51L to 51R are arranged from the left when viewed from the front of the slot machine 10: the first drum 51L, the second drum 51C, and the third drum 51R. The stop buttons 24L, 24C, and 24R are also arranged in the order of the first stop button 24L, the second stop button 24C, and the third stop button 24R from the left. The start lever 25 is also used when rotating the drum and determining set values (to be described later).

A settlement button 74 on the main input section 26 is used to pay out inserted game medals and to settle game medals stored in a storage device (to be described later). The 1-insert button 75 is used to insert the stored game medals one by one, and the 3-insert button 76 is used to set the number of stored game medals and a prescribed number (to be described later) related to the insertion. It is used when inserting a maximum of 3 stored game medals within a range not exceeding. The sub-input switch 78 in the sub-input unit 27 is for performing operations related to production, and is used for switching display contents such as a liquid crystal screen provided in the production unit 18 and for input related to production. .

Further, although not shown, the operation unit 14 is provided with various display units that indicate the content of the game by the presence or absence of LED light emission, the display mode of a 7-segment (7-segment) display, and the like. The various display sections that indicate the game status include an acquired number display section, a stored number display section, a replay display section, an input display section, a stop display section, a game start display section, and an inserted number display section. Characters are printed in the vicinity of these various display units so that the information display function of each display unit can be understood. Furthermore, among these display units, the acquired number display unit and the stored number display unit have the function of displaying numbers and characters using a 7-segment display, and the other display units are LED lighting. Predetermined information is displayed depending on the presence or absence of the light and the mode of lighting. Regarding the LEDs used as light sources in the respective display units, the obtained number display LED, the stored number display LED, the replay display LED, the input display LED, the stop display LED, the game start display LED, and the input number display are described below. They are sometimes called LEDs.

In addition, among the various display units, the acquired number display unit can be used to display the number of game medals according to the number of acquired game medals, display when switching settings, or display an error code, depending on the situation. Used. The stored number display section displays the number of game medals stored in the storage device, and the replay display section displays whether or not replay is activated. Further, the insertion display section displays that the insertion of game medals can be accepted, and the stop display section displays that it is time to settle the accumulated game medals. The game start display section displays that the operation of the start lever 25 can be accepted in a state where the game can be started. Further, the inserted number display section displays the number of inserted game medals, and displays the same number of game medals as in the previous game at the time of replay operation.

The aforementioned stop button section 24 is provided with three stop buttons, ie, a first stop button 24L, a second stop button 24C, and a third stop button 24R. In addition, the drum display unit 15 is provided with a drum display panel 28 in which a display window having a rectangular opening is closed with a transparent panel. 3, three reels (reels) of the first to third reels 51L to 51R housed in the casing 12 can be visually recognized. In addition, the effect section 18 is provided with a liquid crystal display device or the like, and the effect part 18 displays effects associated with the game. Here, in this embodiment, the reel display panel 28 also has the function of a display device, and is capable of displaying various types of moving images in the same manner as the effect section 18 . It should be noted that, without being limited to this, for example, it is also possible to form the effect section 18 and the reel display panel 28 as one effect display device having a continuous screen.

Further, the front door portion 11 is provided with various light sources (LEDs) used for presentation. Although not shown in the drawings, the light sources for these effects include a 3-insert display LED, a stop button LED, a sub-input display LED, and the like. Of these, the 3-insert display LED illuminates the 3-insert button 76 arranged in the main input section 26 from the inside, and is used to display the effects using the 3-insert button 76. . Also, the stop button LEDs illuminate the stop buttons 24L, 24C, and 24R from the inside, and are used to display the effect content using the stop buttons 24L, 24C, and 24R. Furthermore, the sub-input display LED illuminates the sub-input switch 78 arranged in the above-described sub-input unit 27 from the inside, and is used to display the effect content using the sub-input switch 78 .

In addition to these, as light sources for production, although not shown, the upper reel LED, the lower reel LED, the side LED, the chance LED, the left wing LED, the lower left circle LED, the right wing LED, and the lower right circle There are LED, upper left circle LED, upper LED, upper right circle LED, AR lamp LED, lower panel illumination LED, left mini LED, right mini LED, V-shaped LED and so on. Any of the light sources is used for displaying the effect content depending on its arrangement and function.

FIG. 3 shows the rear side of the front door section 11 . On the rear side of the front door portion 11, various substrates, equipment for handling game medals, various sensors, and the like are arranged. Among these, various boards include a sub-control board 31, an image control board 32, an image display connection board 33, an audio board 34, an effect ROM (ROM) board 35, a switch sensor board 36, a display board 37, and a door relay terminal board. 38, a reel illumination board 39, a lower panel illumination board 40, and the like are provided.

Among these, the sub-control board 31 is a board for controlling images for presentation, various solenoids, various LEDs, and sound effects. The sub-control board 31 is housed in a dedicated board case and attached to the front door section 11 by screwing the board case to the front door section 11 .

The image control board 32 mounts an audio board 34 and an effect ROM board 35, which will be described later, relays between the sub control board 31 and the image display connection board 33, and is a board for controlling images for effects and sound effects. is. The image control board 32 is housed in a dedicated board case and attached to the front door section 11 by screwing the board case to the front door section 11 .

The image display connection board 33 is a board that relays between the image control board 32 and the liquid crystal display device of the rendering section 18, and is fixed by screwing into a screw hole provided in the front door section 11. . The audio board 34 is a board on which a ROM storing sound data for presentation is attached, and is fixed by screwing into a screw hole provided in the image control board 32 . The production ROM board 35 is a board on which a ROM storing image data for production is attached, and is fixed by screwing into a screw hole provided in the image control board 32 . Incidentally, various ROMs may be fixed by inserting pins provided on the ROMs into sockets provided on the board on which the ROMs are mounted. Furthermore, various boards may be fixed not only by screwing, but also by fitting a connector provided on each board with a connector provided on a mating door, case, board, or the like. Such a substrate fixing method can be similarly adopted for various substrates described below. Also, the image control connection board does not necessarily need to be provided, and the image control board 32 may be directly connected to the rendering section 18 and mounted.

The switch sensor board 36 relays between the sub-control board 31 and two solenoids (a first solenoid and a second solenoid), which will be described later, to display the contents of the effect by the LED, or to switch and input the liquid crystal screen. is the substrate of The switch sensor board 36 is fixed by screwing into a screw hole provided in the dedicated board case.

The display board 37 is a board on which the obtained number display LED, the accumulated number display LED, the replay display LED, the input display LED, the stop display LED, the game start display LED, and the input number display LED are mounted. It is fixed by being fitted into a hook provided at 11 . The door relay terminal board 38 is a board that relays between a main control board (to be described later), various sensors and blockers 47 (to be described later) and the display board 37 arranged at various locations on the front door section 11 . . The door relay terminal plate 38 is mounted on the front door portion 11 by housing it in a dedicated substrate case and screwing the substrate case to the front door portion 11.

The drum lighting board 39 is a board on which LEDs are attached for illuminating the first drum 51L to the third drum 51R, and is fixed by being fitted into a hook provided on the front door section 11. As shown in FIG. The lower panel illumination board 40 is a board with an upper and lower two-part structure to which an LED for illuminating the lower panel 19 is attached. The lower panel lighting board 40 is a board on which LEDs are attached to illuminate the lower panel, and is fixed by being fitted into hooks provided on the front door section 11 .

Next, devices such as various sensors provided on the front door portion 11 include a start lever sensor 41, a 3-card insertion button sensor 42, a 1-card insertion/settlement button switch 43, a game medal selector 44, an insertion sensor 45, and a selector. There are a path sensor 46, a blocker 47, a game medal return path 48, a stop button sensor 49, a speaker 50, and the like. Among them, the start lever sensor 41 is for detecting the operation of the start lever 25, and the 3-sheet insert button sensor 42 is for detecting the operation of the 3-sheet insert button 76. FIG.

Also, the one-sheet insertion/settlement button switch 43 is a device equipped with a one-sheet insertion button and a settlement button switch. The game medal selector 44 is a device equipped with an insertion sensor 45, a selector passage sensor 46 and a blocker 47, which will be described later, and is also a device for selecting whether or not the inserted game medals are within the receivable range. The insertion sensor 45 described above is a sensor for detecting insertion of game medals, and the selector path sensor 46 is a sensor for detecting passage of game medals. Furthermore, the blocker 47 is a device for returning game medals according to the game state, and the game medal return path 48 is a path for returning the game medals. A stop button sensor 49 is a sensor for detecting the operation of the stop buttons 24L to 24R, and a plurality of speakers 50 are provided for outputting sound effects.

Although not shown, the front door portion 11 is provided with a solenoid 1, a solenoid 2, and a cross key board. Of these, solenoid 1 and solenoid 2 are devices for vibrating the sub-input switch 78 . Also, the cross key board is a board for switching the liquid crystal screen and inputting, and is housed in a dedicated board case and fixed by screwing the dedicated case.

FIG. 4 shows the front side of the housing section 12 . A main control board 61, a setting unit 62, a game medal payout device (hopper) 63, a power supply unit 64, and the like are arranged in the housing portion 12. As shown in FIG. Of these, the main control board 61 controls the input/output to and from the slot machine 10 to control the game, and has a stop switch, a setting display LED, a monitor LED, etc., which will be described later, although the reference numerals are omitted. is the substrate. The main control board 61 is housed in a main board case 65 which is a dedicated board case, and the main board case 65 is fixed with a dedicated fastener and attached to the housing 12 . The setting display LED 66 displays a set value that defines the theoretical likelihood of winning (the degree of advantage for the player). The stop switch is set to either the upper side or the lower side to select either the stop function or the automatic settlement function. This kill switch is not used. Therefore, the stop switch does not affect the result of the game. An IC tag sealing sticker (not shown) is attached to the main substrate case 65, and the IC tag sealing sticker is a sealing paper having an IC tag embedded therein.

Further, a door switch 60 is provided in the housing portion 12 , and the door switch 60 is a switch for detecting opening/closing of the front door portion 11 . The setting unit 62 is a box containing a setting door switch 67, a setting key switch 68, and a setting/reset button 69 ("/" means "or"), which will be described later. Among these, the setting door switch 67 is a switch for detecting opening/closing of a setting door that constitutes a part of the housing of the setting unit 62 and closes the setting unit 62 . The setting key switch 68 is a switch for switching and confirming settings in the slot machine, and the setting/reset button 69 is a button for selecting the setting value or canceling an error. It should be noted that the setting door switch 67 does not necessarily have to be provided. Also, in this embodiment, the setting/reset button 69 serving as both a setting button and a reset button is used, but they may be provided separately. Furthermore, the lock portion 23 is provided with a setting and resetting function. It may function as a setting/reset switch. Either one of the setting key switch 68 and the setting/reset button 69 shown in FIG. 4 may be provided separately from the setting unit 62 . For example, a setting key cylinder (not shown) having a setting key switch 68 is provided on the power supply unit 64, and a setting/reset button 69 is provided on the setting unit 62, for example.

Furthermore, an external collective terminal plate 70 is provided in the housing part 12, and this external collective terminal plate 70 outputs medal insertion signal output, medal payout signal output, external signal output 1 to external signal output 5 to the outside. It is a board on which monitor LEDs (7 pieces) are attached while outputting. The external collective terminal plate 70 is fixed to the housing portion 12 by being fitted into hooks provided on the housing portion 12 .

The aforementioned game medal payout device 63 is provided with a payout sensor (not shown; sometimes referred to as a "payout sensor"), and this payout sensor is a sensor for detecting the paid out game medals. is.

Furthermore, the housing part 12 is provided with a game medal auxiliary storage box 71, and this game medal auxiliary storage box 71 is a storage box for storing game medals exceeding the storage capacity of the game medal payout device 63. is. The game medal auxiliary storage box 71 is provided with a full detection electrode (not shown), and this full detection electrode is an electrode for detecting the full state of the game medal auxiliary storage box.

The aforementioned power supply unit 64 is a box containing a power switch 72, and the power switch 72 is a switch for turning ON/OFF the main power. By turning the power switch 72 from OFF to ON, predetermined power is supplied to various devices including the control board and the like via the power supply unit 64 .

Further, the housing portion 12 is provided with the above-described first to third drums 51L to 51R. The drums 51L to 51R are devices for rotating the pattern drawn on the outer peripheral surface. A spinning drum sensor (not shown) is provided inside each of the spinning drums 51L to 51R. This part is sometimes called an "index").

Further, although not shown, the housing 12 is provided with a BL (backlight) relay board, a drum device board, a backlight LED, an LED backlight board, and the like. Among these, the BL relay board is a board that relays between the sub-control board 31 and an LED backlight board, a reel sensor, and the like, which will be described later. The BL relay board is attached to the housing 12 by housing the board in a dedicated board case and fixing the board case with a dedicated fastener.

Further, the rotary drum device board is a board that relays between the main control board 61, a rotary drum stepping motor (to be described later), and a rotary drum sensor in order to rotate or stop the rotary drums 51L to 51R. It is also a board that relays between the main control board 61 and the above-mentioned full detection electrode, door switch 60, game medal payout device 63, external centralized terminal board 70, and power supply unit 64. This spinning drum device board is mounted on the housing part 12 by housing the board in a dedicated board case and fixing the board case with a dedicated fastener. The backlight LED is an LED arranged inside each of the drums 51L to 51R for illuminating the pattern on the drums 51L to 51R from behind. The LED backlight substrate is a substrate on which the backlight LEDs described above are mounted.
<Electrical basic configuration of various control boards>

Next, the basic electrical configuration of the main control board 61, the sub-control board 31, and the image control board 32 will be described. As shown in FIG. 5(a), the main control board 61 stores a main CPU 81 that controls the progress of the game, a program (game control program) used for game control of the main CPU 81, and various data. Various electronic components such as a main ROM 82, a readable/writable RWM 83 for temporarily storing data for controlling the progress of the game, and an interface section (not shown) are provided. In this embodiment, the game control program is roughly divided into two control programs, a first control program and a second control program. Control executed based on the first control program can be called first control, and control executed based on the second control program can be called second control. It is also possible to call the first control "control used for games" and the second control "control not used for games", but the details of these will be described later.

In addition, the sub-control board 31 stores a sub-main CPU 86 that performs control for effects based on commands from the main control board 61, programs (effect control programs) used for effect control of the sub-main CPU 86, and various data. Various electronic components such as a sub-main ROM 87, a readable and writable RWM 88 that temporarily stores data for effect control, and an interface section (not shown) are provided. The sub-control board 31 receives a command (main command) transmitted from the main control board 61 and performs control based on this main command. The sub-control board 31 then transmits commands (sub-main commands) for image display and voice (sound) output to the image control board 32 .

The image control board 32 includes a sub-sub CPU 91 that performs image control based on sub-main commands from the sub-control board 31, a program (image control program) used for image control of the sub-sub CPU 91, and an effect ROM 92 that stores various data. Based on commands from the sub-sub CPU 91, a VDP 94 that controls image display using image data stored in the character ROM 93, an audio chip 96 that controls audio output using audio data stored in the audio ROM 95, image display and audio Various electronic components such as a readable and writable RWM 97 for temporarily storing data for output and an interface unit (not shown) are provided. Here, the effect ROM 92 is mounted on the effect ROM board 35 described above, and the voice ROM 95 is mounted on the voice board 34 described above. However, the present invention is not limited to this mode, and the sub-control board 31 may supplement some or all of the functions of the image control board 32 . For example, the sub-control board 31 may be provided with an audio ROM 95 to perform selection and output control of audio data without going through the image control board 32 , or the sub-control board 31 may be provided with a character ROM 93 and VDP 94 . More specific operations of the main control board 61, the sub-control board 31, and the image control board 32 will be described later.
<<Component configuration related to main control board>>

Next, an overview of the component configuration of the main control board 61 will be described. The main control board 61 is a rectangular plate-shaped wiring board having printed wiring, and in this embodiment, a multi-layer (here, two-layer) structure is used. Furthermore, through holes for mounting lead-type electronic components are provided at predetermined portions of the main control board 61, and flow soldering or the like can be performed with the leads inserted into the through holes. Then, lead-type electronic equipment is mounted on the main control board 61 . Moreover, not only lead type electronic components but also surface mount type electronic components can be mounted on the main control board 61 .

FIG. 5(b) schematically shows the mounting surface, which is the surface side of the main control board 61. As shown in FIG. The main control board 61 is mounted with a main CPU 81 that is a lead-type packaged device. The mounting of the main CPU 81 is performed by inserting and fitting the leads of the main CPU 81 into lead-type sockets soldered to the main control board 61 . Furthermore, various electronic components 181 and various connectors 182 are soldered onto the main control board 61 as shown in the figure.

Among them, the various connectors 182 are arranged along the periphery (outer edge) of the main control board 61, and the connection ports are exposed to the outside from the main board case 65 described above. Connectors provided on harnesses from boards related to external devices such as the above-described sub-control board 31, reel device board, various LED boards, etc. are fitted to the various connectors 182, and the main control board 61 and the main control board 61 are connected. , for electrical connection with various external devices.

Reference numeral 183 in FIG. 5B denotes a non-mounting area where no connector is provided. This non-mounting area 183 is an area reserved for mounting an emergency connector for connection to a test machine at the stage of product development. This is the area where the permanent connector has been removed for the transition. In the non-mounting area 183, the board surface of the main control board 61 is exposed, and it is possible to see a plurality of through holes 184 for inserting the leads of the emergency connector. In addition, since the mounting position of the emergency connector is the periphery of the main control board 61 as described above, the non-mounting area 183 is also located in the board periphery outside the main CPU 81 . In addition, in FIG. 5B, only a part of the through holes of the emergency connector are shown in order to avoid complication of the drawing.

The emergency connector is used to connect the main control board 61 to a performance tester (not shown) that is used in the development stage, especially in the official approval stage. More specifically, a test relay board (not shown) is connected to the emergency connector, and a performance tester is connected to this test relay board. The test data signal extracted via the test relay board is input to the performance tester, and the performance tester determines the performance data of the slot machine 10 based on the input test data signal. get.

The test relay board is not used at the stage of commercialization, and is not provided in the commercialized slot machine 10 . A test drive circuit (test driver) is used to output the test data signal, and this test driver is mounted on the test relay board. The main control board 61 is not provided with an area for mounting a driver. Furthermore, the shape, dimensions, number of pins, and color of the emergency connector are different from any of the other various connectors 182, and are structurally different from the mating connector connected to the other connector. Connection is not possible.

On the other hand, since the performance tester is not connected at the stage of commercialization, no emergency connector is mounted when the main control board 61 is manufactured. However, if the printed wiring of the main control board 61 and the game machine control program were changed in accordance with the fact that the emergency connector was not installed, the difference between the commercialized slot machine 10 and the slot machine at the time of testing would not be possible. Conditions cannot be matched. In addition, if the slot machine 10, which has been commercialized, still has an emergency connector so as not to change the conditions, a connector that can be mated with the emergency connector is used in the device for fraud, making fraud easier. It is also conceivable that it will become

For this reason, the emergency connector has been removed to prevent tampering, and in order to minimize changes in conditions, the printed wiring for the emergency connector is left in the same form as when the emergency connector is installed. . Moreover, solder is supplied to the through hole 184 for the emergency connector, and the through hole 184 for the emergency connector is closed with the solder over its entire length. By plugging the through holes 184 with solder, it is possible to prevent illegal acts such as using the through holes 184 . In addition, the solder can be used to connect the wiring for the emergency connector to other wiring (for example, wiring for grounding).

Furthermore, during soldering, it is conceivable that the surface tension of molten solder causes the solidified solder to protrude to some extent (for example, about 0.1 mm) from the surface of the substrate. However, as described above, no emergency connector is mounted during commercialization, so the raised solder does not come into contact with the emergency connector or other electronic components. Although it is possible to plug through holes 184 with a material other than solder (for example, solder resist), solder for plugging through holes 184 is not necessary in this case. It is also possible to leave the through hole 184 open without blocking it. In this case, no material is required to block the through hole 184 .

Although not shown, the main circuit board case 65 is composed of a box base made of transparent resin and having a substantially rectangular parallelepiped shape, and a box cover made of transparent resin and covering the opening of the box base. It is Holes for exposing the permanent connectors 182 are provided in the box cover at positions corresponding to mounting areas of various permanent connectors 182 that are used even after commercialization, but no emergency connectors are mounted. At a position corresponding to the area 183, no hole for exposing the emergency connector is left, and the non-mounting area 183 is enclosed.
<Mechanism for rotation of drum>

Next, a mechanism for rotating the first to third drums 51L to 51R will be described. A reel tape is attached to the outer peripheral surface of each of the drums 51L to 51R, and a predetermined number of patterns are drawn on the reel tape. In this embodiment, the number of symbols is 21 for each. All the drums have the same size, and the axes of rotation are positioned on the same straight line. Further, each of the drums 51L to 51R is connected to and integrated with the drum rotating device 54 shown in FIG. It is rotationally driven while facing in the left-right direction. Here, the arrangement of the symbols on the first drum 51L to the third drum 51R and the control mode related to the display of the symbols will be described later. The number of symbols is not limited to 21, and may be, for example, 20 or 14.

The drum rotation device 54 is a device for rotating the first drum 51L to the third drum 51R, and is operated by operating the start lever 25 to rotate the first drum 51L to the third drum 51R. It has the ability to rotate.

Although not shown, the drum rotating device 54 is composed of a drum stepping motor, a reel bushing, a drum sensor, a drum device board, and the like, and includes a first control program and a second control program, as will be described later. It is controlled by a computer program (game control program). Each of the first to third drums 51L to 51R is recessed and recessed into the stainless steel shaft of the stepping motor via a cylindrical reel bushing, and is attached to the stepping motor via a screw and a resin washer. is fixed to the axis of The shaft of the stepping motor is used as the shaft of the first to third drums 51L to 51R. Since the motor frame is inserted into the reel frame made of metal or the like that is the skeleton of the reel frame and fixed by a latch (here, a so-called snap latch equipped with a plunger and a grommet), even if the reel rotation device 54 is operated , the first to third drums 51L to 51R do not sway (they do not swing in the rotational direction or the axial direction).

When stopping the first to third drums 51L to 51R, the drum rotating device 54 functions as a rotation stopping device. That is, the rotation stopping device has a function of stopping the spinning drum and a function of displaying the combination of symbols. Among these functions, the function of stopping the spinning drum is a function of stopping the spinning drum corresponding to the pressed stop button when each of the stop buttons 24L, 24C, and 24R is pressed. In addition, the function of displaying the combination of symbols is to stop all the three drums 51L to 51R by the function to stop the drums described above. It is a function to display a combination of symbols by .

Furthermore, the rotation stopping device is composed of stop buttons 24L, 24C, 24R, stop button sensors, door relay terminal plates, spinning drum stepping motors, spinning drum sensors, and spinning drum device substrates. It operates when the player operates the stop button, and does not operate otherwise. Here, each of the drums 51L to 51R is formed with an index that serves as an index of the rotation angle. The position of the pattern when the rotation is stopped is controlled.
<Control of Mechanism Related to Spindle Rotation>

Each of the drums 51L to 51R has various data described below, that is, a drum drive state number, a drum drive pulse output counter, the number of times the drum drive pulse is switched during acceleration, a step number of one pattern, a pattern number (passing position), pattern number (for stop position), reel rotation failure detection counter, reel drive pulse data search counter, reel rotation start standby counter, and the like. The drive state of each drum is checked by the drum drive management module at each interrupt (2.235 ms), and excitation data is output according to the conditions.

Among the various data described above, the reel drive state number has values from 0 to 5, where 0 is stopped or shaking, 1 is waiting to start rotation, 2 is decelerating, 3 is starting deceleration, 4 indicates that the vehicle is at constant speed, and 5 indicates that it is accelerating. In addition, the drum drive pulse output counter represents the number of interrupts to switch the excitation, and the number of times of switching the drum drive pulse during acceleration represents the offset of the drum rising pattern (interruption count) table, and 1 pattern represents the number of steps for one symbol.

Furthermore, the symbol number (for passing position) represents the symbol number (0 to 20) passing through the middle stage, and if the value is FFH (H represents hexadecimal notation), This indicates that the drum sensor has not passed. The symbol number (for stop position) represents the symbol number (0 to 20) to be displayed in the middle stage, and if the value is FFH, it means that the symbol number has not been set. The drum rotation failure detection counter is a counter for detecting rotation failure of the drum, and outputs a value equal to the number of steps after passing through the sensor/2. Further, when each of the drums 51L to 51R passes the drum sensor, the driving state number of the drum becomes "4" indicating "constant speed".
<Game Medal Selector>
<<Configuration of Game Medal Selector>>

Next, the aforementioned game medal selector 44 will be described. As shown in FIGS. 2 and 3, the game medal selector 44 is located on the back side of the front door portion 11, on the open end side of the front door portion 11 (the left end side in FIGS. 2 and 3), and It is attached to a portion approximately in the middle in the vertical direction. Furthermore, the game medal selector 44 is positioned immediately below the spinning drum display portion 15, and the game medal selector 44 inserted (so-called maintenance) into the game medal slot 21 (see FIG. 1) on the front surface of the front door portion 11 Medals are received behind the front door part 11. - 特許庁

The game medal selector 44 has a rectangular box-like outer shape as shown in FIG. Among them, the body portion 101 is fixed to the front door portion 11, and as shown in FIG. Further, the hinge mechanism portion 103 is arranged on the right side of the front door portion 11 when viewed from the rear side, and the opening/closing portion 102 is arranged on the hinge mechanism portion 103 centering on the axis of the hinge mechanism portion 103 extending in the vertical direction. It can be opened in the horizontal direction while resisting the elastic restoring force of the provided coil spring 104 and the like.

When the opening/closing part 102 is closed, a medal passage 105 having a width slightly larger than the thickness of one game medal is formed between the main part 101 and the opening/closing part 102 . That is, the medal passage 105 opens upward in a slit shape, bends and branches in the middle, and extends to the side of the game medal selector 44 (the right side when viewed from the back of the front door portion 11) and downward. is growing. The upper end of the medal passage 105 serves as an entrance (game medal entrance) 106 for game medals, and the opening serving as the game medal entrance 106 communicates with the game medal slot 21 described above. A side exit (hereinafter referred to as a "first exit") 107 of the game medal selector 44 can discharge game medals toward the above-described game medal payout device 63, and a lower exit (hereinafter referred to as a "first exit"). ) 108 can discharge game medals toward the aforementioned game medal payout opening 16 .

Further, at a bent portion 110 positioned in the middle of the medal passage 105, a deceleration portion 111 in the form of a deformed plate is provided as shown in FIG. The deceleration part 111 is rotatable in the front-rear direction (the front-rear direction of the front door part 11) with its upper end as the base end, and elastically protrudes into the medal passage 105 when no game medals pass through. ing. A game medal is inserted into the game medal slot 21, and when the inserted game medal comes into contact with the decelerating portion 111 while passing through the bent portion 110, the decelerating portion 111 is pushed by the game medal and plunges into the main body portion 101. do. Further, the deceleration part 111 protrudes into the medal passage 105 again when the game medal passes and the pressing force of the game medal is released. Then, the game medals passing through the curved portion 110 change course while being decelerated by contact with the decelerating portion 111 and head toward the downstream side of the curved portion 110 .

The selector passage sensor 46 described above is provided on the downstream side of the bent portion 110 . The selector passage sensor 46 has a rectangular plate-like first movable portion 112. The first movable portion 112 extends along the longitudinal direction of the medal passage 105 in the width direction (passing through) to the branch portion 113 of the medal passage 105. It is arranged in a state facing the radial direction of the game medals to be played). The first movable portion 112 is rotatable in the front-rear direction (the front-rear direction of the front door portion 11) with one side on the upstream side of the medal passage 105 as a base end. 105 protruding. However, when a game medal that has passed through the decelerating portion 111 contacts the first movable portion 112 , the first movable portion 112 is pushed by the game medal and sinks into the main body portion 101 . Then, the first movable portion 112 protrudes into the medal passage 105 again when the game medal passes and the pressing force is released.

A microsensor (not shown) for the selector path sensor 46 is built in the main body 101, and the microsensor detects whether or not the first movable part 112 is retracted. That is, when the first movable portion 112 is pushed by the game medals that enter the medal passage 105 and flow down, the movement of the first movable portion 112 is detected, and the output signal of the microsensor changes. do. In the main control board 61 described above, the output from the microsensor for the selector path sensor is used to execute control (FIGS. 22 to 29, etc.) relating to the insertion of game medals, as will be described later. be. Here, as the microsensor for the selector path sensor 46, various microsensors such as contact type and non-contact type can be applied. In addition, the first movable portion 112 is configured so that a reverse flow of foreign matter or the like is caught (the foreign matter cannot move from the downstream side to the upstream side of the first movable portion 112). As a result, it is also possible to prevent the goto machine (machine tool used for so-called goto action) from being easily pulled out when it is inserted.

A second movable portion 114 is provided on the upstream side of the first movable portion 112. This second movable portion 114 also normally projects elastically into the medal passage 105 and is pushed by the game medals. In this case, it is designed to be immersed in the body portion 101 . In this embodiment, the selector passage sensor 46 is composed of movable portions such as the first movable portion 112 and the second movable portion 114 and a detection portion such as a microsensor for the selector passage sensor 46 . In this embodiment, the selector passage sensor 46 is formed by the first movable portion 112 and the second movable portion 114, but is not limited to this. It may be good, and it does not have to be a shape like the above.

The insertion sensor 45 is provided at a portion of the medal passage 105 on the way from the selector passage sensor 46 to the first exit 107 . The input sensor 45 is composed of two sensors, an input sensor 1 indicated by reference numeral 115 and an input sensor 2 indicated by reference numeral 116 . In addition, below, when the code|symbol in a figure is attached|subjected and demonstrated to the input sensor 1 and the input sensor 2, it describes like the input sensor 1 (115) and the input sensor 2 (116).

The input sensor 1 ( 115 ) and the input sensor 2 ( 116 ) both use non-contact microsensors (not shown) built in the main body 101 . Further, the inserted sensor 1 (115) and the inserted sensor 2 (116) are arranged at a predetermined distance (for example, about 5 to 10 mm) smaller than the diameter of the game medal (here, 25 mm) with respect to the flowing direction of the game medal. Of these, the insertion sensor 1 (115) is located upstream of the medal passage 105 from the insertion sensor 2 (116).

Also, as the microsensors used for the input sensor 1 (115) and the input sensor 2 (116), light receiving type microsensors are used. Light (detection light) emitted from 118 can be received. In other words, a light emitting device (not shown) using an LED or the like is built in the light projecting unit 118, and the positional relationship between this light emitting device and the input sensor 1 (115) and the input sensor 2 (116) is as follows. The detection light output from the light emitter is set to pass through the window portion 117 and enter the input sensor 1 (115) and the input sensor 2 (116).

When the game medal flowing down the medal passage 105 blocks the detection light, the detection light stops entering the insertion sensor 1 (115) and the insertion sensor 2 (116), the game medal is detected, and the insertion sensor 1 ( 115) and the output signals of the microsensors used for the input sensor 2 (116) change. In the main control board 61 described above, the outputs from the insertion sensor 1 (115) and the insertion sensor 2 (116) are used to control the insertion of game medals (Fig. 22 to Fig. 22). 29) are executed.

In addition, in this embodiment, the insertion sensor 1 (115) and the insertion sensor 2 (116) are arranged in the upper part of the medal passage 105, for example, even if a plurality of game medals pass continuously, , the upper gap between the game medals passes through the input sensor 1 (115) and the input sensor 2 (116). Thus, game medals can be reliably detected one by one.

Further, as shown in FIG. 7, the opening/closing portion 102 is provided with the aforementioned blocker 47 . The blocker 47 is composed of a plate-like movable block portion 119 having an L-shaped cross section, a solenoid (not shown), and the like. It is Furthermore, the arrangement of the blocker 47 is such that when the opening/closing portion 102 is closed, most of the movable block portion 119 is directed toward the first outlet 107 rather than immediately below the first movable portion 112 in the selector passage sensor 46. It is set to be positioned downstream with respect to the game medals. The blocker 47 advances and retreats the movable block portion 119 in the front-rear direction (the front-rear direction of the front door portion 11) in accordance with ON/OFF driving of a solenoid (not shown).

In this embodiment, when the solenoid is turned off, the blocker is turned off. When the blocker is turned off, the movable block portion 119 is retracted into the opening/closing portion 102, and the shielding plate portion 120 is pulled into the opening/closing portion 102. is in good condition. When the blocker is OFF, the lower second exit 108 is open, and the game medals do not go to the first exit 107, but fall to the side of the second exit 108 and are guided to the second exit 108, It is returned to the tray 17.

On the other hand, when the solenoid is ON, the blocker is ON. When the blocker is ON, the movable block portion 119 moves forward toward the main body portion 101 as shown in FIG. 105 is in a protruded state. When the blocker is ON, the second outlet 108 on the lower side is blocked by the shielding plate portion 120, and is led to the side of the first outlet 107 along the shielding plate portion 120. FIG. Then, the game medals pass through the selector path sensor 46 and the insertion sensor 45 toward the first exit 107 and are ejected from the first exit 107 toward the game medal payout port 16 .

Here, reference numeral 121 in FIG. 7 denotes a reject switch that is provided in the body portion 101 and constitutes a reject mechanism, and reference numeral 122 denotes a reject switch that faces the reject switch 121 when the opening/closing portion 102 is closed. It is a receiving part for rejection arranged like this. The function of the reject switch 121 will be described later.
<< Function of game medal selector >>

Next, the function of the game medal selector 44 will be explained. The game medal selector 44 has a game medal selection function, a game medal reception prohibition function, and a game medal detection function. Among these functions, the game medal sorting function is a function for sorting out whether or not the inserted game medals are within the acceptable size range. Also, the game medal reception disapproval function is a function of returning the game medals without accepting them by the blocker 47 according to the game state, and the game medal detection function detects the game medals that have passed through the insertion sensor 45 described above. It is a function to

Regarding the above-mentioned game medal reception disabling function, as a game state in which game medals are returned without being accepted, 50 game medals are stored in the storage device (described later), and a specified number of game medals (described later) is inserted, during the period from acceptance of operation of the start lever 25 after inserting the specified number of game medals to completion of the game at that time, the number of inserted game medals and accumulated game medals Examples include refund, error occurrence, setting switching, and setting confirmation.

When game medals within the acceptable game medal size range are inserted from the game medal slot 21, they pass through the game medal entrance 106 of the game medal selector 44, pass through the medal passage 105, and reach the game medal exit (first exit 107). ) to the game medal payout device 63 . When game medals pass through the selector path sensor 46 and the insertion sensor 45 , detection signals are sent from the sensors 45 and 46 to the main control board 61 . The detection signal of the selector path sensor 46 is used for confirming the number of game medals that have passed through the selector path sensor 46 in the aforementioned game control program.

The detection signal of the insertion sensor 45 is used to determine the time and order in which the game medals pass through the selector path sensor 46 in the aforementioned game control program. If the detection signals from the selector path sensor 46 and insertion sensor 45 are within the specified time and within the specified order and the specified number of medals, it means that the game medals have been detected normally. If the time is longer than the specified time, or the order and the number of tokens are not specified, an error occurs, and the inserted game medals are invalidated. However, if the detection signal is only the output signal of the input sensor 1 (input sensor 1 signal) and there is no detection by the detection signal of the input sensor 2 (input sensor 2 signal), no error occurs.

Here, as a case where only the input sensor 1 signal is detected and the input sensor 2 signal is not detected, the case where the game medal returns from the input sensor 1 in the opposite direction can be mentioned. Further, a specific aspect of such game medal detection will be described later.

When the deformed game medal is inserted from the game medal slot 21, it stays at the game medal inlet 106.例文帳に追加By operating the game medal return button 22 (see FIG. 1), the above-described reject switch 121 is pushed, and the opening/closing portion 102 of the game medal selector 44 is slightly opened, and the accumulated game medals are released from the game medal payout port 16. It is returned to the tray 17. When game medals smaller than the size of game medals that can be accepted are inserted from the game medal insertion port 21, they pass through the game medal entrance 106 and are returned to the receiving tray 17 from the game medal payout port 16.例文帳に追加

In addition, the above-mentioned blocker 47 is turned off according to the game state by the above-mentioned game medal reception disabling function, and the movable block portion 119 retreats from the medal passage 105 . At that time, when the game medals within the acceptable range are inserted from the game medal slot 21, they pass through the game medal entrance 106, reach the bent portion 110 of the medal passage 105, and further drop freely. , the second exit 108, and is returned to the receiving tray 17 from the game medal payout opening 16.例文帳に追加
<Procedure for changing settings>

In the slot machine 10 of this embodiment, the normal operation for changing the setting of the setting unit 62 (see FIG. 4) is performed as follows. First, for example, a store clerk or the like opens the front door section 11 of the slot machine 10 whose power is off (see FIGS. 1 and 2). To open the front door portion 11, as described above, a predetermined key is inserted into the lock portion 23 (see FIG. 1) of the front door portion 11 which is locked in the closed state, and the key is moved in the unlocking direction. (e.g. counterclockwise).

Further, the setting door provided in the setting unit 62 shown in FIG. 4 is opened to make it possible to access the setting key cylinder into which the setting key is inserted, although not shown. Also, the setting key is inserted into the setting key cylinder, and the setting key is rotated in the ON direction (for example, clockwise) (ON operation). Then, power is supplied to the slot machine 10 by turning on the aforementioned power switch 72 . In this way, by turning on the power switch 72 while the setting key is ON, the setting change device processing (see FIG. 13) to be described later is performed in the "setting change device operation" state (situation in which the setting change mode is entered). ).

When power is supplied to the slot machine 10, a set value is displayed on the aforementioned setting display LED 66 mounted on the aforementioned main control board 61 (see FIG. 4). A so-called 7-segment display is used for the setting display LED 66 . Furthermore, in this embodiment, the setting display LED 66 displays one of the set values (here, six values from "1" to "6") which are integer values within a predetermined range, and the displayed setting The values are visible through the transparent main board case 65 .

When the setting/reset button 69 (see FIG. 4) is pressed under the condition that the setting change device is activated as described above, the display of the set value changes. In this embodiment, each time the set/reset button 69 is pressed, the display of the set value is incremented by one step. For example, when the slot machine 10 is powered on with setting 1 (the setting value is 1) and the setting/reset button 69 is operated once, setting 2 is set. Thereafter, each time the set/reset button 69 is pressed, the display of the set value changes to "2", "3", . . . in ascending order.

Furthermore, in the present embodiment, the highest set value, ie, the set value 6, is the most advantageous for the player, and the lower the set value, the lower the advantage. When the setting/reset button 69 is operated once at setting value 6, which is the highest setting value, setting 1, which is the lowest setting value, is obtained. Furthermore, in a situation where the value displayed on the setting display LED 66 is the set value to be selected, the game clerk or the like operates the start lever 25 (see FIG. 1) to operate the start switch (start lever 25 or By turning on a device having a start lever sensor 41 (not shown), the set value is determined.

It should be noted that the manner in which the display of the set value changes when the set/reset button 69 is pressed as described above is not limited to incrementing the display of the set value by one step. may be decremented by one step and changed in descending order. Furthermore, the range of setting values that can be changed by the setting change device processing (see FIG. 13), which will be described later, is not limited to six levels from "1" to "6", but for example, four levels from "1" to "4". may be

Subsequently, the setting key is rotated in the OFF direction (for example, counterclockwise direction) (OFF operation), the setting door provided in the setting unit 62 is closed, the regular setting change operation is completed, and the game can be played. state (normal state).

Here, after the above-mentioned "setting change device is activated" situation, the situation after the operation of the setting/reset button 69 becomes valid can be called the "setting value changeable" situation. . This “setting value changeable” is a state in which the setting value can be changed (selected) by operating the setting/reset button 69 .

In addition, the state in which the set value is confirmed by operating the start lever 25 (lever operation) after the “set value changeable” can be referred to as the “set value confirmed” state. When the set value is to be changed, the set/reset button 69 is operated as described above while the set value is changeable, and the start lever 25 is operated when the target set value is reached. to enter the “set value confirmed” status. In the "set value confirmation" situation, even if the set/reset button 69 is operated, the display of the set value does not change.

Further, the state of waiting for the setting key to be turned off after the above-described "setting value determination" can be referred to as a "setting value determination waiting state". It is impossible to change the setting value by operating the set/reset button 69 even in this state of "waiting for setting value determination". Furthermore, in this embodiment, it is possible to divide the state in the setting change work into the first state and the second state. When the power is turned on while the setting key is turned on, the state shifts to the first state related to the setting change, and when the start lever 25 is operated after that, the state shifts from the first state to the second state. Further, when the setting key is turned off in the second state related to the setting change, the second state ends.
<Procedures for Playing a Game and Processing When Inserting Game Medals>

Next, the procedure for playing a game and the processing when game medals are inserted will be described. In the process of inserting game medals, when the game medal selector 44 (see FIG. 6) is in a state of accepting game medals (a state in which game medals can be passed), the game medals are inserted from the game medal slot 21 (see FIG. 1). can be put in. Here, "inserting game medals" is synonymous with "setting the bet amount", and "setting the bet amount" is synonymous with "betting". When the game medals are inserted, the inserted number display LED lights according to the number of inserted game medals, and the start lever 25 can be effectively operated by inserting the prescribed number of game medals. Since the start lever 25 can be effectively operated, processes such as winning lottery based on the operation of the start lever 25, freeze lottery (lottery for freezing performance described later), and updating of the spinning drum drive state can be executed. become. Game medals are used as game media, and the game media are not limited to game medals, and game balls, electronic data, and the like can also be used.

Note that, when the maximum prescribed number of game medals for each game state is exceeded, the game medals thereafter are accumulated in the accumulation device. The storage device functions to store game medals up to a predetermined number (here, 50) under the control of the slot machine 10 . However, when the number of stored game medals exceeds the maximum number of 50, the game medal selector 44 enters the game medal return state, and the game medals inserted from the game medal slot 21 are paid. It is returned to the tray 17 from the outlet 16 (see FIG. 1). The storage device is also called "credit", and specifically refers to a device that electrically stores game medals (stores them in RWM).

After inserting a prescribed number of game medals, the spinning drum can be rotated by operating the start lever 25 and operating the spinning drum rotating device 54 . However, when any of the settlement button 74, the stop buttons 24L to 24R, the 1-sheet insert button 75, or the 3-sheet insert button 76 is operated, the spinning drums 51L to 51R are rotated even if the start lever 25 is operated. It is not possible.

When the start lever 25 is operated, the rotating drums 51L to 51R start rotating at an accelerated rate, and when they reach a predetermined rotational speed (here, 79.90 rpm), they enter a constant speed state. When the start lever 25 is operated, the game medal selector 44 enters the game medal returning state. Even if the start lever 25 is operated when a predetermined time (here, 4.1 seconds), which is the minimum game time (shortest game time), has not passed since the spinning drums 51L to 51R started rotating in the previous game. , the drums 51L to 51R do not rotate. The spinning drums 51L to 51R start rotating 4.1 seconds after the spinning drum started to rotate in the previous game. However, in the case of game standby due to a game effect (freeze effect, etc.) as will be described later, it is also possible to control the reel to start rotating after the end of the game standby.

When it is detected that the drums 51L to 51R are all rotating normally (here, rotating at a constant speed and not out of step), the stop buttons 24L to 24R are operated. becomes acceptable. However, if it is not detected that all of the drums 51L to 51R are rotating normally, the operation of the stop buttons 24L to 24R cannot be accepted until they are rotating normally. The game medals inserted from the game medal slot 21 are returned from the game medal payout slot 16 to the receiving tray 17 after the start lever 25 is operated until all the drums 51L to 51R are stopped.

In stopping the rotation of the drums, the rotating drums 51L to 51R are arbitrarily selected and the corresponding stop buttons 24L to 24R are operated to stop the drums 51L to 51R. However, if any of the settlement button 74, the start lever 25, the stop button corresponding to the reel that has already stopped, the 1-sheet insertion button 75, or the 3-sheet insertion button 76 is being operated, the stop button will not be operated. However, it is not possible to stop the rotating drum. It is also possible to make some of the buttons (main system buttons) managed by the main control board 61 operable (effective in operation) depending on the combination. The combination of buttons and switches that can be operated (the operation becomes valid) and buttons and switches that cannot be operated (the operation becomes invalid) can be determined arbitrarily. For example, while one of the stop buttons is being operated, the other stop buttons cannot be operated, but while the start lever 25 is being operated (after the operation), all of the stop buttons can be operated. be able to.

When the stop buttons 24L to 24R are operated, the corresponding reel stops within a predetermined time (here, 190 ms). Any of the remaining rotating drums are similarly stopped by operating the stop button corresponding to the arbitrarily selected drum. If you continue to operate the stop button, even if you operate the rest of the stop buttons, the corresponding reel does not stop. After operating the start lever 25, the rotating drums 51L to 51R do not stop unless the stop buttons 24L to 24R are operated. However, it is also possible to configure so that the spinning drum is stopped without operating the stop buttons 24L to 24R during the freeze effect.

In the display determination of the combination of symbols, when all the reels 51L to 51R are stopped, the display determination of the combination of symbols related to the winning or the action of the accessory is performed on the effective line corresponding to the prescribed number related to the input. However, if the start lever 25 or any of the stop buttons 24L to 24R is continuously operated during the 3rd stop, which is the 3rd stop, after releasing the operation, winning or operation will occur on the effective line according to the specified number. The display judgment of the combination of symbols is performed. Note that "determination of display of symbol combination" and "determination of display" means that the main CPU 81 detects a stopped symbol and directly determines what the stopped symbol is. ), for example, it is determined whether or not an abnormality has occurred in the control of the drums 51L to 51R. It means to proceed with the subsequent processing as if it was broken. Here, although illustration is omitted, the specified number that can be inserted in the slot machine 10 of the present embodiment is two in the game when the accessory is activated, and three in the other games. These are the upper, middle, and lower three lines of the reel display portion 15 (see FIG. 1). However, it is also possible to adopt a valid line of only one line in the middle stage, or five lines including diagonally upward right and diagonally upward left. Then, when a winning combination of symbols is displayed on the effective line corresponding to the prescribed number, the corresponding control is executed, and the combination of symbols related to the activation of the accessory or the continuous activation device of the accessory is displayed. When it is done, the control when the symbol combination related to the character product operation or the character product continuous operation device is displayed is executed.

When a winning symbol combination is displayed, the number of game medals corresponding to the predetermined winning symbol combination is paid out and won by the player. It should be noted that the acquired game medals are stored in the aforementioned storage device. However, when the number of stored game medals exceeds 50, the excess winning number is paid out from the game medal payout opening 16 to the receiving tray 17.例文帳に追加The game medals inserted from the game medal insertion port 21 during acquisition of the game medals are returned from the game medal payout port 16 to the tray 17. - 特許庁When all the game medals of the number corresponding to the combination of the symbols related to the winning of each prescribed number are obtained, the game medal selector 44 enters the game medal reception state when a predetermined condition is satisfied. Then, the above-described process for inserting game medals is executed. In this embodiment, the upper limit of the number of game medals that can be obtained by winning one prize does not exceed fifteen.

When a combination of symbols related to the operation of the role product is displayed, processing corresponding to the applicable role product is executed. In this embodiment, as the role (as the role to be drawn), the so-called normal role, the first type special electric role, the second type special electric role, and the first type special electric role are consecutive. There is no combination of symbols that activates each of the operating devices, but the combination of symbols that activates the replay and the combination of symbols related to the first class special accessories A symbol combination is provided which will cause the actuator to activate. Then, when a combination of symbols corresponding to these is displayed, the corresponding processing is executed.

On the other hand, when the symbols relating to winning and operation are not displayed, the game medal selector 44 enters the game medal receiving state. Then, the above-described process for inserting game medals is executed.

Next, the number of game medals that can be obtained when the combination of symbols related to the winning of each prescribed number and the combination of symbols is displayed will be described. The combination of winning symbols and the number of game medals that can be obtained correspondingly are determined in advance for each prescribed number. A game medal cannot be obtained without displaying a combination of symbols for winning a prize. Further, the combination of symbols related to the winning is not displayed without the operation of the condition device related to the winning.

The combination of symbols for winning and the number of game medals to be won when the accessory and the continuous operating device for accessories are not activated are set only when the specified number is 3, and the combination of symbols for winning (1 symbol or A predetermined number is defined for each obtained number of symbols (including those defined for only two symbols). In addition, the combination of symbols related to winning and the number of game medals to be acquired when the first type special accessory is activated are specified only when the prescribed number is 2, and the combination of symbols related to winning (only 1 or 2 symbols A predetermined number is defined for each acquired number.

Next, a combination of symbols related to operation for each prescribed number will be described. Combinations of symbols relating to the replay, the accessory, and the operation of the accessory continuous actuating device are determined in advance for each specified number. The combination of symbols related to the replay, the accessory, and the operation of the accessory continuous activation device is displayed without the conditional device relating to the operation of the replay, the accessory, and the continuous accessory activation device, etc. (when not activated). It is designed not to

And, the combination of symbols and the operation name related to the operation when the role and the continuous operation device are not operated are defined only for the specified number of 3 sheets, and the combination of symbols related to the operation (only 1 symbol or 2 In this embodiment, 8 types are provided as the number of patterns (including those defined only for patterns). The specific relationship between these operation names and symbol combinations will be described later. Then, when the combination of symbols related to the operation is displayed, the game control corresponding to the name of the operation is executed after that.

Next, a combination of symbols that allows a replay, effects when the combination of symbols is displayed, and processing when the combination of symbols is displayed will be described. When all of the spinning drums 51L to 51R are stopped, if the combination of symbols displayed on the activated line is the combination of symbols for replay, the replay is activated. Further, the slot machine 10 of the present embodiment is provided with a game in which the probability of operating a conditional device relating to a replay varies.

The trigger for the change in the probability of activating the conditional device related to replay is when the conditional device related to the operation of the continuous activating device related to the 1st type special accessory is activated, and the continuation of the 1st type special accessory This is when the combination of symbols for which the operating device is to be activated is displayed on the activated line, and when the operation of the accessory continuous operating device related to the first class special accessory is completed. As a process when a combination of symbols enabling replay is displayed, the same number of game medals as in the previous game are automatically inserted, and the start lever 25 becomes operable. Game medals inserted from the game medal slot 21 after the combination of symbols related to the replay are displayed are stored in the storage device when a predetermined condition is satisfied. Then, after that, in the same manner as in the above-described normal time (here, in the case other than the replay), control for rotation of the reel, control for stopping the rotation of the reel, and control for display determination of the combination of reels. is executed.

Next, the first class special accessories will be explained. When the accessory continuous operation device related to the first class special accessory operates, the first class special accessory at the time of operation of the accessory continuous operation device relating to the first class special accessory operates at the same time. In addition, at the time of operation of the accessory continuous operation device related to the first class special accessory, when the operation of the first class special accessory ends, immediately A kind of special function works again. As described above, when the first class special accessory is activated, in the same way as the above-described normal time (here, in the case other than the game related to the first class special accessory), the processing at the time of inserting the game medal and the rotation of the reel A game is played under the control of

Furthermore, when controlling the stopping of the rotation of the spinning drum, the player can arbitrarily select the rotating spinning drum and operate the corresponding stop button to stop the spinning drum. However, if any of the settlement button 74, the start lever, the stop button corresponding to the reel that has already stopped, the 1-sheet insertion button 75, or the 3-sheet insertion button 76 is being operated, the stop button will not be operated. cannot stop the rotating drum. When the stop buttons 24L, 24C, and 24R corresponding to the first to third drums 51L to 51R are operated, the corresponding drums rotate within a predetermined time (here, 190 ms) as in the case described above. Stop.

When one of the stop buttons is continuously operated, even if the remaining stop buttons are operated, the corresponding reel does not stop. After the start lever 25 is operated, the rotating drum does not stop unless the stop button is operated. As for the display determination of the combination of symbols, the control for the display determination of the combination of the reels is executed in the same manner as in the normal operation described above. In the present embodiment, a waiting time of about 200 ms (also referred to as the reel stop reception waiting time) is provided after the stop button operation is effectively accepted until the next stop button is effectively accepted. there is That is, when all the reels (51L to 51R) are rotating, for example, after the left stop button (first stop button 24L) is operated, the middle or right stop button (second stop button 24C or second stop button 24C or third stop button 200ms) 3 stop button 24R) can be accepted.

Regarding the end of the operation of the first-class special bonus, the first-class special bonus has the operation end condition that the specified number of games has been completed or the number of winnings has reached the specified number. The operation is terminated when at least one of the operation termination conditions is met.

Next, a description will be given of the accessory continuous actuating device relating to the first class special accessory. In the game when the accessory continuous operation device related to the first class special accessory is not activated, when all the spinning drums are stopped, the combination of the symbols displayed on the active line If it is a combination of symbols related to the operation of the operating device, the game related to the above-mentioned first class special accessory is executed. The trigger for ending the operation of the accessory continuous operating device for the first class special accessory is when the number of game medals obtained exceeds a predetermined number (for example, 465). After that, in the same manner as in the above-described normal operation, the processing may be shifted to the process of inserting game medals.
<Game production>

A typical example of the above-described game effect is a freeze effect. This freeze effect delays the progress of the game by suspending it for a predetermined period of time, and in this sense it can be called a delay effect. Furthermore, the freeze effect can be classified and understood as follows. That is, the freeze effect can be classified into one that the player can easily recognize the execution of the freeze effect and one that the player cannot recognize (or is difficult to recognize). Of these, the execution of the freeze effect can be easily recognized, such as those that do not respond to the operation of the start lever 25, and those that respond but rotate in a mode different from the operation mode of the reel during normal games. There are those that perform reel production (rotor production) that activates the torso. Those that do not respond to the operation of the start lever 25 include those that do not start operating even when the start lever 25 is operated and those that require a predetermined period of time (for example, 10 seconds) to start operating. .
<Major operations on the main control board>

Next, the main operation of the main control board 61 functioning as the main control means of the slot machine 10 according to this embodiment will be described with reference to FIG. 11 and subsequent drawings. First, the main control board 61 is configured so that the main CPU 81 can read the first control program stored in, for example, the built-in ROM of the main CPU 81 or the external ROM (main ROM 82) mounted on the main control board 61. Based on a second control program (to be described later), the built-in RWM of the main CPU 81 and the external RWM (main RWM 83) mounted on the main control board 61 are used to perform random number lottery and control of various devices. to execute.

Further, the main control board 61 sends commands (“main command”, “sub control command”, “sub main (also called "command"). Power is supplied to the main control board 61 from the aforementioned power supply unit 64 . For convenience of illustration, the external ROM and RWM are denoted by reference numerals 82 and 83, but in the following, unless otherwise specified, the ROM 82 and RWM 83 are those built into the main CPU 81. It is used as a generic term for externally attached items.

Examples of the aforementioned random number lottery include role lotteries such as replays, accessories, and accessory continuous actuating devices, performance lotteries such as freeze lotteries, and AT lotteries related to the execution of AT (assist time) and the like. can. In addition to the main control board 61, the main control means includes a main CPU 81 and peripheral devices such as a main ROM 82 and an RWM 83 that cooperate with the main CPU 81 to realize various functions of the main control board 61. is. Furthermore, although the terms "lottery" and "lottery" are used differently depending on the situation, these terms have the same meaning.
<Relationship between first control and second control>

Next, the above-described first control and first control program, and second control and second control program will be described. FIG. 11 shows an example of a memory map of the main CPU 81. As shown in FIG. The memory map in FIG. 11 shows an address space from "0000H" to "FFFFH". Among them, the space from "0000H" to "2FFFH" is allocated to the built-in ROM, and the space from "F000H" to "F3FFH" is allocated to the built-in RWM.

Furthermore, a register area (built-in register area) for registers built into each circuit in the main CPU 81 is allocated to the space from "FE00H" to "FEBFH". By causing the main CPU 81 to execute instructions for accessing these addresses, it is possible to execute access to the corresponding hardware.

The configuration of the built-in ROM (0000H to 2FFFH) described above can be divided into a first ROM area and a second ROM area. Among these, the first ROM area is an area that mainly controls the progress of the game. In addition, the second ROM area is mainly an area for controlling processes relating to situations different from the normal progress of the game, such as errors.

The first ROM area has a first control area (from "0000H" to "11FAH") and a first data area (from "1200H" to "1D9EH") shown on the right side of the drawing. The second ROM area has a second control area (from "2000H" to "22E4H") and a second data area (from "22E5H" to "2346H"), which are also shown on the right side of the drawing. .

Furthermore, the second control area has an unused area (1D9FH to 1FFFH) interposed between it and the first data area. The last address (22E4H) of the second control area and the top address (22E5H) of the second data area are continuous, and the unused area (2347H to 2FBFH) is located after the last address (2346H) of the second data area. ) and a management area (2FC0H to 2FFFH).

In this embodiment, the first ROM area is configured to have a larger capacity than the second ROM area. For example, it is assumed that the first ROM area does not include an unused area and consists only of a first control area and a first data area, and similarly the second ROM area does not include an unused area and consists of a second control area and a first data area. This relationship is established even when it consists of only two data areas. Note that the memory map shown in FIG. 11 is an example, and the number of bytes in each area and the presence or absence of unused areas can be changed in various ways.

The configuration of the built-in RWM (F000H to F3FFH) described above can be divided into a first RWM area and a second RWM area. Among these, the first RWM area is an area (sometimes referred to as a used area) in which information (game data) based on the progress of the game is written and stored as necessary, and the written information is further updated. ). In addition, the second RWM area is an area (sometimes referred to as "out of use area") for storing information based on processing different from the normal progress of the game, mainly related to errors. It can also be said that the first RWM area is the RWM area used in the first control, and the second RWM area is the RWM area used in the second control.

The first RWM area has a first work area (from "F000H" to "F14AH") and a first stack area (from "F1D7H" to "F1FFH") shown on the right side of the drawing. The second RWM area has a second work area (from "F210H" to "F21EH") and a second stack area (from "F3F3H" to "F3FFH") also shown on the right side of the figure. . Here, it is also possible to define the second RWM area to start from F200H.

The first stack area is an area used when the program related to the first control needs to store data internally, and the second stack area is used when the program related to the second control needs to store data internally. is an area used when it is necessary to store data internally. In the first stack area and the second stack area, for example, return address information (return address data) stored at the time of transition to a subroutine is written at any time according to the game situation. Note that the memory map shown in FIG. 11 is an example, and the number of bytes in each area can be changed in various ways.

An unused area (16 bytes of F200H to F20FH) of a predetermined size is provided between the first stack area and the second work area. It is conceivable that this unused area is essential. Furthermore, unused areas (F14BH to F1D6H, F21FH to F3F2H) of a predetermined size are also provided between the first work area and the first stack area and between the second work area and the second stack area. ing. It is conceivable that these unused areas are not required.

The first RWM area has a larger capacity than the second RWM area. Further, in this embodiment, a set of the first work area and the first stack area is the first RWM area, and a set of the second work area and the second stack area is the second RWM area. However, without being limited to this, it is also possible to employ a configuration in which the first stack area is not included in the first RWM area and the second stack area is not included in the second RWM area. In this case, for example, the space from "F000H" to "F14AH" can be assigned the first RWM area, and the space from "F210H" to "F21EH" can be assigned the second RWM area. is.

Here, regarding the ROM mounted on the main control board, it is preferable to configure so that unused areas (unfilled areas) are not provided in order to prevent unauthorized programs from being modified. is. To do this, for example, it is conceivable to fill unused areas with 0's and write used areas to younger (smaller number) addresses. In this embodiment, all bits of the unused area are "0", and any bit of the area other than the unused area is "1" (not "0"). are).
<Trigger and Range of RWM Initialization>

Next, the timing and scope of initialization of the first RWM area and the second RWM area will be described. First, the timing and range of initialization of the first RWM area are determined as follows (1) to (3) according to the state of recovery from power failure in this embodiment.
(1) When power failure recovery cannot be executed normally when the setting change device is activated Data 0 is set in the first RWM area (“F000H” to “F1FFH”).
(2) When the setting change device is activated, except when power failure recovery cannot be executed normally. Data 0 is set in the range (“F008H” to “F1FFH”) excluding the soft random number initial value and the RT state number.
(3) When the power is restored after power failure ”) is set to data 0.

Next, the timing and scope of initialization of the second RWM area will be described.
(1) When the setting change device is activated Data 0 is set in the second RWM area (for example, "F200H" to "F3F5H") excluding the stack usage amount when the setting change device is activated.
(2) When the power is restored after power failure Data 0 is set to "F20FH" and "F21FH" to "F3F2H").

It should be noted that the first work area can be referred to as, for example, a "use area work area". Furthermore, the first RWM area only needs to include the first work area. For example, from the start address of the first work area to the end address of the first stack area (in the example of FIG. 11, the unused addresses of F14BH to F1D6H are area) may be the first RWM area. Furthermore, the same applies to the second RWM area. For example, the area from the first address of the second work area to the last address of the second stack area (including the unused area of F21FH to E3F2H in the example of FIG. 11) is set as the second RWM area. good too.

Here, the first control area, the first data area, the second control area, and the second data area, which are areas used for ROM data, are based on their usage, for example, "writing is not performed during the game. can be referred to as a "region" or the like. Also, the first work area, the first stack area, the second work area, and the second stack area can be called, for example, "areas in which writing can be performed during a game" based on their usage.

By arranging the built-in ROM area and the built-in RWM area via an unused area (3000H to EFFFH) as described above, the "area where writing is not performed during the game" and the "game area" with different uses are arranged. In RWM, structurally (and addressing), it is possible to clearly demarcate the "area in which writing can be performed".

Also, in this embodiment, the first data area is arranged after the first control area 1, followed by the second control area 2 and the second data area with an unused area (1D9FH to 1FFFH) interposed therebetween. are placed. Also, the first work area, the first stack area, the second work area, and the second stack area are arranged with an unused area interposed therebetween. Therefore, both the "area where writing is not performed during the game" and the "area where writing can be performed during the game" are classified without mixing according to the distinction between the first control and the second control. can be placed in the same state.

The distinction between the first control and the second control can be called, for example, "control distinction", "control division", "control type", or "control classification". Also, a set of a first control area and a non-second control area, a first data area and a second data area, a first work area and a second work area 2, or a first stack area and a second stack area are respectively , as the same type of information (data) between different control sections, and it is possible to say that the data types are the same for each set.

In this embodiment, the same data types (first control area and second control area, or first work area and second work area, etc.) between different control sections as described above are arranged adjacent to each other. It can be said that region allocation is performed without

In addition, in the present embodiment, an unused area is provided between the first stack area and the second work area in the built-in RWM area, which is the "area where writing can be performed during the game." In the area of the built-in RWM, areas of different control categories (first control and second control) are arranged without being adjacent to each other and without being mixed with each other via unused areas.

Furthermore, in this embodiment, for example, when control is being performed according to the first control program, writing (updating, etc.) to the second RWM area is not performed, and control is performed according to the second control program. is being performed, writing (updating, etc.) to the first RWM area is not performed. However, for example, when the control is being performed according to the first control program, the data in the second RWM area may be referred to (confirmed, etc.), and the control is being performed according to the second control program. data in the first RWM area may be referred to (confirmed, etc.).

Further, as will be described later, when returning to the first control after transitioning from the first control to the second control, or when returning to the second control after transitioning from the second control to the first control, at the time of transition and The contents of the register are kept the same when returning.

According to the area arrangement and handling of the RWM as described above, for example, the same data type between different control sections, such as the first work area related to the first control and the second work area related to the second control It is possible to prevent a situation in which relevant data are stored in adjacent areas or addresses. For this reason, for example, even if an unauthorized third party tries to find predetermined data generated during a game and confirms the stored data by tracing the addresses of the RWM in ascending or descending order, the necessary data cannot be obtained. cannot be detected efficiently.

That is, it is the first work area and the second work area that various winning combination results, error information, and the like in the game are stored. Therefore, even if a third party tries to find the first work area or the second work area by tracing the addresses in ascending or descending order, unused areas and stack areas for storing return addresses exist before and after. Therefore, the first work area and the second work area cannot be reached immediately.

Also, even if you try to shift the detection destination from the first work area to the second work area (or from the second work area to the first work area), the existence of the unused area and the first stack area will cause the target work area to cannot be reached. As a result, it becomes possible to delay access to information necessary for fraudulent activity, and to prevent or deter fraudulent activity.

Furthermore, in this embodiment, the program code that exists in the first control area and is accessed by the main CPU 81 and the program code that exists in the second control area and is accessed by the main CPU 81 are separated on the memory map. (with non-consecutive addresses). Furthermore, since an unused area (1D9FH to 1FFFH) is sandwiched between the first control area and the second control area, the arrangement of both program codes can be clearly seen visually on the program source code or dump list. It is possible to divide into Further, it is possible to prevent illegality by such separation as well.

Also, in this embodiment, data is written to the RWM only in the RWM area determined for the control section being executed. In other words, between the first control and the second control, the control division is changed in a predetermined case. No data is written or updated, and in a situation where the second control is being performed, no data is written or updated with respect to the first work area and the first stack area.

Data writing in each control section is performed only in the work area and stack area corresponding to the control section within the control section without transferring to another control section. Therefore, the first control and the second control can be clearly divided in terms of the processing of the main CPU 81 as well, thereby enabling deterrence and early detection of fraud.

The area (0000H to 2FFFH) of the built-in ROM is divided into an area (0000H to 1D9EH) related to the first control and an area (2000H to 22E4H) related to the second control. Then, by performing control processing while shifting between the first control program and the second control program, it is possible to perform game control while clearly separating the first control and the second control.
<Processing when power is turned on in the main control board>

Next, a description will be given of the process performed by the main control board when the power is turned on. When the main CPU 81 of the main control board 61 is powered on via the power supply unit 64, the program code located at the address (first control area) of "0000H" in the built-in ROM (see FIG. 11) They are executed in order. The main CPU 81 sets the Q register to "F000H" based on the data in the ROM area and RWM area related to the first control.

Next, the main CPU 81 executes main control function setting based on the data in the ROM area and the RWM area related to the first control. Further, the main CPU 81 calculates a checksum based on the data in the ROM area and the RWM area related to the first control, checks the first RWM and the second RWM (for example, holds the calculated checksum and the checksum area Based on the stored checksum data, it is checked whether or not the data stored in the built-in RWM is correctly held by power-off/power-off recovery), and power-off recovery data is generated.

12, when the power is turned on to the main CPU 81 of the main control board 61, the power-on process shown in FIG. ” etc.) is executed. In this power-on process, an initial value is set for a predetermined register (S1). The contents of the setting include the setting of the communication speed of the serial communication circuit provided in the main CPU 81, the setting of the interrupt type (mode), the setting of the parity given to the command to be transmitted, and the like. Furthermore, in this embodiment, only one type of maskable interrupt is used as the type of interrupt among various interrupt types that can be used. Also, even parity is used for parity setting.

Subsequently, a maskable interrupt is set (S2) and access to the RWM is permitted (S3). Further, an internal random number is set (S4), and an RWM check is performed. In this RWM check, a checksum calculation (S5) and a power-off processing completion flag indicating that power-off processing has been completed are used to determine whether or not the backup at the time of the previous power-off was normal. Power failure recovery data is generated. In the above-described checksum calculation (S5), the checksum for the same storage area range (here, "F000H" to "F3FFH" of the built-in RWM in FIG. 11) as the RWM checksum in the power-off process (described later) to run.

In addition, in the checksum calculation (S5), after the calculation process, it is determined whether or not the calculation has been completed for the entire target range (S6), and if the calculation for the entire range has not been completed ( S6: NO), returning to the calculation process (S5). Then, the calculation of the checksum is repeated until the calculation for the entire target range is completed. Here, the determination as to whether or not the calculation for the entire target range has been completed may be performed after the calculation for each address, or may be performed after the calculation for each predetermined range.

After the checksum calculation for the entire target range is completed (S6: YES), the power failure recovery data is stored in the register (S7). Here, the power-off recovery data differs depending on whether either the power-off execution processing flag or the RWM checksum is abnormal and when both are normal. Further, the data of input port 1 is stored in the register (S8). Here, the data of the port (input port 1) to which the designated switch signal in the next step (S9) is input is acquired.

Subsequently, it is determined whether or not the designated switch is ON (S9). The specified switches refer to three switches, a door switch, a setting door switch, and a setting key switch. Then, the states of the door switch signal, the setting door switch signal and the setting key switch signal are checked (S9), and if all the switch signals are ON (S9: YES), setting change device processing (see FIG. 13) will be described later. I do. In this embodiment, when all switch signals are ON, the door (front door section 11) is opened, the setting door of the setting unit 62 (see FIG. 4) is open, and the setting key switch 68 is opened. is rotated in the ON direction, and the determination result of S9 becomes "YES" when these three conditions are satisfied. The setting door switch may be excluded from the designated switches, and the setting change device may be activated when both the door switch and the setting key switch are ON.

For example, when the door (front door section 11) is closed (when the door switch is in the closed state), the setting door of the setting unit 62 (see FIG. 4) is in the open state and the setting key switch 68 is turned on. Even if the direction is rotation, the determination in S9 will not be "YES". In such a case, there is a possibility that fraudulent activity has been carried out. Therefore, by not making the judgment result "YES", it is possible to prevent the transition to the later-described setting change device processing (also referred to as "setting change processing"). It's becoming If the setting door switch 67 (see FIG. 4) is not provided, all the switch signals are ON as a result of checking the states of the door switch signal and the setting key switch signal in the determination process of S9. is ON.

If the condition is satisfied and the result is "YES" in the determination of whether or not the designated switch is ON (S9), it is determined whether or not the power failure recovery data is abnormal (S10). ). If the determination (S10) related to the power failure recovery data is affirmative and "YES" (if the power failure recovery data is abnormal), the setting change device processing (see FIG. 13) described later Move to Further, when a negative determination is made and the result is "NO" (when the power failure recovery data is not abnormal), it is determined whether or not the setting change prohibition flag is ON (S11), and a negative determination is made. When the result is "NO" (when the setting change prohibition flag is not ON), the setting change device processing (see FIG. 13) is also performed.

Further, when the determination (S11) relating to the setting change disable flag is affirmatively determined to be "YES" (when the setting change disable flag is ON), confirmation of power-off restoration data, which will be described later, is performed. It shifts to processing (S12). The setting change prohibition flag is one of the data stored in the RWM, and is set during the period from the role lottery process (S60) to the check at the end of the game (S68) in the game progress main process (see FIG. 14), which will be described later. is data indicating that the setting cannot be changed.

If at least one of the switch signals is not ON (S9: NO) in the determination of whether or not the designated switch is ON (S9), or if the setting change prohibition flag is ON If so (S11: YES), the process proceeds to the process of confirming power-off recovery data (S12). In this power-off recovery data confirmation process (S12), power-off processing (to be described later) was performed at the time of the previous power-off, and a predetermined RWM area was calculated at the time of the previous power-off. If the obtained checksum value is normal, it is determined to be normal, otherwise it is determined to be abnormal.

In the power failure recovery data confirmation process (S12), if it is determined that the power failure recovery data is abnormal (S12: NO), an error is displayed (S13), and an error code ( E1) is displayed and the operation of the gaming machine is stopped. The E1 error, which is the error at this time, is an error that cannot be canceled unless the setting change device processing (see FIG. 13) is executed. be. In the process of confirming the power-off recovery data (S12) described above, if the power-off recovery data is determined to be normal (S12: YES), the process proceeds to the power recovery process (see FIG. 21). The power restoration process (see FIG. 21) will be described later.
<Setting change device processing>

FIG. 13 shows the setting change device processing described above. In this setting change device processing, the stack pointer is set and the operation of the setting change device is started. Then, as shown in the figure, a predetermined range of RWM initialization is stored in a register (S21). , the aforementioned storage area range (here, addresses F000H to F3FFH in FIG. 11) are set. Furthermore, here, the set value data related to the aforementioned set values, the RT state number related to the replay time (RT), and the conditional device flag related to the aforementioned conditional device are not stored as objects to be initialized. Here, RT (replay time) is a game state in which the probability of winning a replay is higher than normal, and the RT state number is a number for distinguishing a plurality of RT states with different winning tendencies in replays. . Also, the set value can be explained as defining the theoretical probability of winning (the degree of advantage for the player) as described above. It can be explained that the probability of winning a role differs depending on the number of hands. In addition to this, the set value may be used in such a manner that the probability of winning a role is the same, but the probability of winning another lottery (such as an AT lottery) based on the winning of a role is different.

Subsequently, it is determined whether or not the power-off restoration data is normal (S22), and it is determined whether or not power-off processing (to be described later) has been performed normally. This power-off recovery data is stored in a predetermined register after the checksum calculation is completed in the above-described power-on process. If it is determined that the power was not turned off normally (S22: NO), the set value data, RT state number, and condition device flag are included in the "specific range" to be initialized. , is stored in a predetermined register (S23). Here, the "specified range" is distinguished from the above-mentioned "predetermined range" in that it includes the set value data, the RT state number, and the condition device flag.

On the other hand, if it is determined that the power-off is normal (S22: YES) in determining whether or not the power-off recovery data is normal (S22), a predetermined register (here, the AF register) is saved (S24), and the contents of the register (return address) are stored in the first stack area. Then, the first control is shifted to the second control, and the RWM initialization 3 (S25), which is the control module related to the second control, is executed. This RWM initialization 3 (S25) is a part of the second control program developed in the aforementioned second control area. Then, in the RWM initialization 3 (S25), the amount of stack used when the setting change device is activated (stack area required when the setting change device is activated) in the RWM region (here, F200H to F3FFH) related to the second control is The RWM area except (F200H to F3F5H) is cleared. The details of this RWM initialization 3 will be described later.

After this RWM initialization 3 (S25), the AF register is restored (S26), and the transition (return) from the second control to the first control is performed. Then, the timer interrupt is activated by the interrupt activation setting process (S27). In this interrupt activation setting process (S27), the type of interrupt and the cycle of the timer interrupt are set. After this processing, timer interrupt processing (see FIG. 18), which is timer interrupt processing, can be executed. In this embodiment, as described above, the period of the timer interrupt is 2.235 ms.

Subsequently, data indicating "set change start" is stored in the register (S28). This data indicating "set change start" serves as a command for notifying the aforementioned sub-control board 31 that the setting change device process has started and is being executed. Further, the processing of the control command set 1 (S29) is performed. The processing of the control command set 2 is to store the aforementioned sub-control commands in a ring buffer (transmission buffer) that temporarily stores them before transmission. Here, a sub-control command indicating "setting change start" is set in the ring buffer by the processing of the control command set 1 (S29). Details of the processing of the control command set 2 will be described later.

Subsequently, a check is made to see if the set value is within a predetermined range (S30), and if the set value is not within the normal range (here, one of six values from "1" to "6") ( At S30: NO), the setting value is set to 1 (S31), and the process proceeds to the process of displaying the setting change device in operation (S31). On the other hand, if the set value is within the normal range (S30: YES), the set value (=1) is not set (S31), and the setting change device operating display process (S32) is performed. Here, in this embodiment, the normal range of set values is set to "1" to "6", and "0" is not used as the value of the normal range. This is because it is conceivable that the value may accidentally become "0" when an abnormality occurs in the control for some reason, and such a case can be accurately determined as an abnormality.

In the above-described setting change device operating display processing (S32), the lamp (LED) is lit and the set value is displayed during the setting change device processing. The "lighting" and "display" performed here are processing for setting data (flag) for "lighting" and "display". A predetermined process (here, the LED display process (S549) in FIG. 18) in the interrupt process (see FIG. 18) outputs to drive the setting display LED (66) and the obtained number display LED. In this embodiment, the set value is displayed on the setting display LED (66), and "--" indicating that the setting change device is in operation is displayed on the obtained number display LED.

Further, determination processing (S33) relating to the setting/reset button signal (setting/reset switch signal) is performed, and the setting/reset button signal is changed from OFF to ON while the door switch signal and the setting door switch signal are ON. If so (S33: YES), the process proceeds to the set value update process (S34), otherwise, the process proceeds to the determination process related to the start lever 25 (S35). Here, the setting/reset button (69) related to the above-described setting/reset button signal serves as one button device as both a setting button (setting switch) and a reset button (reset switch) as described above. It is. Further, determination (S33) relating to the setting/reset button signal is performed based on the rise data of the setting/reset button signal.

In the setting value updating process (S34), the setting value is incremented by one. However, if the value exceeds the maximum set value (here, 6) as a result of the addition, the set value returns to 1. In the determination processing (S35) relating to the start lever 25, if the start lever sensor signal (start sensor signal) has changed from OFF to ON (S35: YES), determination processing relating to the setting key switch 68 (S36). Otherwise (S35: NO), the process proceeds to determination processing (S33) relating to the setting/reset button signal.

In the determination processing (S36) relating to the setting key switch 68, if the setting key switch signal is turned off while the door switch signal and the setting door switch signal are ON (S36: YES), the setting is changed. The process proceeds to the process of clearing the display during device operation (S37), and in other cases (S36: NO), the process of S36 is repeated. In the process of clearing the setting change device operating display (S37), the lamp is turned off during the setting change process and the display of the set value is ended. More specifically, the setting display LED is turned off, and "00" is displayed on the obtained number display LED. The "turn off" and "end of display" performed here are processes for setting data (flag) for "turn off" and "end of display" in the same manner as described above. The data obtained is used for driving the setting display LED and the obtained number display LED by a predetermined process (here, the LED process (S549) in FIG. 18) in the subsequent timer interrupt process (see FIG. 18). used for

Subsequently, data indicating "end of setting change" is set in the register (S38). The data indicating "end of setting change" serves as a command for notifying the aforementioned sub-control board 31 that the setting change device processing has ended. Further, processing of control command set 1 (S39) is performed, and this control command set 1 (S39) uses the same control module as the above-described control command set 1 (S29). Then, by the processing of the control command set 1 (S39), a sub-control command indicating "end of setting change" is set in the ring buffer. After that, the process proceeds to the game progress main process (see FIG. 14), which will be described later.

In order to activate the setting change device, it was necessary to turn on a plurality of switches (S9 in FIG. 12). is confirmed (S36 in FIG. 13). In other words, it can be said that the conditions for terminating the operation of the setting change device are relaxed compared to the conditions for starting the operation.
<<Control command set 2>>

Next, the processing of control command set 2 performed in control command set 1 (S29, S39) described above will be described. In this control command set 2, the control command buffer address is set and the data of the control command write pointer is obtained. Furthermore, the specified address is set, the specified address data is obtained, and it is determined whether or not the control command is smaller than "64".

Then, if the control command is smaller than "64", the control command is set, the control command write pointer is updated, and the process ends. In the process of determining whether the control command is smaller than "64", if the control command is not smaller than "64", the control command is not set and the control command write pointer is not updated. Finish processing.
<Game progress main processing>

Next, the game progress main processing will be described with reference to FIG. Here, an outline of the game progress main process will be described, and among various control modules used in the game progress main process, main ones in this embodiment will be described later. In the game progress main process, the stack pointer is set (S51), and in the game start set process (S52), the following processes are performed. That is, the game state is set in the game start set process (S52).

That is, in the game start set process (S52), the set at the time of game start is performed. Furthermore, although illustration is omitted, the game standby display start time is set, the pull-in symbol data is cleared, and the operation state is set.

More specifically, based on the combination of symbols stopped and displayed in the previous game, it is determined whether the current game is a replay or a game in which the accessory continuous actuating device related to the above-mentioned first class special accessory operates. (Type 1 BB game) data is set. Furthermore, a wait standby is performed after the sub-bonus. Here, the sub-bonus is a bonus managed by the aforementioned sub-control board 31 side. It means a game state such as

As a specific example, "7" symbols are displayed in line on the winning line in the production, and it becomes a winning state of a specific replay. A game state such as giving a profit by setting the state can be mentioned. The wait waiting after the sub-bonus means the waiting time for performing the bonus termination demonstration, similar to the bonus (main bonus) managed by the main control board 61, when the AT state ends. . Then, the trigger for starting the standby time can be set on the main control board 61 side, such as when 30 games have elapsed after winning a specific replay.

Subsequently, in the game start set process (S52), although not shown, commands indicating various game information are written in command buffers. Further, a full detection signal is checked, and if the game medal auxiliary storage 71 is full, an error code (FE) is displayed to that effect on the win number display LED, and the game is stopped.

When the game medal auxiliary storage box 71 is not full or when the error is canceled, the insertion of game medals is accepted. In accepting the insertion of game medals, if the replay is not yet activated, the blocker signal is turned ON (passable state) to start accepting the insertion of game medals. In the case of the replay operation, if game medals can be inserted into the storage device (if the number of credits has not reached the maximum number of 50), the blocker signal is turned ON (medal channel formation), and the tokens are sent to the storage device. When game medals cannot be inserted, the blocker signal is not turned ON, and game medals corresponding to the number of bets in the previous game are automatically inserted. Blocker processing during replay operation will be described later.

In the game progress main process, subsequently, as shown in FIG. 14, the process of reading game medals (S53) is executed. In the process of reading game medals (S53), data on the number of game medals is read, and the presence or absence of the number of game medals is checked. After the process of reading game medals (S53), the presence or absence of game medals is checked (S54). notification) processing (S55), and if there are game medals (S54: YES), the processing shifts to game medal management processing (S56). Here, the presence of game medals indicates a state in which game medals are bet set (bet) in order to meet the prescribed number for playing the game.

In the display processing (S55) when waiting for game medals to be inserted, when the setting key switch signal turns from OFF to ON, the blocker is turned OFF, and a control command for starting setting value display is set. Further, the set value is displayed on the setting display LED until the setting key switch signal turns from ON to OFF. Then, a control command for ending the setting value display is set, and the blocker is turned on. Then, when the game standby display start time has passed, the process shifts to the process of clearing the acquired number display, otherwise the process ends.

In the game medal management (S56), blocker state confirmation processing is performed. A process based on the operation of the button 76) is performed. This game medal management (S56) will be described later (see FIG. 26). Furthermore, after the game medal management process (S56), soft random number update 1 (S57), which is a process for updating soft random numbers, is performed. In this soft random number update 1 (S57), soft random number update 2 is performed. Soft random number update 2 is for updating the internal random number processing random numbers.

Subsequently, in the start lever check process (S58), a reception check of the start lever is performed. In other words, although illustration is omitted, an error display of the insertion/payout sensor is performed, and if the number of inserted coins does not match the specified number, the process is terminated. Further, if the monitoring time when the blocker is ON (monitoring time when the blocker is ON) has not elapsed, the game start display LED signal is turned OFF, and the processing is terminated. Subsequently, the game start display LED signal is turned ON. Then, when the start lever sensor signal is changed from OFF to ON, the process shifts to the start lever reception, otherwise the process ends.

More specifically, as an acceptance check of the start lever 25, the following processes are performed in order. That is, the selector passage sensor stagnation flag indicating whether or not the game medals are staying in the selector passage is checked, and if the game medals are staying, the error code (CH) corresponding to the winning number display LED is displayed. Stop playing. In other cases or when the error is canceled, the input sensor abnormality detection data is checked, and if an abnormal input is detected, an error code (C0) corresponding to the winning number display LED is displayed and the game is stopped. do. Specific processing for these will be described later.

In addition, in other cases (when no abnormal input is detected) or when the error is cleared, the payout sensor abnormality detection data is checked, and when an abnormal input is detected, H0 is set to the acquired number display LED. Display and stop the game. In addition, in other cases (when an abnormal input is not detected) or when the error is canceled, the overflow detection data is checked, and when the game medal auxiliary storage is full, FE is displayed on the winning number display LED. and stop playing. In other cases (when the game medal auxiliary storage box is not full) or when the error is cleared, the process proceeds to the following process.

That is, the number of inserted game medals is compared with the specified number, and if they match the specified number, the process proceeds to the next process (the process of determining whether or not to accept the start lever (S59)); It is determined that the start lever cannot be accepted, and the process returns to the processing for reading game medals (53). Furthermore, in the process (S59) for determining whether or not to accept the start lever, the start lever sensor signal is turned ON from OFF while the stop buttons 24L to 24R, the settlement button 74, and each input button are not operated. If changed, the start lever will be accepted, otherwise the start lever will not be accepted. Then, the blocker 47 of the game medal selector 44 is turned off (solenoid is turned off), and the game medal selector 44 is placed in a return state in which the game medals cannot pass through.

If it is determined that the start lever is not accepted (S59: NO) in the process of determining whether the start lever is accepted (S59), the process returns to the game medal reading process (S53), and if the start lever is accepted (S59: YES). , internal random numbers (hardware random numbers) are taken in, and the internal lottery start process (S60), which is part lottery process, is performed. Here, the loop processing (S53 to S59) when it is determined that the start lever is not accepted (S59: NO) is arranged after the stack pointer is set (S51). is always executed before the loop processing (S53-S59).

In the internal lottery start process (S60), the internal lottery process for determining the role lottery related to the condition device (replay, winning combination, role item, role item continuous operation device) and the symbol control number, etc. is performed. In the internal lottery process, different combination lottery tables are used according to game states, and the types of winning numbers (winning combinations) and winning probabilities differ according to various game states and RT states. As the random numbers for the internal lottery, those obtained by adding processing random numbers (software random numbers in this case) to the internal random numbers described above are used. Furthermore, regarding the lottery related to various types of winnings, the order of drawing is determined based on the types of winnings. Details of the internal lottery start process (S60) will be described later (see FIG. 15).

In the drum management processing (S61 to S65) including the drum rotation start processing (S61), management from acceleration to stop of the drum is performed. In addition, although illustration is omitted, the spinning drum management process (S61 to S65) is also executed in the pseudo game start process, which is the process for performing the above-described pseudo game. Then, in the drum management process (S61 to S65), the mechanism relating to the rotation of the drum is controlled, which will be described later.

In the drum rotation start process (S61), a data set for starting rotation of the drum and a faulty rotation inspection are performed. More specifically, the presence or absence of a reel with a data set request (a data set request reel) is determined, and if there is a data set request reel, data is set in the requested reel. Further, when a rotational failure is detected in a rotating drum during constant speed, the request data for setting the acceleration state is set for the rotating drum, and the above-described determination of the presence or absence of the data setting request rotating drum is performed. Then, when there is no data set request rotation, the software random number updating process 1, which is the above-described control module, is performed.

Following the drum rotation start process (S61), the number of frames to be shifted (pull-in point) is created (S62). In this process of creating the number of frames to be shifted (S52), data indicating the number of frames to be shifted is created for all reels that have not been stopped. More specifically, although illustration is omitted, if there is no request to create the number of frames to be shifted, the process ends. Further, the following processing is performed for all reels for which there is a shift frame number creation request in the order of the third reel (51R), the second reel (51C), and the first reel (51L).

First, the RWM address for storing the table search number used for creating the number of frames to be shifted is stored. Subsequently, the control reel number is stored in the RWM, and processing for initializing the pull-in points for the number of pattern arrangement frames is performed. Furthermore, control control execution processing is performed, and table set control processing is performed. Further, the control symbol numbers are initialized, and the following processes are performed for each control symbol number.

First, processing for creating a possible stop position is performed. Subsequently, the number of frames to be shifted is saved in the RWM corresponding to the control reel and the control pattern number. Further, the shift frame count creation request is cleared, and the process shifts to interrupt waiting processing.

After the process of creating the number of frames to be shifted (S62), the process proceeds to the process of checking acceptance of rotation stoppage (S63). In this rotation stop acceptance check process (S63), first, the sensors of all the reels are checked in order to check the stop operation, and if the stop acceptance is not accepted, the process ends. Furthermore, when any of the stop button sensor output signals (stop button sensor signal) corresponding to the spinning drum is turned ON, the process shifts to stop button reception processing. Furthermore, according to the rotating or stopped state of all reels, the stop reception information data is set, the stop position is determined, and the process proceeds to the processing of all reels stop check (S64).

In the process of checking all reels stopped (S64), it is checked whether all the reels are stopped and whether the stop buttons (24L, 24C, 24R) and the start lever 25 have been operated. In the process of checking the stoppage of all spinning drums (S64), all the spinning drums 51L to 51R are stopped, and the operation of the start lever 25 and the stop buttons 24L to 24R is started, for example, at the third stop as described above. It is checked whether the lever 25 or one of the stop buttons 24L to 24R is not in a state of being continuously operated, and whether the operation is properly terminated.

In the following processing for determining whether all reels should be stopped (S65), if the determination is affirmative (S65: YES), the process proceeds to display determination processing (S66); Return to S62).

In the display determination process (S66), the following processes are performed in order. That is, if the combination display of symbols is abnormal as a result of the display determination, an error code (E5) corresponding to the winning number display LED is displayed, and the game operation is stopped.

Subsequently, the game medal payout process (S67) is performed by winning a prize. In the game medal payout processing (S67) due to winning, game medals are paid out if there is a game medal payout due to winning. Also, although not shown, when the game medals are paid out, a display process is performed to display the number of game medals that have been paid out. In this processing for displaying the number of game medals, each time one game medal is paid out, the value displayed on the display device (in this case, the stored number display unit) is updated.

More specifically, in order to manage the payout of game medals upon winning and the number of payouts during BB operation, first, a control command for starting the payout of game medals is set. Subsequently, the number of medal payout signal outputs is set, and if there is no number of game medals to be paid out, the process is terminated. Further, it updates the number of medals that can be obtained when the BB is activated, performs the processing described later for the number of medals to be paid out, and sets a control command for ending the payment of game medals.

As the processing related to the number of payouts described above, first, the following processing is performed according to the payout destination of the game medals. That is, if it is possible to pay out to the storage device, one game medal is added after waiting for the addition time, and if it is impossible to pay out to the storage device, one game medal is paid out. Subsequently, as a process corresponding to the number of payouts, 1 is added to the acquired number data.

Next, a process (S68) at the end of the game is performed. In the processing (S68) at the end of the game, first, the replay display LED is turned off. Subsequently, the replay operation state flag and the winning and replay condition device numbers are cleared. Further, when the BB is in operation, the BB operation management process is performed, and in the case of the RB operation, the RB operation management process is performed. Also, when the bonus is not in operation, the processing shifts to RT state management.

After that, the output request at the end of the game is set (S69), the above-described control command set 1 is performed (S70), and the main game progress processing is executed again. In addition, even if a prize is generated for the accessory or the continuous operation device, if the corresponding combination of symbols is not complete, the flags related to these prizes are carried over. In addition, flags related to replay and condition devices for small wins are cleared. That is, as the end processing according to the game state described above, RWM clear processing of the condition device numbers other than carryover hands, RT number generation processing, freeze state transition processing, external signal data generation processing, etc. are performed. will be

Next, the internal lottery start process (S60) among various processes in the game progress main process (S51 to S70) will be described in more detail. As described above, the internal lottery start process (S60) is a process that proceeds when reception of a start lever operation is detected in a situation where a game can be started. As shown in FIG. 15, in the internal lottery start process (S60), the condition device number set (S81), the symbol control number set (S82), the drawing symbol data set (S83), the control symbol set (S84), the ball Lottery management (S85), condition device command setting (S86), spinning drum rotation start standby (S87), and spinning drum rotation start preparation (S88) are executed in order.

Of these, in the condition device number set (S81), first, it is determined whether or not the bonus condition device is activated. Then, if the bonus condition device is not activated, the data indicating the bonus condition device number is saved (S502), and the data indicating the winning and replay condition device numbers are saved.

In the ball lottery management process (S85 in FIG. 15) described above, the data related to the effect group number is set, the specified number is set, the main game state management process is performed, and the condition device command set process (Fig. 15 S86).

In the processing of the condition device command set (S86 in FIG. 15), as shown in FIG. 16, interrupts are prohibited (S511), the AF register is saved (S512), the second control is performed, and the pattern A stop signal output process (S513) is executed. The pattern stop signal output process (S513) performed as the second control is a process for outputting the pattern stop signal data for the trial shooting test, and the details thereof will be described later (see FIG. 33).

When the pattern stop signal output processing (S513) is finished, the process returns to the condition device command set processing (FIG. 16) relating to the first control, and the AF register is restored (S514). Further, the interrupt is permitted (S515), the command table is set when the start lever is received (S516), and the caller is returned to.

In the spinning drum rotation start standby process (S87 in FIG. 15), it is determined whether or not the minimum game time has elapsed, and when the minimum game time has elapsed, the minimum game time data is saved. Subsequently, the conditional device output time is saved, and processing for waiting for command transmission is performed.

In the drum rotation start preparation process (S88 in FIG. 15), the drum stop order data and push order data are initialized, and the drum stop flag and the data for requesting the number of frames to be shifted are initialized. Furthermore, the data of the number of initialized symbol groups is set, and the symbol control data table 1 is set. In addition, the initialization start RWM address is set, and the stop symbol data is initialized.

Subsequently, data relating to an output request at the start of full reel rotation is set, and the same control command set 1 as described above is executed. Then, the all-rotation-rotation-starting bit and the data relating to the preparation state for starting rotation are set, and the data indicating that there is a rotation-starting rotation is set.

Next, the display determination process (S66) in the above-described game progress main process (see FIG. 14) will be described. FIG. 17 shows the contents of the process of display determination (S66). In this display determination process, an acquired number display clear process (S401) is executed, and then various data set processes (S402, S403) and an E5 error set process (S404) are executed.

The acquired number display clearing process (S401) described above is for clearing the data of the acquired number display, and is the same process as the acquired number display clearing process (S339) in the above-described storage insertion process (see FIG. 27). is. Furthermore, the above-described various data setting processes (S402, S403) include setting of RWM addresses related to predetermined stop symbol data (S402), and setting of RWM addresses related to the number of control symbol groups and kicking symbol data (S404). is.

Here, the kick-off symbol data is symbol data that constitutes a symbol combination that does not correspond to the result of the winning combination lottery. The kicking symbol data corresponds to, for example, symbol data relating to some symbols constituting the BB (big bonus) symbol combination when the aforementioned BB (big bonus) is not won.

Further, a set calculation relating to the kicking pattern is performed (S405), and the correlation between the kicking pattern data and the symbols displayed in the game at this time is calculated. Then, it is determined whether or not the displayed pattern corresponds to the kicking pattern (S406), and if the kicking pattern is displayed (S406: YES), the process proceeds to unrecoverable error processing (see FIG. 29). Transition. This unrecoverable error processing will be described later.

On the other hand, when the kicking pattern is not displayed (S406: NO), the next stop pattern data address is set (S407) and the next kicking pattern data address is set (S408). Then, it is determined whether or not determination corresponding to the number of control symbol groups has been completed (S409), and if completed (S409: YES), the process proceeds to 1-line display determination processing (S421). Also, if the determination corresponding to the number of control symbol groups has not been completed (S409: NO), the process returns to immediately before the arithmetic processing (S405) relating to the kicking symbol.

In the above S409, when the determination corresponding to the number of control symbol groups has been completed (S409: YES), the process proceeds to S421, and 1-line display determination processing is executed. In this one-line display determination process (S421), display determination of one effective line and data setting at the time of display are performed. Specifically, the operation type, symbol combination display flag, payout number data of game medals, payout number buffer and winning symbol group are stored according to the symbol combination determined to stop on the activated line.

Subsequently, processing for effect display when all reels are stopped is performed by processing for effect display when all reels are stopped (S422). In the effect display processing (S422) when all reel rotation is stopped, the CPU waits until the third stop standby time related to the third stop operation has passed, performs main game state management processing, and stops all reel rotation. A control command is set at time, and RWM initialization is performed at the time when all reel rotations are stopped.

Further, the flow advances to the process of inserting/dispensing sensor abnormality display (S423), and although the details will be described later, the inserting/dispensing sensor abnormality set process is performed. Then, the presence or absence of an error display request is checked, and if there is an error display request, the corresponding error is displayed, otherwise the process is terminated. Also, when the error is canceled, the input/discharge sensor error clear is performed.

FIG. 50 more specifically shows the above-described input/discharge sensor abnormality display processing (S423 in FIG. 17). As shown in FIG. 50, in this insert/payout sensor abnormality display process, interruption is prohibited (S431), the AF register is saved (S432), and the insert/payout sensor abnormality set process related to the second control is executed. It does (S433). The details of the input/discharge sensor abnormality set process (S433) will be described later (see FIG. 36).

After the input/discharge sensor abnormality set processing (S433), the AF register is restored (S434), interrupt permission is performed (S435), and error display request data acquisition processing is performed (S436). In this error display request data acquisition process (S436), error display request data is acquired. Then, it is determined whether or not there is error display request data (S437), and if there is no error display request data (S437: NO), the process is terminated. In S437, if there is error display request data (S437: YES), error display processing (S438) is performed. The details of this error display processing (S438) will be described later (see FIG. 24).

Thereafter, the interrupt is prohibited (S439), the AF register is saved (S440), and the input/discharge sensor abnormality clearing process (S441) relating to the second control is performed. The details of this input/discharge sensor abnormality clearing process will be described later (see FIG. 37). After the input/discharge sensor abnormality clearing process (S441), the AF register is restored (S442), the interrupt is permitted (S443), and the first interrupt prohibition process (S431) is returned to.
<Timer interrupt processing in the main control board>

Next, timer interrupt processing will be described with reference to FIG. An outline of the timer interrupt processing will be explained here, and main ones in the present embodiment among various control modules used in the timer interrupt processing will be described later. The timer interrupt process is repeatedly executed at predetermined intervals (here, 2.235 ms) based on the power-on process shown in FIG. 12 and the activation of the setting change device process shown in FIG. 13 (see S27). is.

In this timer interrupt processing, as initialization processing at the start of interrupt, the value of the register is saved (S541), and the interrupt flag for prohibiting duplicate interrupts is cleared (S542). The register saving process (S541) in this initialization process is for enabling the registers used in the game progress main process (see FIG. 14) to be used in this timer interrupt process. be.

Subsequently, power-off processing (S543) is executed. In this power-off processing (S543), after determining whether or not there is a power-off detection signal, various types of processing are performed, the details of which will be described later. Furthermore, the interrupt counter is updated (S544), input port data generation (S545), reel drive management (S546), port output (S547), control command transmission (S548), LED display (S549), and sub notification data output. (S550) and timer measurement (S551) are sequentially executed.

Then, after executing these, as shown in the figure, the processing shifts to error management processing (S552, see FIG. 20). Subsequently, external signal output data management processing (S759) and external signal output processing (S760) are performed in order. Each of these processes (S759, S760) will be described later.

Further, the AF register is saved (S761), the process shifts to the second control, and test signal output processing (762) is performed. This test signal output processing (S762) will be described later (see FIG. 35). When the test signal output processing (S762) ends, the control returns to the first control, and the AF register is restored (S763). Then, soft random number management processing (S764) is performed, and after returning to the register (S765), interrupt permission is performed, and the processing ends.

Although each process (S543, S545 to 551, etc.) in the timer interrupt process will be described below, first, the power-off process (S543) among the above-described processes will be described.
<<Power off processing>>

In the power-off processing (S543), as shown in FIG. 19, it is determined whether or not the previous power-off detection signal is ON (S561). Input port 0 data is input (S562). Further, it is determined whether or not the power failure detection signal is ON (S563), and if it is ON (S563: YES), data of the clear output port address and the number of output ports are set (S564).

Subsequently, the output ports (0 to 6) are turned off (S565), and the data of the next output port address are set (S566). Further, it is determined whether or not the output has ended (S567), and if it has ended (S567: YES), the stack pointer is saved (S568). If the output is not finished in S567 (S567: NO), the process returns to S565 for turning off the output ports (0 to 6) (S565).

After S568, the power-off processing completion flag is set (S569), the RWM checksum data is cleared (S570), and the initial data for calculating the RWM checksum is cleared (S571). Also, the RWM checksum is calculated (S572), and it is determined whether or not the calculation for all bytes has been completed (S573). Furthermore, if the calculation for all bytes has been completed (S573: YES), the RWM checksum data is set (S574). Then, access to the RWM is prohibited (S575), and the process is looped to wait for reset (S576).

If the previous power-off detection signal was not ON in S561 (S561: NO) or if the power-off detection signal was not ON in S563 (S563: NO), the process ends. .

Triggers for execution of the power-off process include hardware that generates a non-maskable interrupt (NMI) based on the input of a power-off signal indicating a voltage drop to the NMI terminal (not shown) of the main CPU 81, and an interrupt. There is a software-like process that checks the power-off flag that is set when a voltage drop is detected. Further, a power-off flag may be set based on a power-off signal input to the NMI terminal, and used as a trigger for executing power-off processing.
<<Generate input port data>>

Subsequently, in the input port data generation process, the input ports 0 to 2 are read.
<<Rotating drum drive management>>

In the processing of the above-described reel drive management (S546), drive control of each reel is performed. More specifically, the number of drums is set, and the drum data address setting process is performed. Further, the drum driving control is performed, and when all the drums are finished, the port output processing (S547 in FIG. 18) is performed. In the above processing, if the drum drive control has not been completed for all the drums, the process returns to the drum data address setting process.
<<<Rotating drum drive control>>>

Next, a description will be given of the processing of the above-described spinning drum drive control. In the drum drive control process, it is determined whether or not the drum is stopped, and if it is not stopped, it is determined whether or not it is ready to start rotation. Further, if it is in the state of preparation for starting rotation, the drum drive pulse data retrieval counter is corrected, the acceleration state data is set, and the drum drive state data is set in the update address.

Here, in the process of determining whether or not the spinning drum is stopped, if the spinning drum is not stopped, the process is terminated. Further, in the process of determining whether or not it is in the state of preparation for starting rotation, if it is not in the state of preparation for starting rotation, data of the drive state of the reel is set in the above-mentioned update address without performing the interim processing. process.

After the process of setting data of the driving state of the driving drum in the update address, the driving pulse output counter for driving the driving drum is decremented by 1, and it is determined whether the output counter is 0 or not. Further, when the output counter is 0, drive pulse clear data and stop state data are set, and the four phases of the motor (rotating drum stepping motor) are turned off. Here, if the output counter is not 0 in the process of determining whether or not the output counter is 0, the process is terminated.

Subsequently, it is determined whether or not the motor is decelerating, and if it is not decelerating, the reel drive pulse output counter is incremented by one. Further, it is determined whether or not the rotary drum is in a constant speed state, and if it is in a constant speed state, it is determined whether or not the rotary drum driving pulse data search counter is an even number.

Then, in the process of determining whether or not the drum drive pulse data search counter is an even number, if the drum drive pulse data search counter is an even number, the drum rotation failure detection counter is incremented by 1, and the drum is driven. Handle the pulse update. Further, in the process of judging whether or not the rotary drum is in a state of constant speed, if it is not in a constant speed, or in the process of judging whether or not the rotary drum drive pulse data search counter is an even number, the rotary If the counter for retrieving the drum drive pulse data is not an even number, the processing for updating the drum drive pulse is performed without performing the interim processing.

Subsequently, constant speed state set processing is performed, and it is determined whether or not the vehicle is accelerating. Further, if the vehicle is accelerating, the number of pulse switching times is decremented by -1, and it is determined whether or not the number of switching times is zero. If the number of times of switching is not 0, the data of the reel drive pulse output counter is set to the update address.

Furthermore, data on the number of times of pulse switching is acquired, and a reel rise pattern table is set. Then, the specified address data set is processed, the reel control data set at the update address is updated, and the process ends. In the process of determining whether or not the number of times of switching is 0, if the number of times of switching is 0, the process is terminated without performing the intermediate process.

In the process of determining whether or not the speed is being accelerated, if the spinning drum is not being accelerated, the step number RWM address of one pattern is set, and it is determined whether or not the speed is constant. Further, when the speed is low, a reel sensor signal is acquired, and it is determined whether or not the acquired reel sensor signal is from the reel sensor of the reel to be controlled.

When it is determined in the process of determining whether or not the acquired rotary drum sensor signal is from the rotary drum sensor of the controlled rotary drum, It is determined whether or not the rise of the drum sensor signal has been detected. Further, in the case of the rise of the drum sensor, the reference pattern number at the time of passage of the drum sensor is saved, and the drum rotation failure detection counter is initialized.

Subsequently, the reference step number correction value is set, the reference step number when passing the reel sensor is generated, the reference step number when passing the reel sensor is saved, and the process is terminated. In the process of determining whether or not the acquired reel sensor signal is from the reel sensor of the reel to be controlled, if the acquired reel sensor signal is not from the reel to be controlled , the processing shifts to the above-described processing for acquiring the bobbin sensor signal. Further, in the process of determining whether or not the rising of the drum sensor signal is detected, if the rising of the drum sensor signal is detected, it is determined whether or not the drum sensor has passed. Also, in the process of determining whether or not the vehicle is at a constant speed, it is determined whether or not it has already passed through the reel sensor even when the vehicle is not at a low speed.

In the process of determining whether or not the reel sensor has passed, if the reel sensor has been passed, the number of steps for one symbol is decremented by 1, and it is determined whether or not the symbol has moved by one symbol. In the process of determining whether or not the belt has already passed through the spinning drum sensor, if it has not passed through the spinning drum sensor, the process ends. Furthermore, when the player moves by one symbol, 16, which is the number of steps for one symbol, is saved, and the symbol number is updated.

Further, the step number RWM address of one symbol is set, the symbol number is incremented by 3, and a predetermined division ((symbol number+3)/5) is performed. Also, it is determined whether or not the value of the symbol number +3 is a multiple of 5. If the result of determination is not a multiple of 5, the number of symbol steps is corrected to determine whether the deceleration start symbol position has been reached. make a judgment as to whether

In the process of determining whether or not the value of the symbol number +3 is a multiple of 5, if the determination result is a multiple of 5, the deceleration start symbol is executed without performing the aforementioned correction of the number of symbol steps. Processing is performed to determine whether or not the position has been reached. If the spinning drum has not moved by one symbol in the process of determining whether or not it has moved by one symbol, it is determined whether or not the deceleration start symbol position has been reached without performing intermediate processing. process.

In the process of judging whether or not the deceleration start symbol position has been reached, if the deceleration start symbol position has been reached, the deceleration pulse counter is set, and if the deceleration start symbol position has not been reached, the process ends. . Further, after setting the deceleration pulse counter, the deceleration state is set, the deceleration pulse data is set, the four phases of the motor are turned on, and the rotation state is set. Here, in the aforementioned processing for determining whether or not the motor is decelerating, if the motor is not decelerating, the processing for setting the reel state is performed without performing the intermediate processing.

After the process of setting the spinning drum state, it is determined whether or not the spinning drum state has changed from the start of deceleration to during deceleration. Set the output request. Then, the control command set 2 is processed (referenced) (S649), and the process ends. In the process of determining whether or not the state of the drum has changed from the start of deceleration to during deceleration, if there is no change in the state of the drum, the process is finished without performing the intervening process.
<<Port output>>

In the aforementioned port output processing (S547 in FIG. 18), output ports 0 and 1 are output. More specifically, the data of output port 0 is generated and the data of output port 0 is output. Further, the data for the output port 1 is generated (S663), the data for the output port 1 is output, and the control command transmission processing (S548 in FIG. 18) is performed.
<<Send control command>>

In the above control command transmission process (S548 in FIG. 18), a control command to be transmitted to the peripheral board is output. More specifically, it sets the control command buffer address and acquires the data of the control command read pointer. Furthermore, the specified address is set, and the transmission target control command address is set. Then, the presence or absence of a control command is determined, and if there is an unsent control command, the control command output processing is performed and the control command is output to the output ports 7 and 8 .

Subsequently, with the sub control data strobe signal ON, the output data is output to the output port 2, the transmitted control command storage buffer is cleared, and the control command read pointer is updated. Furthermore, the output data is output to the output port 2 with the sub-control data strobe signal turned off. Then, it outputs clear data (control command clear data) to the output ports 7 and 8, and shifts to the LED display process (S549 in FIG. 18). If there is no control command that has not yet been transmitted (S675: NO), the intermediate process is not performed, and the output data is output to the output port 2 with the sub control data strobe signal turned OFF. process.
<<LED display>>

In the above-described LED display processing (S549 in FIG. 18), the LED display counter is updated, based on the counter value, the LED digit 1 to 5 signals to be output are determined, and the LED digit 1 to 5 signals to be output are determined. If there is a corresponding LED display request, the LED segment A to G signals corresponding to the data to be output are set. When there is no display request, all LED segment A to G signals are turned off. Then, when there is a request to display the LEDs displayed by the LED digit 1 to 5 signals to be output and the LED segment P signal, the LED segment P signal is turned ON, the LED digits and LED segments are output, and the LED digits and LED segments are output. Update the output of the LED segment.

More specifically, output ports 3 and 4 corresponding to the LED digit segment are turned off and the LED display counter is updated. Further, it is determined whether or not the LED display counter is 0, and if the LED display counter is 0, the LED display counter is initialized, and the data of the LED display counter and the LED display request flag are acquired.

In the process of determining whether the LED display counter is 0 or not, if the LED display counter is not 0, the data of the LED display counter and the LED display request flag are acquired without initializing the LED display counter. Furthermore, it sets data relating to confirmation of a segment display request for the digits to be displayed this time, and determines whether or not there is a display request. Then, when there is a display request, the error display data is acquired and the error display data is set.

Subsequently, the 7-segment LED segment table 2 is set and setting data is acquired. Further, it generates set value display data and determines whether or not there is a set value display request. Then, if there is no set value display request, the stored number data is acquired, and the upper digit offset data is acquired.

Furthermore, it determines whether or not there is a request to display the number of stored items (upper digits), and if there is no request to display the number of stored items (upper digits), it determines whether or not there is a request to display the number of stored items (lower digits). conduct. If there is no request to display the stored number of sheets (lower digits) in S707, the setting change device operating display data, acquired number of sheets data, and display data are acquired, and it is determined whether or not an error is displayed. conduct.

Subsequently, in the process of determining whether or not an error is being displayed, if an error is being displayed, the 7-segment LED segment table 1 is set, and offset data for upper digits is acquired. Further, it is determined whether or not there is a request for display of the acquired number (upper digits), and if there is not, the offset data for the lower digits is acquired. Further, it acquires segment output data and determines whether or not there is a display request for a predetermined segment P. FIG.

If there is a segment P display request (S715: YES), the segment P output data is set (S716) and output to the output ports 3 and 4 corresponding to the LED digit segment.

If there is no display request in the process of determining whether or not there is a display request described above, the process proceeds to the process of confirming the display request related to the segment P described above without performing the interim process. In addition, when there is a set value display request in the above-described determination processing as to whether or not there is a set value display request, the processing shifts to segment output data acquisition processing.

Furthermore, if there is a request to display the stored number of sheets (upper digits) in the process of determining whether or not there is a request to display the stored number of sheets (upper digits) described above, the above-described process of acquiring the offset data for the lower digits , and if there is a request to display the stored number of sheets (lower digits) in the above-mentioned process of determining whether or not there is a request to display the stored number of sheets (lower digits), the above-mentioned process of acquiring segment output data Move to In addition, in the above-described process of determining whether an error is being displayed, if the error is not being displayed, the 7-segment LED segment table 1 is not set, and the offset data for the upper digits is acquired.

Furthermore, in the process of determining whether or not there is a request to display the acquired number (upper digits) described above, if there is a request to display the acquired number (upper digits), the process proceeds to the above-described acquisition of segment output data. . Also, if there is no segment P display request as described above, the processing shifts to the above-described processing of outputting to the output ports 3 and 4 corresponding to the LED digit segment.
<<Sub-announcement data output>>

In the sub notification data output process (S550 in FIG. 18) described above, the stop buttons 1 to 3 notification data are set according to the stop acceptance information data in order to output the notification data to be transmitted to the peripheral board. Furthermore, when all the predetermined conditions regarding whether or not the game medal limit (also called the accumulation limit number of coins, here 50 coins) has been reached, etc. are satisfied, the 3 coin insertion button notification data is set. Then, the setting/reset button notification data, the setting key switch notification data, the door switch notification data, and the setting door switch notification data are set according to the input port 0 level data. In addition, the notification data set to the output port 6 is output.

More specifically, stop reception information data is set, and game medal limit check processing is performed. Further, it is determined whether or not the game medal limit has been reached, and if it has not been reached, it is determined whether or not the blocker signal is OFF.

Also, if the blocker is not OFF, a determination is made to confirm the number of stored tokens, and if there is a number of stored tokens, it is determined whether or not game medals have passed. Then, in the process of determining whether or not the game medals have passed, if the game medals have not passed, the 3-insert button notification data is set. Then, setting/reset button notification data, setting key switch notification data, door switch notification data, and setting door switch notification data are set. Subsequently, the notification data set to the output port 6 is output.

When the game medal limit has been reached in the process of determining whether or not the game medal limit has been reached, and when the blocker signal is OFF in the process of determining whether the blocker signal is OFF, to confirm the number of stored coins. If there is no stored number in the determination process of (1), or if passing of the game medals is detected in the determination process of whether or not the game medals have passed, then the process of setting the 3-insert button notification data is performed. First, set/reset button notification data and the like are set.
<<Timer measurement>>

In the above timer measurement process (S551 in FIG. 18), the timer is updated, and 1 is subtracted from all timer RWMs (0 is set if less than 0). More specifically, it sets the measurement start timer address and sets the number of 1-byte timers. Furthermore, it performs countdown processing and sets the next timer address. Subsequently, it is determined whether or not the 1-byte timer measurement has ended, and if it has ended, the number of 2-byte timers is set. In the process of determining whether the 1-byte timer measurement has ended or not, if the 1-byte timer measurement has not ended, the process returns to the countdown process.

After setting the number of 2-byte timers in the process of setting the number of 2-byte timers, the 2-byte timer value is updated and the next timer address is set. Then, it is determined whether or not the 2-byte timer measurement has ended, and if the 2-byte timer measurement has not ended, the above-described processing for updating the 2-byte timer value is returned to.
<<Error Management>>

In the error management described above (see FIGS. 18 and 20), as shown in FIG. 20, it is determined whether or not the rise of the output signal of the selector passage sensor (selector passage sensor signal) is detected (S751). . If the rise of the selector passage sensor signal is detected (S751: YES), the blocker OFF monitor time (approximately 100.57 ms in this embodiment) and the blocker ON monitor time are set (S752). Further, the AF register is saved (S753), the second control is performed, and error check processing is performed (S754). This error check processing (S754) will be described later (see FIG. 38).

When the error check process (S754) ends, the process returns to the first control, and the AF register is restored (S755). Further, it is determined whether or not an error is detected (S756), and if an error is detected (S756: YES), an output request for error detection is set (S757). If it is determined in S751 that the rising edge of the selector path sensor signal has not been detected (S751: NO), the intermediate processing is skipped and the AF register save processing of S753 is performed.

After the output request for error detection is set in S757, the control command set 2 is processed (S758), and the process ends.
<<External signal output data management>>

In the aforementioned external signal output data management processing (S759), output data generation processing for external signals 1 to 5 is performed. Set output data. Further, when the door switch signal or the setting door switch signal is ON, the output data of the external signal 5 is set. If the setting key switch signal is ON and the output time of the external signal 4 at the time of power failure recovery has not elapsed or the error detection flag is output, the output data of the external signal 4 is set.

More specifically, the external signal flag is acquired, and it is determined whether or not the external signal 1 management time has elapsed. If the external signal 1 control time has not elapsed, the external signal 1 output data is set, and it is determined whether or not the door switch signal or the set door switch signal has been turned ON. If it is ON, the output data of the external signal 5 is set, and it is determined whether or not the setting key switch signal is ON.

If the setting key switch signal is not ON, the data of the error detection flag and the output time of the external signal 4 at the time of power failure recovery are checked, and it is determined whether or not all the data are lost. Then, if all the data are not lost, external signal 4 output data setting is performed, and the process proceeds to external signal output processing (S760 in FIG. 18).

In the process of determining whether or not the external signal 1 control time has passed, if the external signal 1 control time has passed, the door switch signal or the set door switch signal is output without setting the external signal 1 output data. It is determined whether or not it has turned ON. Further, if the door switch signal or the setting door switch signal is not ON, it is determined whether or not the setting key switch signal is ON without setting the output data of the external signal 5 .

Further, if the setting key switch signal is ON, the external signal 4 output data setting is performed without performing the interim processing. Further, if all the data are lost in S778, the external signal output processing (S760 in FIG. 18) is performed without performing the above-described external signal 4 output data setting.
<<External signal output>>

In the above-described external signal output processing (S760 in FIG. 18), the output data of the external signals 1 to 5, medal insertion signal and medal payout signal are output.
<<soft random number management>>

In the soft random number management process described above (see S764 in FIG. 18), the soft random number update 2 process is performed.
<Power recovery processing>

Next, referring to FIG. 21, the power recovery process described in the power-on process (see FIG. 12) will be described. This power recovery process is carried out when it is determined that the power failure recovery data is normal (S12: YES) in the above-described power-on process in the main control board 61 (see FIG. 12).

In the power restoration process shown in FIG. 21, the value in the stack pointer is restored to the state at the time of power failure (S311), and the initialization start address and the number of bytes to be initialized are set (S312). Further, the range determined as the RWM initialization target is initialized (RWM initialization 1 (S313)), and the AF register is saved (S314). Then, after shifting to the second control and performing RWM initialization 2 (see FIG. 30), which will be described later, returning to the first control, the AF register is restored (S316).

In the subsequent input port read processing (S317), predetermined input ports (0 to 2) are read, and the input data is updated from the data before the power-off to the latest data. Further, the timer interrupt is activated (S318), and after clearing the data indicating the power-off processing completed flag (power-off execution processing flag) from the RWM (S319), the processing of the timer interrupt generated at the time of power-off is resumed. In the interrupt activation setting process (S318), the type of interrupt and the cycle of the timer interrupt are set. After this processing, the timer interrupt processing can be executed. In this embodiment, the period of timer interrupt is 2.235 ms.

Here, starting the timer interrupt (S318) after reading the input port in the input port read processing (S317) means rewriting the input data to the latest data in the input port read processing (S317) as described above. It is taken into consideration. For example, if the setting key switch 68 was ON when the power was turned off and was OFF before the power was restored, and if there was no input port read processing (S317), the timer interrupt processing is executed. Fall data of the setting key switch 68 is generated by the input port data generation process (see S545 in FIG. 18). Specifically, if the power is turned off during the above-mentioned "display when waiting to insert game medals" (see S55 in FIG. 14) and the setting key switch 68 is changed as described above, the power is turned off. At the time of recovery, an unintended process of shifting from the set value confirmation state to the normal state is executed based on the trailing edge data. Therefore, as described above, after reading the input port (S317), timer interrupt activation (S318) is executed.
<Error type>

Next, among various errors in the slot machine 10 of this embodiment, an error related to the handling of game medals will be described. Errors relating to the handling of game medals include errors that can be recovered after the error is canceled and errors that cannot be recovered. Among these, recoverable errors include HE error, HP error, HQ error, and FE error, which are related to the payout of game medals, and CP errors, which are errors related to the insertion of game medals. There are C0 errors, C1 errors, CH errors and CE errors.

Among the various errors described above, the HE error is an error when it is determined that the game medals in the game medal payout device 63 are empty. This is an error (hopper error) when it is determined that the hopper is clogged. Furthermore, the HQ error is an error when it is determined that there is an abnormal input to the payout sensor (not shown), and the FE error is an error when it is determined that the game medal auxiliary storage 71 is full as described above. .

Also, the CP error is an error when it is determined that the inserted game medals have passed through illegally, and the C0 error is when it is determined that there is an abnormal input to the insertion sensor (insertion sensor 2 in this case) as described above. error. Furthermore, the C1 error is an error when it is determined that there is an abnormality in the portion of the medal passage 105 where the insertion sensor 45 and the selector passage sensor 46 are provided, and the CH error is an error when the selector passage sensor 46 is detected in the game as described above. This is an error when it is determined that medals are stuck. Also, the CE error is an error when it is determined that the game medals have accumulated in the portion provided with the inserted sensor 1 (115) or the inserted sensor 2 (116).

A condition for canceling these errors is that the signal of the setting/reset button 69 (setting/reset button signal) is changed from OFF to ON after removing the cause of the error. Furthermore, when the door switch signal associated with the door switch 60 and the setting door switch signal associated with the setting door switch 67 are ON, the above-described canceling operation becomes effective.

On the other hand, non-recoverable errors include E1 error, E5 error, E6 error, and E7 error. Of these errors, the E1 error is an error when power-off recovery cannot be performed normally, and the E5 error is an error when the symbol combination display is abnormal when all reels are stopped. Furthermore, the E6 error is an error when the setting value is out of range, and the E7 error is an error in the frequency of the clock input to the RCK terminal (not shown) for updating the random number in the main CPU 81, or an internal random number (16-bit random number) is detected as an error in the update status.
<<CP Error (Illegal Passage of Game Medals)>>

Subsequently, detection modes of CP error, C0 error, C1 error, CH error, and CE error, which are errors related to inserting game medals, will be described. First, with respect to the CP error, in the above-described processing for inserting game medals (more specifically, the processing for checking the insertion of game medals, which will be described later), the ON/OFF order of the insert sensors as shown in FIG. It is determined that it has passed, and one game medal is accepted. That is, in FIG. 8(a), the insertion sensor ON/OFF sequence is shown in five stages on the left end. Furthermore, the ON/OFF states of the input sensor 1 signal and the input sensor 2 signal in the stages of each order 1 to 5 are shown on the right side thereof. The input sensor 1 signal and the input sensor 2 signal are normally in an OFF state, and are turned ON when game medals are detected.

When no game medal is detected, as shown in order 1, both the input sensor 1 signal and the input sensor 2 signal are OFF. Then, when a regular game medal enters the game medal entrance 106 of the game medal selector 44 and flows down the medal passage 105, as shown in order 2, the insertion sensor 1 signal located upstream of the medal passage 105 goes first. Then, while the input sensor 1 signal is in the ON state, the input sensor 2 signal is also turned ON as shown in sequence 3. Further, as the game medals flow down, as shown in sequence 4, the input sensor 1 signal is first turned OFF, and then, as shown in sequence 5, both the input sensor 1 signal and the input sensor 2 signal are turned OFF. Become. When the ON/OFF of the input sensor 1 signal and the input sensor 2 signal are detected in this order, the main CPU 81 (see FIG. 5) determines that one game medal has passed normally. . More specifically, the determination result of an error (CH error) of a selector passage sensor arrangement site retention, which will be described later, is also referred to, and when both errors are not detected, the main CPU 81 Judge that the medal passed normally.

In other cases, it is determined that the game medals have been illegally passed, resulting in an error. However, as shown in orders 1 to 3 in FIG. 8(b), when only the input sensor 1 signal is turned ON and detected, and the input sensor 2 signal is not detected, the game medals return to the upstream side. It is treated as a thing, does not cause an error, and invalidates the input of the input sensor 1 signal. The reason why the case shown in FIG. 8B is not treated as an error is that game medals may be detected only by the insertion sensor 1 even when the blockers are OFF. Even in such a case, if an error is reported or the game is stopped, the rhythm of the game played by the player will be disturbed.
<<C0 error (insertion sensor error input)>>

Next, in the C0 error, as shown in FIG. 8(c), the blocker signal, which is data for controlling the blocker (47), is changed from ON (game medal passing state) to OFF (game medal return state). ), and after a predetermined time (about 500.60 ms here) has elapsed, it is determined whether or not there is an input to the input sensor 2 signal while the blocker is OFF (returned state). This predetermined time is an opening sensor abnormal input detection start time, which will be described later, and is a time until detection of an abnormal input related to the opening sensor is started.

Then, after a predetermined time (time to start detecting an abnormal input from the inserted sensor), when the inserted sensor 2 signal is input (becomes ON) even though the blocker signal remains OFF (returned state of game medals). ), it is determined that there is an abnormal input to the input sensor (45), and error monitoring is enabled (ON) as shown in the middle part of the figure. When an error is detected in this manner, the input sensor 2 signal is turned ON until the cause of the error is removed, an error display output request corresponding to the C0 error is made, and the C0 error is displayed at a predetermined timing after that. executed. The timing at which the error display is performed is while waiting for game medals to be inserted, while waiting for acceptance of the start lever, or after all reel rotations have stopped.

However, in this embodiment, while a CE error, CP error, CH error, C0 error, or C1 error has already occurred, the C0 error detection factor as shown in FIG. is not judged to be an abnormal input.
<<C1 error (medal passage error)>>

Next, in the C1 error, as shown in the middle part of FIG. 9(a), when the selector path sensor 46 turns from OFF to ON, the input monitor counter is incremented by 1 as shown in the upper part of the figure. Further, as shown in the lower part of the drawing, when the insertion sensor 2 signal changes from ON to OFF when game medals pass through the insertion sensor 45 normally, the insertion monitoring counter is decremented by one. Then, every time the input sensor 2 signal is switched from ON to OFF in the case of normal input, the input monitoring counter is decremented by 1, and when the input monitoring counter is out of a predetermined range (for example, the range of 0 to 3), will result in an error.

That is, when the input monitoring counter is within a predetermined range, it is determined to be normal, and when it is out of the predetermined range, it is determined to be abnormal. The maximum value (here, 3) of the predetermined range related to the insertion monitoring counter can be determined by the relationship between the distance from the selector passage sensor 46 to the insertion sensor 2 (105) and the size of the game medals. For example, when the distance from the selector passage sensor 46 to the insertion sensor 2 (116) exceeds the diameter of the game medal and is equal to or less than the dimension of two game medals (here, 50 (=25×2) mm) , it is assumed that a maximum of three game medals are lined up between the selector passage sensor 46 and the insertion sensor 2 (116), one game medal in its entirety and one part of two game medals. be done. Therefore, the maximum value of the predetermined range related to the input monitoring counter can be set to 3.

In addition to this way of thinking, for example, in order to make error detection more reliable, the maximum value of the predetermined range related to the input monitoring counter is set to "2", or the error detection accuracy is intentionally relaxed. , it is also possible to set the maximum value to "4". Furthermore, it is possible to set the maximum value to a value other than "3" or "4" according to the distance from the selector path sensor 46 to the input sensor 2 (116). Further, the distance from the selector passage sensor 46 to the input sensor 2 (116) may be set from the most upstream portion of the selector passage sensor 46 to the central portion (optical axis portion) of the microsensor of the input sensor 2 (116). Various settings are possible, such as from the central portion of the sensor 46 to the most upstream portion of the input sensor 2 (116). As will be described later, the input monitoring counter is cleared to 0 when the blocker signal is turned from OFF to ON.
<<CH error (retention in selector passage sensor location)>>

Next, in the CH error, as shown in FIG. 9(b), when the selector passage sensor 46 remains ON for a predetermined time (here, 446.97 ms, which is the selector passage sensor retention time), game medals are awarded. It will be judged as staying and an error will occur. This predetermined time is the retention determination passing time related to the selector passage sensor. When an error is detected, an error display corresponding to the CH error is requested to be output, and the CH error is displayed at a predetermined timing thereafter. The timing at which the error display is performed is while waiting for game medals to be inserted, while waiting for acceptance of the start lever, or after all reel rotations have stopped. However, in this embodiment, when a CE error, CP error, CH error, C0 error, or C1 error has already occurred, the CH error detection factor as shown in FIG. is not judged to be an abnormal input.
<<CE error (injection sensor placement site retention)>>

Next, in the case of the CE error, as shown in FIG. 10, when the game medals are inserted, it is determined that the game medals are accumulated if the retention determination passage time related to the input sensor is outside the range of A to C in FIG. and an error occurs. Here, the time A in the figure is the retention determination passing time from ON to OFF of the input sensor 1, and the time B is the retention determination passing time from ON to OFF of the input sensor 1. Furthermore, the time C is the stay determination passing time from ON to OFF of the input sensor 2 . In this embodiment, each of the residence determination passage times A to C is 4.47 ms ≤ A < 143.03 ms, 2.23 ms ≤ B < 98.33 ms, and 4.47 ms ≤ C < 143.03 ms. .

As a process for error display, when an error display starts or when an error is detected, a detected error display output request is made. Also, an error code corresponding to each error is displayed on the obtained number display LED, and the game is stopped. Here, stopping the game will be described later. Further, as a process for canceling the error, the acquired number display LED is returned to the state before the error, an output request is issued at the end of the error display, and then the game is restarted.
<Control processing related to insertion of game medals>

Next, the above-described control processing for inserting game medals will be described in more detail with reference to FIGS. 22 to 29 and the like. The processing described here is part of a control module (program module) that is executed depending on the situation in the above-described game progress main processing (see FIG. 14) and timer interrupt processing (see FIG. 18). . That is, what will be described here is the first control among the control processes related to the insertion of game medals, and the second control will be described later.

Among the control processes related to the insertion of game medals, those related to the first control include the process of starting accepting game medals (see FIG. 22), the process of turning on blockers (see (a) of FIG. 23), and the process of turning off blockers (see FIG. 23A). 23(b)), error display processing (see FIG. 24), and input error set processing (see FIG. 25).

Among these control modules, the game medal reception start processing, blocker ON processing, blocker OFF processing, and error display processing shown in FIGS. It is executed as required in various types of processing. More specifically, the game medal reception start process is executed in the game start set process (S52) in FIG. This is executed in the display processing (S55) when waiting for the insertion of medals. Then, after the game medal acceptance start process, the blocker ON process (to be described later) is performed, and the blocker 47 described above is turned ON (passable state), and game medals can be inserted.

Furthermore, blocker ON processing, blocker OFF processing, and error display processing are general-purpose processing. ), processing for display when waiting for insertion of game medals (see S55 in FIG. 14), processing for settling game medals (see FIG. 28), etc., may be executed depending on the situation.

The blocker OFF processing includes the display processing when waiting for game medals to be inserted (see S55 in FIG. 14), the game medal settlement processing (specifically, the blocker OFF processing is performed before the game medals are settled). executed), start lever check processing (S58 in FIG. 14), start lever acceptance processing (S59 in FIG. 14), etc., may be executed depending on the situation.

Furthermore, the error display process is executed depending on the situation in the game medal settlement process, the start lever check process (S58 in FIG. 14), the game medal payout process due to winning (S67 in FIG. 14), and the like. Sometimes.

Regarding the control module executed in the timer interrupt process, the data set in the game progress main process (see FIG. 14) (for example, a flag indicating abnormality detection) before the occurrence of the timer interrupt process of that period will be handled. Below, each process mentioned as a control process related to the insertion of game medals will be described, and then the interrelationship between these processes will be described.
<Start accepting game medals>

The game medal reception start process (see FIG. 22) described above is for performing the process at the time of game medal reception start, and the game medal selector 44 (see FIGS. 2, 6, and 7) is in the game medal return state (see FIG. 22). When a predetermined condition is satisfied, the game medal receiving state (passable state) is controlled from the state in which passage is impossible, and game medals can be inserted from the game medal slot 21 (see FIG. 1). We are taking steps to ensure that As shown in FIG. 22, the processing for starting to accept game medals first clears the data on the number of game medals (S101), and then turns off the inserted number display LED (S102). Further, the game medal management flag is initialized (S103), and the operation flag check process (S104) is executed. This operation flag check process (S104) is a process for confirming the presence or absence of operation of the accessory, the accessory continuous actuating device, and the replay.

Then, it is determined whether or not it is time for a replay operation (S105). 23(a)), and if it is a replay operation (S105: YES), set the automatic insertion waiting time 1 (237 interrupt: about 529.65 ms) ( S106). Further, it is determined whether or not the display type data is 0 (S107), and if the display type data is 0 (S107: YES), the processing shifts to 2-byte time waiting processing (S111). This 2-byte time waiting process (S111) is a process of waiting until the designated waiting time (automatic input waiting time 1) becomes zero. Here, the display type data is data indicating the type of the replay combination that is stopped and displayed. Specifically, when a predetermined replay combination in which "replay-replay-replay" is stop-displayed on the active line or the invalid line is stop-displayed, the display type data is 0. On the other hand, on the active line or on the invalid line, a specific replay combination that does not stop and display "Replay-Replay-Replay" (Example: "Bell-Bell-Bell", "Red 7-Red 7-Red 7") is stopped, the display type data 1 is displayed. This display type data is stored in the RWM 83 at the time of winning determination, and is intended to change the time until the automatic insertion process is started based on the symbol combination that is stopped and displayed. For example, when the combination of symbols corresponding to the display type data 1 is stopped, an automatic insertion waiting time 2 (described later) is set, and when waiting for the set 2 byte time, the effect corresponding to the small combination or bonus combination is set. A sound is output so that the player can recognize the established combination as a minor combination or a bonus combination.

Further, in the determination of the display type data (S107), if the display type data is not 0 (S107: NO), the automatic input waiting time 2 (500 interrupt: about 1119.50 ms) is set (S108), The processing shifts to the above-described 2-byte time waiting process (S111).

After the process of waiting for 2 bytes (S111), the process of reading the stored number of sheets is executed (S112). The process of reading the stored number of sheets (S112) reads the stored number of sheets data and checks the presence or absence of storage and the number of stored sheets. Thereafter, it is determined whether or not the stored number of sheets has reached the storage limit number (here, 50 sheets) (S113). Processing (S114) is executed. This blocker ON processing (S114) will be described later. On the other hand, if the stored number of sheets has reached the storage limit number (S113: YES), the blocker ON process (S114) is not performed, and the display type data acquisition process (S116) is performed.

With such a configuration, when the replay is not activated (S105: NO), the blocker ON process can be executed regardless of the number of accumulated coins, and when the replay is activated (S105: YES). Blocker ON processing can be performed according to the number of stored sheets. Therefore, (1) medals can be uniformly inserted even if the stopped symbol combination is a symbol combination that cannot be recognized as a replay, (2) blocker ON processing can be realized with a small amount of program processing, and (3) medals. (4) Even in a game with a high probability of replay, the player can insert medals at a constant rhythm. It can be done, and the like.

After the determination processing (S113) related to the stored number or the blocker ON processing (S114) described above, the display type data is acquired (S116), and it is determined whether or not the display type data is 1 (S117). . If the display type data is 1 (S117: YES), the 3-piece throw display LED-R (red) is lit (S118), and the automatic throw standby time 3 (8949 interrupt: about 19999.49 ms) is set. (S119), and saves the input detection waiting time (S120). Further, the inputs of the selector path sensor signal, the one-sheet insertion switch signal, the three-sheet insertion sensor signal, and the settlement switch signal are checked (S121), and it is determined whether or not these inputs have been received (S122). Here, the lighting of the 3-insert display LED-R (red) (S118) functions as a notification prompting the player to operate the BET (bet) button. If there is any input (S122: YES), the input detection standby time is cleared (S123), and an input information command is set (S124). Here, the input information command refers to a command indicating the state of "selector path sensor signal, 1-sheet throwing switch signal, 3-sheet throwing sensor signal, 3-sheet throwing switch signal". In the above S122, if there is no input (S122: NO), the input information command is set (S124) without clearing the input detection standby time (S123). In other words, the automatic loading standby time 3 is canceled based on the passage of time or the above input information (selector path sensor signal, single-sheet loading switch signal, 3-sheet loading sensor signal, or 3-sheet loading switch signal). By adopting such a control mode, when a replay combination belonging to the display type data 1 is displayed, it is possible to disguise it as a minor combination or a bonus combination.

Subsequently, it is determined whether or not the input detection standby time has passed (S125). If it has not passed (S125: NO), the process returns to S121 to check the input of various signals. If the input detection standby time has elapsed in S125 (S125: YES), the three-sheet insertion display LED is extinguished (S126), and an input information output request is set (S127). In S117 described above, if the display type data is not 1 (S117: NO), the processing of S118 to S126 is not performed, and an input information output request is set (S127). Then, the processing of the control command set 1 is executed (S128). In the present embodiment, the processing of the control command set 1 (S128) is to perform the processing of the control command set 2. FIG. The processing of the control command set 2 is to store the aforementioned sub-control commands in a ring buffer (transmission buffer) that temporarily stores them before transmission. In the subsequent steps, there is a processing step of "set output request", but this is a process of storing information (command) to be transmitted to the sub-control means (sub-control board 31 here) in a register. point to

After that, the replay display LED is turned on (S129), the output request at the time of automatic insertion is set (S130), and the control command set 1 process (S131) which is the same as the above-described S128 is executed. Then, the process of adding one game medal (S132) is executed, and in the process of adding one game medal (S132), the number of game medals is added by one and the display process of the inserted number display LED is performed. More specifically, in the process of adding one game medal (S132), although not shown, 1 is added to the number data of game medals and the display data of the number of acquired medals is cleared. Furthermore, it stores the inserted number display LED signal data corresponding to the game medal number data, performs the game medal limit setting process, and performs the process of reading the game medals. Then, when the game medal number data matches the game medal limit number (previously defined number), the game medal limit flag is set.

After the process of adding one game medal (S132), the game medal limit flag is checked (S133), and if the number of game medals does not reach the game medal limit (S133: NO), one game medal is added. (S132). Then, in S133, if the number of game medals has reached the game medal limit (S133: YES), the process returns to the process that was being executed before the game medal reception start process, which is a subroutine.
<Blocker ON>

Next, blocker ON processing will be described with reference to FIG. 23(a). As shown in FIG. 23(a), this blocker ON processing determines whether or not the blocker OFF monitor time (approximately 100.57 ms in this embodiment) has elapsed (S211). (S211: NO), S211 is repeated until the time elapses. If the blocker OFF monitoring time has passed (S211: YES), the interrupt is prohibited (S212), the blocker signal is turned ON (S213), and the input monitoring counter is cleared (S214). Further, the blocker signal state is turned ON (S215), the interrupt is permitted (S216), and the processing before the blocker ON processing is started is returned to. Here, "blocker signal_ON" in S213 refers to the process of storing "1" in the RWM area for turning on the blocker 47 in this embodiment. In addition, description of "_" is abbreviate|omitted in the figure (the same applies below). By the process of S213, the blocker 47 is turned ON by the port output process (S547) in the timer interrupt process (see FIG. 18) executed after this process. It should be noted that the processing of S213 can be a processing of storing "1" in the output port for directly outputting the blocker signal.

In addition, in S214, "loading monitoring counter_clear" refers to the process of resetting the data in the RWM 83 of the loading monitoring counter that is updated when there is an input from the selector path sensor 46 to 0 in this embodiment. With this process, for example, after the binary data determined to have passed through the selector path sensor 46 is "10B", an error is determined when a game medal insertion check (see FIGS. 42 and 43) is executed, which will be described later. can prevent it from being done. Furthermore, "Blocker signal state_ON" in S215 means storing in the RWM 83 information indicating that medals can be inserted in this embodiment. By the processing of S215, the LED display processing (S75) of the interrupt processing executed after this processing can light up the lamp (game start display LED) indicating that game medals can be inserted. Note that the processing order of S213 to S215 is not limited to this.

The blocker signal ON processing described above (S213) is performed after the blocker OFF monitor time has elapsed (S211: YES). The reason for this is that when there is a possibility that a game medal is passing, the blocker 47 is not turned on, thereby preventing the medal from being caught. That is, as in the present embodiment, by determining whether or not the blocker-OFF monitoring time has elapsed (S211) and then turning ON the blocker signal (S213), the ON operation of the blocker 47 is suspended for a predetermined period. Thus, it is possible to secure the time for waiting for the passage of the game medals until the blocker signal is output from the main control board 61 and the blocker 47 performs a mechanical operation.

In addition, the above-mentioned interrupt prohibition (S212) is executed after waiting for the elapse of the monitoring time when the blocker is OFF (S211). In this embodiment, as described above regarding the C1 error (see FIG. 9A) related to the closing sensor and the selector passage sensor, the value of the closing monitoring counter increases or decreases based on the detection of the selector passage sensor signal and the closing sensor 2 signal. The blocker 47 is turned off when the value of the input monitoring counter exceeds a predetermined range (for example, the range of 0 to 3). Then, in the blocker ON process (see FIG. 23A), the process related to the blocker signal (S213, S215) and the process related to the input monitoring counter (S214) are executed as a series of processes. , matching is achieved between the selector passage sensor signal and the detection result of the closing sensor 2 signal.

Further, when timer interrupt processing (see FIG. 18) occurs between the blocker signal ON processing (S213) and the blocker signal state ON processing (S215), the timer interrupt processing at this time (the interrupt ) (here, S545 for creating input data, S547 for port output, etc.), the blocker 47 can be turned ON (passable state) as described above. However, in the game progress main process (see FIG. 14), the blocker signal ON process (S213) followed by the blocker signal ON process (S215) is not performed. In S549, which is the LED display process, the lamp (game start display LED) indicating that game medals can be inserted cannot be turned on. In other words, a situation may occur in which the game start display LED is not displayed even though the blocker 47 is ON.

However, as in this embodiment, the interrupt is prohibited (S212), and the processing related to the blocker signal (S213, S215) and the processing related to the input monitoring counter (S214) are replaced by the timer interrupt processing (see FIG. 18). By executing the process as a series of processes that do not intervene, the operation of the blocker 47 can be matched with the LED display, making it possible to appropriately control the insertion of game medals.
<<Blocker OFF>>

Next, blocker OFF processing will be described with reference to FIG. 23(b). As shown in FIG. 23(b), this blocker OFF processing determines whether or not the blocker signal is OFF (S221), and if the blocker signal is not OFF (S221: NO), interrupts are prohibited. (S222), the blocker signal is turned off (S223), and the blocker signal state is turned off (S224). Furthermore, for the C0 error, the above-mentioned input sensor abnormal input detection start time (approximately 500.60 ms in this embodiment) is set (S225), interrupts are permitted (S226), and processing before the blocker OFF processing is started. return. Here, "blocker signal_OFF" in S223 refers to the process of storing "0" in the RWM area for turning on the blocker 47 in this embodiment. By this process, the blocker 47 is turned off by the port output process (S547) in the timer interrupt process (see FIG. 18) executed after this process. It should be noted that the processing of S223 can be a processing of storing "1" in the output port for directly outputting the blocker signal.

Furthermore, "Blocker signal state_OFF" in S224 means storing in the RWM 83 information indicating that medals cannot be inserted in this embodiment. By this process, the lamp (game start display LED) indicating that game medals can be inserted is kept turned off. Further, in S225, a predetermined time (approximately 500.60 ms in this embodiment) related to the C0 error is set in the input sensor abnormal input detection start time setting.

Also, in the blocker OFF process (see FIG. 23(b)), the setting of the input sensor abnormal input detection start time (S225) prohibits interrupts (S222), the blocker signal OFF (S223), the blocker signal It is performed following each processing of state OFF (S224). That is, in the blocker OFF process, the process related to the blocker signal (S223, S224) and the input sensor abnormal input detection start time setting (S225), which is the process related to the input error check, are executed as a series of processes.

Also, when a timer interrupt (see FIG. 18) occurs between the blocker signal OFF (S223) and the blocker signal state OFF (S224), a predetermined As described above, the blocker 47 can be turned off (returned state) through processing (here, S79 for creating input data, S82 for port output, etc.). However, in the game progress main process (see FIG. 14), the blocker signal OFF process (S223) followed by the blocker signal OFF process (S224) is not performed. In S75), which is the LED display process, the lamp (game start display LED) indicating that game medals can be inserted cannot be reliably turned off. In other words, a situation may occur in which the game start display LED is lit even though the blocker 47 is turned off.

However, as in the present embodiment, the interrupt is disabled (S222), and the blocker signal OFF (S223) and blocker signal state OFF (S224) are performed as a series of processes without intervening timer interrupt processing (see FIG. 18). By executing this, it is possible to match the operation of the blocker 47 with the LED display, and appropriate control relating to the insertion of game medals becomes possible.
<<Error display>>

Next, error display processing will be described with reference to FIG. As shown in FIG. 24, the error display process stores the error number (S231) and saves the state information related to the pre-error blocker signal and the hopper motor drive signal (S232). When saving the status information, data is saved from the status information storage areas (blocker signal data storage area, hopper motor drive signal data storage area) in the RWM 83 to a predetermined storage area (C register serving as the status information save area). executed. Furthermore, the information in the hopper motor drive signal data storage area in the state information storage area is cleared (S233), and blocker OFF processing (S234) is executed. This blocker OFF processing (S234) is to perform the aforementioned blocker OFF processing (see FIG. 23(b)). Then, the start lever acceptance permission flag is cleared (S235), the information indicating the number of obtained coins is saved (S236), and an error display is set (S237). When saving the obtained number display information, the data is saved from the obtained number display information storage area in the RWM 83 to a predetermined storage area (the B register serving as the obtained number display information saving area).

Further, an output request at the start of error display is set (S238), the processing of control command set 1 is executed (S239), and the rise of the setting/reset button signal (set button signal or reset button signal) is detected. (S240). In S240 described above, if the rising edge of the setting/reset button signal is not detected (S240: NO), S240 is repeated until the rising edge of the setting/reset button signal is detected. S240: YES), clear the set/reset button signal rise data (S241).

Subsequently, full detection signal inspection data is set (S242), and it is determined whether or not the aforementioned FE error related to payout of game medals has occurred (S243). In S243, if it is determined that the FE error is not occurring (S243: NO), the payout inspection data is set (S244), and it is determined whether or not the payout-related error is occurring (S245). When it is determined that it is not a payout-related error (S245: NO), the inspection data of the input sensor and the selector path sensor are set (S246), and the input state for each error is checked by the inspection data (S247). . Specifically, it corresponds to the process of confirming the level data of the input sensor 45 (input sensors 1 and 2), the level data of the selector path sensor 46, and the level data of the payout sensor (not shown). If it is determined at S243 that there is an FE error (S243: YES), and if it is determined that there is a payout-related error at S245 (S245: YES), the above-described processing is not performed. to S247.

After S247 described above, it is determined whether or not the cause of the error has been removed (S248). If the cause of the error has not been removed (S248: NO), the process returns to S240 described above, and the setting/reset button signal rises. is detected. "Elimination of error factors" in this embodiment means that the level data of the various sensors described above is "0". If the cause of the error has been removed (S248: YES), the error number is cleared (S249), the acquired number display is restored (S250), and an output request at the end of the error display is set (S250). Further, the processing of the control command set 1 is executed (S252), the state information of the blocker signal and the hopper motor drive signal before the error is restored (S253), and the hopper motor drive signal is restored (S254). Then, it is determined whether or not the blocker signal before the error was ON (S255), and if it was ON (S255: YES), blocker ON processing (S256) is executed, and error display processing is started. Return to previous processing. On the other hand, if the blocker signal before the error is not ON (S255: NO), the process returns without executing the blocker ON process (S256).
<<Input error set>>

Next, the input error set processing will be described with reference to FIG. As shown in FIG. 25, this input error set process updates an abnormal input flag (also called "abnormal occurrence flag", "error flag", etc.) (S301). In S301, although not shown, the data stored in the A register is saved in the D register. Furthermore, the data stored in the A register and the data stored in the E register are logically operated (OR), and the operation result is stored in the A register. Then, the value of the A register is stored (updated) in the abnormal input data storage area provided at a predetermined address of the RWM 83 .

In other words, S301 executes a process of storing the abnormal input flag data stored in the abnormal input data storage area of the RWM 83 in the A register. Here, the abnormal input flag in this embodiment is composed of 1-byte data, bits D0 to D3 are not used, bit D4 is selector passage sensor retention, bit D5 is input sensor 2 abnormal input, and bit D6 is output sensor abnormal input. , and the D7 bit is unused. For example, when only selector passage sensor stagnation is detected, the abnormal input flag is "00010000B". Further, when an abnormality of the payout sensor is detected after the selector passage sensor retention is detected, the abnormality input flag becomes "01010000B".

In S301 described above, the abnormal input flag data is used to create data indicating whether or not to transmit (data for determining whether or not to issue an output request), and a command for transmitting (control commands) are created. That is, in creating data to determine whether or not to transmit, the value of the D register is stored in the A register. Then, a logical operation (AND) is performed on the A register and the E register, and the operation result is stored in the A register. For example, if the value of the A register is "01000000B" and the value of the E register is "00010000B", the value of the A register after logical operation (AND) is "00000000" (Example 1). Also, for example, if the value of the A register is "01010000B" and the value of the E register is "00010000B", the value of the A register after logical operation (AND) is "00010000B" (example 2). .

On the other hand, when creating a command for transmission, a logical operation (XOR) is executed between the A register and the E register, and the operation result is stored in the A register. For example, if the value of the A register is "00000000B" as in example 1 above, and the value of the E register is "01000000B", the value of the A register after the logical operation (XOR) will be "01000000B". . Also, for example, if the value of the A register is "00010000B" as in example 2 above, and the value of the E register is "00010000B", then the value of the A register after the logical operation (XOR) is "00000000B". ”.

Subsequently, it is determined whether or not an abnormal input error is detected (S302). The determination made in S302 is to check whether or not the abnormal input flag updated in S301 is new (whether or not it is duplicated). Such an inspection is performed by determining whether or not the data stored in the target storage area (abnormal input flag storage area) of the RWM 83 is the same before and after updating. More specifically, when the value of the A register is "0", that is, the Z (zero flag) is "=1", NO is determined, and the value of the A register is other than "0", that is, the Z (zero flag) ) is "≠1", the determination is YES.

Then, if a new abnormal input error is detected (S302: YES), an output request at the start of error display is set (S303). In this S303, a predetermined value (=01H) is stored in the D register. Then, the processing of the control command set 1 is performed. The control command set 1, which is the destination of the input error check, performs the processing of the control command set 2 as described above. Here, the processing of the control command set 2 is to perform the processing for storing the above-mentioned sub-control commands in the transmission buffer. This control command set 1 (control command set 2) makes it possible to transmit information such as the type of error to the sub-control board 31. FIG. Also, in the above S302, if an abnormal input error has already been detected (S302: NO), the process returns to the original process.
<Relationship between blocker operation control and other processing>
<<Relationship with Replay>>

Next, the relationship between the processing for operating the blocker 47 described above and other processing will be described. First, here, the relationship between the aforementioned blocker ON processing (see FIG. 23(a)) and the replay will be described. First, as described above, the blocker 47 (see FIG. 7) is in a state in which game medals can pass when it is ON, and is in a state in which game medals are returned when it is OFF. The progress main process (see FIG. 14) is executed using the blocker ON process shown in FIG. 23(a).

After the blocker ON processing described above, the drive signal is input to the blocker 47, and until the blocker 47 performs the mechanical operation, the port output processing (S547) in the timer interrupt processing (see FIG. 18) and the , control command transmission processing (S548) is required. Timer interrupt processing occurs at predetermined intervals (here, 2.235 ms). Therefore, even if the blocker signal ON data is set in the blocker ON process (see FIG. 23(a)) (S213), a timer interrupt occurs after that, and the blocker 47 can actually pass the game medals. It will be accompanied by a delay in control and mechanical operation until it becomes. After setting the ON data of the blocker signal until the blocker 47 actually closes the second exit 108 (see FIG. 7), the blocker 47 is in the ON state in the game progress main processing, but the blocker 47 is in the OFF state. It can be said that the situation is such that

Further, the selector path sensor 46 (see FIG. 7) is capable of detecting the passage of game medals as described above, and is arranged upstream of the insertion sensor 45 and the blocker 47 (on the upstream side of the medal path 105). ing. Determination regarding the presence or absence of passage of game medals using the selector path sensor 46 can be made before the game medals reach the insertion sensor 45 or the blocker 47 . Furthermore, the first movable portion 112 and the second movable portion 114 of the selector passage sensor 46 project into the medal passage 105, thereby preventing the game medals from flowing backward.

Then, when the start lever 25 is operated, the blocker 47 is turned off and the medals are returned. Data for turning off the blocker signal is stored in the area (blocker signal data storage area). Here, whether or not the start lever 25 is operated is determined in S59 of the game progress main process (see FIG. 14). (Not shown) and description of such processing are omitted.

In this embodiment, as shown in FIG. 22 during the game medal reception start process, it is determined in S105 whether or not it is time for a replay operation. Further, if it is the replay operation (S105: YES), processing for reading the number of stored coins (S112) and determination of whether or not the number of stored coins has reached the limit number of stored coins (S113) are performed. Then, if the stored number of sheets has reached a specific value (here, 50) that is the storage limit number of sheets, blocker ON processing (S114) is executed.

In the blocker ON processing (S114), as shown in FIG. 23A, it is determined whether or not the blocker OFF monitoring time has elapsed (S211). Thus, in this embodiment, it is set to approximately 100.57 ms, and the time is measured based on the timer data stored in the RWM 83 blocker-off monitoring time storage area. This blocker-OFF monitoring time substantially matches the time required to execute the timer interrupt period (here, 2.235 ms) a predetermined number of times (here, 50 times).

Then, if the blocker OFF monitor time has elapsed (S211: YES), the interrupt is prohibited (S212), and data for turning on the blocker signal is stored in the blocker signal data storage area of the RWM 83 ( S213). Further, through the aforementioned clearing of the input monitoring counter (S214) and setting of the blocker signal ON flag (S215), the interrupt is permitted (S216), and the process returns to the process before the start of the blocker ON process. Then, in the timer interrupt (see FIG. 18) that occurs at the timing after this interrupt permission (S216), the blocker 47 is mechanically driven through processing such as port output (S82), and insertion of game medals can be accepted. becomes.

On the other hand, if it is not during the replay operation (S105 in FIG. 22: NO), blocker ON processing shown in FIG. A series of processes from monitoring the monitoring time during OFF (S211) to interrupt permission (S216) are executed. In this way, by performing the processing of S113 and the like at the time of replaying, it is possible to accept insertion of game medals according to the state of the accumulated number of coins even at the time of replaying.

In this embodiment, in timer interrupt processing (see FIG. 18), input detection processing related to selector path sensor 46 and operation information output processing for operating blocker 47 based on blocker ON signal data and blocker OFF signal data are performed. is being done. That is, the input detection processing based on the selector path sensor signal is performed by the input port data generation processing (S545) of the timer interrupt processing and the error check processing of the second control (see FIG. 38) described later. is performed in the control command transmission process (S548) of the timer interrupt process. These input detection processing and motion information output processing are executed at timing corresponding to the control situation at that time in the timer interrupt processing based on the data set in the game progress main processing.

In the blocker OFF process (see FIG. 23B) for turning the blocker 47 OFF (returned state), the start time for detection of abnormal input from the insertion sensor is set (S225) as described above. The start time of detection of abnormal input from the closing sensor is set to approximately 500.60 ms in this embodiment. This starting time for detection of abnormal input from the closing sensor substantially coincides with the time (time required for 224 interrupts) required to execute the aforementioned timer interrupt period (here 2.235 ms) a predetermined number of times (here 224 times). there is Then, the abnormal input related to the closing sensor is detected after waiting for the passage of the closing sensor abnormal input detection start time.

According to the control mode relating to the replay as described above, it is possible to prevent the pinching of the medals by not turning on the blocker 47 when there is a possibility that the game medals are passing. That is, in the portion of the medal passage 105 near the selector passage sensor 46 and the blocker 47, the presence of the bent portion 110 (see FIG. 7), the eccentricity between the adjacent game medals, and the blocker 47 being turned ON. There is a possibility that the game medals are interlocked with each other due to the influence of the timing or the like, and the game medals are pinched.

In particular, for example, when the player continuously inserts game medals into the game medal slot 21 (see FIG. 1) from the end of one game to the start of the next game, the medal passage 105 It is difficult to secure a gap between the game medals, and when the blocker 47 is turned on, the engagement of the game medals depends on the balance of elements such as the positional relationship of the plurality of game medals and the force applied to the game medals by the blocker 47. may occur.

However, as in the present embodiment, by turning on the blocker signal (S213) after determining whether or not the blocker-off monitoring time has elapsed (S211), the ON operation of the blocker 47 is suspended for a predetermined period. Thus, it is possible to secure the time to wait for the passage of the game medals until the blocker signal is output from the main control board 61 and the blocker 47 performs a mechanical operation. Then, it is possible to prevent game medals from being caught.

Also, when the blocker 47 is turned off (returned state) as in the case of operating the start lever 25, after waiting for the start time (500.60 ms) to start detecting abnormal input from the closing sensor as described above, An abnormal input associated with the input sensor is detected. Therefore, the blocker 47 is turned off substantially at the same time as the game medals are normally detected by the insertion sensor 45, etc., and the normally counted game medals are returned from the game medal payout opening 16. can be prevented from occurring.

Further, when the blocker 47 is turned off (returned state), as described above, by setting the blocker signal OFF data in the RWM 83 and making an output request, timer interrupt processing ( 18) causes the blocker 47 to perform a mechanical action to bring it into the return state. However, if the abnormal input inspection by the input sensor 2 is started immediately after the blocker signal OFF data is set, the blocker 47 is still in the ON state (passable state) and the blocker 47 reaches just before the input sensor 2. A game medal that has been played may be detected by the inserted sensor 2 after that. Then, even though the passage of such game medals is normal, it is determined that an abnormality has occurred in the insertion sensor 2 .

In view of this situation, as in the present embodiment, the determination of the abnormal input related to the closing sensor 45 is performed after the opening sensor abnormal input detection start time of about 500 ms from the timing of the blocker OFF data set becomes effective. As a result, it is possible to prevent the passage of normal game medals from being judged to be abnormal, and it is possible to more accurately judge the occurrence of an error.
<<Interrupt prohibition processing in blocker ON/OFF processing>>

As described above, in the blocker ON process (see FIG. 23A), after waiting for the blocker OFF monitoring time to elapse (S211), interrupts are prohibited (S212). In this embodiment, as described above regarding the C1 error (see FIG. 9A) related to the closing sensor and the selector passage sensor, the value of the closing monitoring counter increases or decreases based on the detection of the selector passage sensor signal and the closing sensor 2 signal. The blocker 47 is turned off when the value of the input monitoring counter exceeds a predetermined range (for example, the range of 0 to 3). Then, in the blocker ON process (see FIG. 23(a)), the process related to the blocker signal (S213, S215) and the process related to the input monitoring counter (S214) are executed as a series of processes. The operation of the blocker 47 is matched with the detection results of the selector passage sensor signal and the input sensor 2 signal.

Also, in the blocker OFF process (see FIG. 23(b)), the setting of the input sensor abnormal input detection start time (S225) prohibits interrupts (S222), the blocker signal OFF (S223), the blocker signal It is performed following each processing of state OFF (S224). That is, in the blocker OFF process, the process related to the blocker signal (S223, S224) and the input sensor abnormal input detection start time setting (S225), which is the process related to the input error check, are executed as a series of processes. This ensures consistency between the operation of the blocker 47 in the return state and the error check.

In the present embodiment, in the timer interrupt processing (see FIG. 18), input detection processing related to the selector path sensor 46, addition processing of the count value of the input monitoring counter, and blocker ON signal data and blocker OFF signal data. Operation information output processing for operating the blocker 47 is performed based on this. That is, the input detection processing based on the selector passage sensor signal is performed by the input port data generation processing (S545) of the timer interrupt processing and the error check processing of the second control (see FIG. 38) described later. The process of adding the count value of the counter is performed in the error check process (see FIG. 38) of the error management in the timer interrupt process (see FIG. 20). The process is performed in the control command transmission process (S548) of the timer interrupt process. These input detection processing, input monitoring counter update processing, and operation information output processing are performed at timing according to the control situation at that time in the timer interrupt processing based on the data set in the game progress main processing. executed.

Here, the relationship between the processing for updating the count value of the insertion monitoring counter in the game progress main processing and the processing for updating the count value of the insertion monitoring counter in the timer interrupt processing is limited to the correspondence relationship between addition and subtraction described above. is not. For example, the count value of the insertion monitoring counter may be incremented in the game progress main processing, and the count value of the insertion monitoring counter may be decremented in the timer interrupt processing. In this case, for example, the initial value of the count value of the insertion monitoring counter is set to "3" or more, the initial value is subtracted by timer interrupt processing, and the count value of the insertion monitoring counter is set in the game progress main processing. is added to the count value to determine whether or not the count value is within the normal range.
<<Relationship with setting key switch operation>>

Next, the relationship between the processing for operating the blocker 47 and the setting key switch operation will be described. First, in the process of waiting for insertion of game medals, when the setting key switch signal is ON, that is, the data of the setting key switch signal in the predetermined area (setting key switch signal data storage area) of the RWM 83 indicates ON. 23B, blocker OFF processing shown in FIG. 23B is executed. Data for turning off the blocker signal is stored in a predetermined area (blocker signal data storage area) in the RWM 83 .

Subsequently, the setting display LED 66 (see FIG. 4) for displaying the setting value is enabled. At this time, in the process (S55 in FIG. 14) when waiting for game medals to be inserted, each process of turning on the setting display LED from the setting of the output request at the time of setting value display start is executed. Further, when the data stored in the setting key switch signal data storage area of the RWM 83 indicates OFF, blocker ON processing is executed. Here, the case where the data stored in the setting key switch signal data storage area is OFF means the case where data is stored at the falling edge of the setting key switch signal.

Then, as described above, if the blocker OFF monitoring time has elapsed (S211: YES), the subsequent series of processing (S212 to S216) is performed, and in S213, data for turning on the blocker signal is to set. The input data related to the setting key switch and the trailing edge data generation processing are performed in the input port data generation processing (S545) of the timer interrupt (see FIG. 18). Therefore, in this case as well, it is possible to prevent medals from being caught by not setting the ON data of the blocker signal while there is a possibility that the game medals are passing.

Further, in the present embodiment, in the timer interrupt processing (see FIG. 18), based on the input detection processing related to the selector passage sensor 46, the input detection processing related to the start lever 25, and the blocker ON signal data and blocker OFF signal data. Operation information output processing for operating the blocker 47 is performed. That is, the input detection processing based on the selector passage sensor signal and the input detection processing based on the start lever sensor signal are performed by the input port data generation processing (S545) and the input error check processing (S83) of the timer interrupt processing. , the drive data output process for operating the blocker 47 is performed in the control command transmission process (S548) of the timer interrupt process. These input detection processing and motion information output processing are executed at timing corresponding to the control situation at that time in the timer interrupt processing based on the data set in the game progress main processing.

According to the control mode described above, it is possible to accurately perform cooperation between the setting key switch operation and the blocker operation, and it is possible to appropriately perform the blocker operation control when the setting key switch is operated.
<<Relationship with error handling>>

Next, the relationship between processing for operating the blocker 47 and error processing will be described. What will be explained here is an example of processing when the above-mentioned CE error (see FIG. 10) occurs. 7) is an error when it is determined that the game medals have accumulated.

First, in the game progress main process (see FIG. 14), if the input sensor 1 signal or the input sensor 2 (116) is continuously detected for a predetermined time or longer, it is determined that game medals are stuck (CE error). Here, the predetermined time related to determination of game medal retention is approximately 143.03 ms, which is the upper limit value of retention determination passage times A and C described above. 24, the error number is saved (S231), and the state information relating to the pre-error blocker signal and the hopper motor drive signal is saved (S232). Further, after the hopper motor drive signal is turned off (S233), blocker-off processing (S234) is executed, and as shown in FIG. 23(b), data for turning off the blocker signal is set in S223. .

Subsequently, when the cause of the error is removed (S248: YES), the blocker signal before the error is returned through processing such as clearing the error number (S249) and restoring various information (S250, S253, S254). It is determined whether or not it is ON (S255). If the blocker signal was ON before the error (S255: YES), the blocker ON processing (S256) is executed, and after waiting for the elapse of the blocker OFF monitor time (S211), the blocker signal is turned ON. Data for turning ON is stored (S213). Therefore, in this case as well, it is possible to prevent medals from being caught by not setting the ON data of the blocker signal while there is a possibility that the game medals are passing.

In this embodiment, in timer interrupt processing (see FIG. 18), input detection processing related to selector path sensor 46 and operation information output processing for operating blocker 47 based on blocker ON signal data and blocker OFF signal data are performed. is performed by timer interrupt processing (see FIG. 18). That is, the input detection processing based on the selector path sensor signal is performed by the input port data generation processing (S545) of the timer interrupt processing and the error check processing of the second control (see FIG. 38) described later. is performed in the control command transmission process (S548) of the timer interrupt process. These input detection processing and motion information output processing are executed at timing corresponding to the control situation at that time in the timer interrupt processing based on the data set in the game progress main processing.

According to the control mode described above, it is possible to accurately perform cooperation between error processing and blocker operation, and to appropriately perform blocker operation control when an error occurs.
<<Game medal management processing>>

Next, the game medal management process described above (see S56 in FIG. 14) will be described with reference to FIG. This game medal management process is a process that shifts to when there are game medals (S54: YES) by checking the presence or absence of game medals (S54) in the above-described game progress main process (see FIG. 14).

In the game medal management processing shown in FIG. 26, game medal insertion and settlement processing are managed. More specifically, it is determined whether or not data has been set to turn on the blocker 47 (a state in which game medals can be passed) (S321). Here, it is confirmed whether or not the blocker 47, which is the channel switching portion of the game medal selector 44 for receiving or ejecting the manually inserted game medals, is in the accepting state (medal channel formation state).

If the data for turning on the blocker 47 has been set (S321: YES), it is checked whether or not the input sensor signal is ON (S322), and it is determined whether or not game medals have been inserted. . This determination of whether or not the insertion of game medals has been detected is for determining whether or not actual game medals have been detected by the aforementioned insertion sensors 115 and 116, and whether or not there is a bet setting (bet). This process is different from the above-described S54 (see game progress main process in FIG. 14).

Here, even if only the inserted sensor 2 (116) located downstream of the medal passage 105 detects the game medals among the inserted sensor 1 (115) and the inserted sensor 2 (116), the game medals are detected. (S322: YES). Then, if the insertion of game medals is detected (S322: YES), the process of checking the insertion of game medals in the second control for executing the insertion process such as determining whether or not the insertion of game medals is appropriate (Fig. 42, 43) is executed. That is, when both the blocker signal and the input sensor signal are ON (S321: YES, S322: YES), the game medal insertion check (FIGS. 42 and 43) is performed.

On the other hand, if it is determined in the blocker state confirmation process (S321) that the blocker ON data is not set (S321: NO) or if the insertion of game medals is not detected (S322: NO), the game Without executing medal insertion check processing (see FIGS. 42 and 43), it is determined whether or not it is possible to accept the operation of the bet button and the settlement button 74 in the main input section 26 (see FIG. 1) (S323). . Determination of whether or not this button operation can be accepted (S323) is to determine whether or not various bet buttons or the settlement button 74 are in an acceptable state. Then, it is determined that it is not acceptable when the start lever 25 is being operated or when any of the stop buttons (24L to 24R), which are other buttons, is being operated.

If the various bet buttons described above or the settlement button 74 cannot be accepted (S323: NO), exit the game medal management and return to the original processing. Also, if the operation can be accepted (S323: YES), it is determined whether or not the operation has been accepted (S324). Determination (S324) as to whether or not the button operation has been received is a process for inserting in response to the button operation. Specifically, it is determined whether or not the number of bets has already reached the upper limit, and whether or not the operated insertion button is the above-described 1 BET button (one insert button 75). If it is a 1 BET button (1 insert button 75), 1 card data is set, and if it is not a 1 BET button (1 insert button 75), it is determined as the aforementioned MAXBET, and the specified number of the next game is bet. Number setting Set the number of sheets to be set. Then, it is determined whether or not the scheduled number of bets to be set is greater than the number of stored medals (the number of stored medals) indicating the number of stored medals. . Further, a control command indicating that the input button has been pressed is set, and the number of bets set to 1 and the reserved number subtracted by 1 are repeated for the number of times corresponding to the number of bets to be set.

In the process of determining whether or not the button operation has been accepted (S324), if the operation has not been accepted (S324: NO), the process exits game medal management and returns to the original process. On the other hand, if the operation has been accepted (S324: YES), it is determined whether or not the settlement button 74 is ON (S325), and if the settlement button 74 is not ON (S325: NO), storage input processing described later (See FIG. 27). Also, if the settlement button 74 is ON (S325: YES), game medal settlement processing (S326) for performing settlement in accordance with the operation of the button is executed, and the original processing is returned to.

More specifically, when the signal of the settlement button 74 (settlement switch signal) is turned from OFF to ON, the signal to the game start display LED (game start display LED signal) is turned OFF, and game medal settlement is performed. It shifts to processing (S326). Also, when the above-described one-card insertion switch signal or three-card insertion sensor signal is changed from OFF to ON, the game start display LED signal is turned OFF, and the system shifts to storage insertion. If at least one of S321 and S322 results in a negative determination (NO) and S323 or S324 also results in a negative determination (NO), the game medal management process is terminated.

FIG. 28 more specifically shows the content of the game medal settlement process (S326) described above. In this game medal settlement process, the operation flag is checked (S371), and it is determined whether or not the replay operation is in progress (S372). The presence or absence of medals is confirmed (S373), and if there are game medals for which the number of bets has been set (S373: YES), blocker OFF data is set (S374), and the medal path 105 of the game medal selector 44 (see FIG. 6) is set. ) is set to the state where it cannot be turned on. Then, a settlement start command is set as a control command (S375).

Further, the number of game medals for which the number of bets is set is read (S376), and settlement processing is performed one by one up to the number of medals for which the number of bets is set. Here, every time one game medal is paid out, the number of bets (number of bets) is decremented by 1 (S377), the number of game medals set as the number of bets is read (S378), and the settlement for the number of bets is completed. It is determined whether or not it has been done (S379). Then, if settlement for the number of bets has been completed (S379: YES), the game medal limit flag is cleared (S380). This game medal limit flag is a flag used for prohibiting acceptance of the insertion button.

Subsequently, a settlement end command is set as a control command (S381), blocker ON data is set (S382), and the medal passage 105 (see FIG. 6) of the game medal selector 44 is returned to the insertable state. Then, the game medal settlement process is terminated, and the original process is returned to. In determining whether or not settlement for the number of bets has been completed (S379), if settlement for the number of bets has not been completed (S379: NO), the process returns to reading the number of bets (S376), and The processing of S376 to S379 is repeated until the settlement is completed.

On the other hand, when it is determined that the replay is not in operation (S372: NO) in the determination of whether or not the replay is in operation (S372), or the presence or absence of game medals for which the number of bets is set is confirmed (S373). ), if there are no game medals for which the number of bets has been set (S373: NO), a process of reading out the accumulated number of medals (S383) is executed. Then, it is determined whether or not there is a reserve number (S384), and if there is no reserve number (S384: NO), the game medal settlement process is terminated and the process returns to the original process.

In the above confirmation of the presence or absence of accumulated game medals (S384), if there are accumulated game medals (S384: YES), blocker OFF data is set (S385), and the game medal selector 44 is turned off. The medal passage 105 (see FIG. 6) is placed in a non-insertable state. Then, a settlement start command is set as a control command (S386). The blocker OFF data set (S385) and the settlement start command set (S386) can be the same processing as the aforementioned S374 and S375.

Further, the number of stored game medals is read (S387), and settlement processing is performed one by one up to the number of stored game medals. Here, every time one game medal is paid out, the accumulated number is decremented by 1 (S388), the remaining accumulated number is read (S389), and it is determined whether or not settlement for the accumulated number has been completed. (S390). Then, if the settlement for the number of stored coins has been completed (S390: YES), the aforementioned settlement end command is set (S381), the blocker ON data is set (S382), the game medal settlement processing is completed, Return to original processing.

In the determination of whether or not the settlement for the number of reserves has been completed (S390), if the settlement for the number of reserves has not been completed (S390: NO), the process returns to reading the number of reserves (S387). The processing of S387-S390 is repeated until the settlement is completed.
<<Storage input processing>>

Next, the above-described stored and charged process will be described with reference to FIG. 27 . In the above-described game medal management process (see FIG. 26), the accumulation-throwing-in process shifts to when the settlement button 74 is not ON (S325: NO) by determining whether or not the settlement button 74 is ON (S325). It is a process to

In the storage insertion process shown in FIG. 27, it is determined whether or not the game medal limit flag is set (S331), and if the game medal limit flag is set (S331: YES), the storage insertion process. and return to the original processing in the game progress main processing. If the game medal limit flag has not been set (S331: NO), the process of setting the number of required inserts (S332) is executed. In this setting of the requested number of bets (S332), "1" is set as the requested number of bets, and when the rise of the MAXBET switch signal is detected, the upper limit of the bet amount and the currently set bet amount are determined. The difference is set as the requested number of input sheets.

Subsequently, a stored number read process (S333) is performed, and it is determined whether or not there is a stored number of game medals (S334). Then, if there is a stored number of coins (S334: YES), the stored insertion process is finished, and the process returns to the original process in the game progress main process. If there is no accumulated number of medals (S334: NO), the rise data of the input switch signal is cleared (S335), and the relationship between the accumulated number of game medals and the number of requested insertions is determined (S336). Then, if the number of stored game medals is not equal to or greater than the number of required insertions (S336: NO), the value of the number of stored game medals is set to the number of required insertions (S337), and the process proceeds to the process of adding one game medal (S338). . At S336 described above, if the number of stored game medals is greater than or equal to the number of insertion requests (S336: YES), the process proceeds to the process of adding one game medal (S338) without setting the value of the stored number of game medals (S337). Transition.

In the process of adding one game medal (S338), "1" is added to the number of bets. After that, processing for clearing the display of the number of wins (S339) is executed, processing for displaying the number of bets (S340) is executed, and reading of the specified number and the number of game medals (S341) is executed. Further, a determination process (S342) relating to the limit of the number of game medals is executed, and it is determined whether or not the number of bets has reached the upper limit. Then, if the number of bets has reached the upper limit (S342: YES), the game medal limit flag is set (S343), and the process proceeds to the process of reading the accumulated number of medals (S345). If the number of bets has not reached the upper limit (S342: NO), the game medal limit flag setting process (S343) is not performed, and the accumulated number of medals is read (S345).

After the process of reading the stored number of sheets (S345), the process of subtracting one stored number of sheets (S345) is executed, and it is determined whether or not the series of processes related to the requested number of sheets has been executed for the requested number of sheets (S346). ) is executed. Then, if the processing for the requested insertion number has been completed (S346: YES), the stored insertion processing is completed, and the processing returns to the original processing in the game progress main processing. If the processing for the requested number of inserted medals has not been completed (S346: NO), the processing after the processing for adding one game medal (S338) is executed again.
<Various processing related to the second control>

Next, various kinds of processing in the above-described second control will be described.
<RWM initialization 2>

FIG. 30 shows the process of RWM initialization 2 used in the above-described power recovery process (see FIG. 21) and the like. In this RWM initialization 2 process, the second work area provided in the predetermined RWM area (F200H to F3FFH) and the maximum usage of the second stack area (F210H to F21EH, F3F3H to F3FFH) are not yet used. Clear used area.

More specifically, the stack pointer is saved (S871), an area outside the use area of the stack pointer is set (S872), and a predetermined register is saved (S873). Further, the RWM initialization start address is set (S874), the RWM initialization byte number is set (S875), and the RWM is initialized (S876). Then, the next RWM address is set (S877), and it is determined whether or not the RWM initialization is completed (S878).

At S878, if the RWM initialization has been completed (S878: YES), the RWM initialization start address is set (S879). Return to initialization processing. After S879, the number of RWM initialization bytes is set (S880), and the RWM is initialized (S881).

Further, the next RWM address is set (S882), and it is determined whether or not the initialization of the RWM is completed (S883). At S883, if the RWM initialization has been completed (S883: YES), the register is restored (S884). If not completed (S883: NO), the RWM initialization process at S881 back to After S884, the stack pointer is restored (S885), and the process ends.
<RWM initialization 3>

Next, the process of RWM initialization 3 used in the above-described setting change device process (see FIG. 13) and the like will be described. As shown in FIG. 31, in the process of RWM initialization 3, the stack pointer is saved (S891), an area outside the use area of the stack pointer is set (S892), and a predetermined register is saved (S892). S893). Further, the RWM initialization start address is set (S894), the RWM initialization byte number is set (S895), and the RWM is initialized (S896).

Subsequently, the next RWM address is set (S897), and it is determined whether or not the RWM initialization is completed (S898). At S898, if the RWM initialization has been completed (S898: YES), the register is restored (S899). If not completed (S898: NO), the RWM initialization process at S896. back to After S899, the stack pointer is restored (S900), and the process ends.

As a control module related to RWM initialization, for example, RWM initialization 1 related to the first control is provided in addition to the RWM initialization 2 and RWM initialization 3 described above. This RWM initialization 1 is transferred from the control module used in the game start set processing (S52) of the power-on processing (see FIG. 12) relating to the first control. A description of the processing of is omitted.
<Serial communication settings>

Next, processing for serial communication settings used for serial communication will be described. In this serial communication setting, the transmission function setting of SCU1 used for test firing test output is performed. More specifically, as shown in FIG. 32, the stack pointer is saved (S911), an area outside the use area of the stack pointer is set (S912), and a predetermined register is saved (S913).

Further, the SCU1 baud rate register address (lower order) is set (S914), and the SCU1 baud rate register is set (S915). Subsequently, SCU channel 1 transmission function use, FIFO mode, data length 9 bits, parity use, and even parity are set (S916), the register is restored (S917), and the stack pointer is restored (S918). , terminate the process.
<Pattern stop signal output>

Next, the process of outputting the symbol stop signal used in the process of the condition device command set described above (see FIG. 16) and the like will be described. In the processing of this conditional device command set, the pattern stop signal data for the test firing test is output. More specifically, as shown in FIG. 33, the stack pointer is saved (S921), an area outside the stack pointer usage area is set (S922), and a predetermined register is saved (S923).

Further, the SCU1 data register is set (S924), and the first command (rotating drum information designation) is written (S925). Subsequently, the second command (rotating drum information designation) is written (S926), and the pattern stop signal set is processed (S927). The processing of the symbol stop signal set (S927) will be described later.

Also, the number of times of transmission and first command (designation of pressing order) data are set (S928), and the first command is written (S929). Further, the second command data is acquired from the stop acceptance specification table (S930), and the second command is written (S931). Also, the next first command data is set (S932), and the next table address is set (S933).

Subsequently, it is determined whether or not the transmission is finished (S934). If the transmission is finished (S934: YES), the register is restored (S935), the stack pointer is restored (S936), and the processing is finished. do. If the transmission has not ended in S934 (S934: NO), the process returns to the first command write process in S929.
<Pattern stop signal set>

Next, the pattern stop signal set processing (S927) used in the above-described pattern stop signal output processing (see FIG. 33) will be described. In the processing of this conditional device command set, the pattern stop signal data table for the trial shooting test is set according to the instruction number, operating state flag and bonus conditional device number.

More specifically, as shown in FIG. 34, the stop acceptance specification table 2 is set (S941), and the offset is set (S942). Further, it is determined whether or not the instruction number is 0 (S943), and if the instruction number is 0 (S943: YES), the stop acceptance specification table 1 is set (S944). Also, it is determined whether or not the bonus is activated (S945), and if the bonus is not activated (S945: NO), the stop acceptance designation table 2 is set (S946).

Subsequently, an offset is set (S947), and it is determined whether or not the bonus condition device is not activated (S948). If the bonus condition device is not in operation (S948: NO), an offset is generated (S949), a stop acceptance specification table is set according to the offset (S950), and the process ends.

At S943, if the instruction number is not 0 (S943: NO), the process of setting the stop reception designation table corresponding to the offset is performed (S850) without performing the intermediate process. If the bonus is activated in S945 (S945: YES), or if the bonus condition device is not activated in S948 (S948: YES), the process is terminated without performing the subsequent processes. do.
<Test signal output>

Next, test signal output processing used in the above-described error management processing (see FIG. 20) and the like will be described. In this test signal output processing, a test signal for the simulation test, condition device information and replay state identification information are output. Then, the bonus operation information and the replay operation information are output to the output port 10, and the output data is output to the port 9 according to the condition device output time and the replay state identification information flag. When the accessory condition differential device information is output, the accessory condition device information is output, when the winning and re-game condition device information is output, the winning and re-game condition device information is output, and when the re-game state identification information flag is ON, the re-game is played. Outputs state identification information, and outputs clear data in other cases.

More specifically, as shown in FIG. 35, the stack pointer is saved (S961), and the stack pointer (outside the used area) is set (S962). Subsequently, the register is saved (S963), and test signal output data is generated (S964). Furthermore, a test signal is output (S965), and an RT state number is acquired (S966).

Subsequently, it is determined whether or not the bonus is activated (S967), and if the bonus is activated (S967: YES), the game is replayed except when the predetermined bonus (here, type BB-A) is activated. A state identification signal is set (S968). Furthermore, it is determined whether or not the predetermined bonus (type 1 BB-A) is in operation (S969). A) A replay state identification signal related to time is set (S970).

Subsequently, a replay state identification signal is generated (S971), and it is determined whether or not the replay state identification information flag is ON (S972). Here, the replay state identification information is information generated from the RT state number and the operation type. If it is determined at S967 that the bonus is not activated (S967: NO), the interim processing is not performed, and it is determined at S972 whether or not the replay state identification information flag is ON. In addition, in the above S969, if the predetermined bonus (1 type BB-A) is not activated (S969: NO), the above S970 is not performed, and the replay state identification information flag of the above S972 is set. It is determined whether or not it is ON.

At S972, if the replay state identification information flag is not ON (S972: NO), condition device information clear data is set (S973), and it is determined whether or not it is time to output the condition device information. (S974). If it is time to output the condition device information (S974: YES), the data for outputting the accessory condition device information is set (S975), and the bonus condition device number RWM address is set (S976).

Further, it is determined whether or not it is time to output the accessory condition device information (S977), and if it is not the time to output the accessory condition device information (S977: NO), winning and replay condition device information Data is set (S978), winning and replay condition device number RWM address is set (S979), and the condition device number is acquired (S980). At S977, if it is time to output the accessory conditional device information (S977: YES), the intermediate processing is not performed, and the conditional device number is obtained at S980 (S980).

Subsequently, the conditional device low-order information (lower-order digit information) is set (S981), and it is determined whether or not it is time to output the conditional device low-order information (S982). Furthermore, if it is not time to output the conditional device low-order information (S982: NO), the conditional device high-order information (high-order digit information) is set (S983), and the conditional device information is generated (S984). Then, the condition device information is output (S985), the register is restored (S986), the stack pointer is restored (S987), and the processing is terminated.

At S972, if the replay state identification information flag is ON (S972: YES), and if at S974 it is not the time to output the condition device information (S974: NO), the interim process is executed. Instead, the condition device information of S985 is output (S985). If it is determined at S982 that it is time to output the condition device lower-level information (S982: YES), the above S983 is not performed, and the condition device information generation processing at S984 is performed (S984).
<Insert/discharge sensor error set>

Next, the processing of the above-described insertion/payout sensor abnormality set related to detection of an error in inserting or paying out game medals will be described. In the processing of the input/discharge sensor abnormality set, a display request for the corresponding error is made according to the error detection flag.

More specifically, as shown in FIG. 36, the stack pointer is saved (S991), and the stack pointer (outside the used area) is set (S992). Further, the register is saved (S993), and a CH error display request is set (S994). Also, it is determined whether or not a CH error is detected (S995), and if not detected (S995: NO), the error display request is cleared (S996).

Subsequently, the error display request data is saved (S997), the register is restored (S998), the stack pointer is restored (S999), and the process ends. If a CH error is detected in S995 (S995: YES), error display request clear processing in S996 is not performed, and error display request data is saved in S997.
<Clear input/discharge sensor error>

Next, a description will be given of processing for clearing an insertion/withdrawal sensor error related to the processing when an error is displayed in the insertion/withdrawal of game medals. In the process of clearing the input/discharge sensor abnormality, when an error display request is made, the corresponding error detection flag and related data are cleared. More specifically, as shown in FIG. 37, the stack pointer is saved (S1011), and the stack pointer (outside the used area) is set (S1012).

Furthermore, the register is saved (S1013), and an error detection flag is set (S1014). Also, it is determined whether or not there is a request for CH error display (S1015), and if there is a request for display (S1015: YES), the CH error detection flag is cleared (S1016). Then, the register is restored (S1017) and the stack pointer is restored (S1018), and the processing is terminated. In the above S1015, if there is no display request (S1015: NO), the above S1016 is not carried out, and the above S1017 register return processing is carried out.
<Error check>

Next, error check processing used in the above-described error management processing (see FIG. 20) and the like will be described. In this error check process, various error check processes are performed. More specifically, as shown in FIG. 38, the stack pointer is saved (S1021), an area outside the use area of the stack pointer is set (S1022), and a predetermined register is saved (S1023).

Furthermore, in the error check processing, set value error check processing (S1024), built-in random number check processing (S1025), timer measurement 2 processing (S1026), game medal insertion check processing (S1027), game medal passing State update processing (S1028), input/discharge sensor abnormality check processing (S1029), and error display request data clear processing (S1030) are performed in order, and these processing will be described later. After clearing the error display request data (S1030), the register is restored (S1031), the stack pointer is restored (S1032), and the process ends.
<Set value error check>

Next, the set value error check process (S1024) used in the above-described error check process (see FIG. 38) will be described. In this setting value error check processing, it is checked whether the setting stage is within the normal range.

More specifically, as shown in FIG. 39, E6 error, which is one of unrecoverable errors, is set (S1036), and it is determined whether or not the set value is less than the maximum value (here, 6). (S1037). Furthermore, in S1037, if the set value is less than the maximum value (S1037: YES), the process is terminated, and if the set value is not less than the maximum value (S1037: NO), the unrecoverable error process 2 is performed. This unrecoverable error process 2 will be described later (see FIG. 49).
<Built-in random number check>

Next, the internal random number check process (S1025) used in the error check process (see FIG. 38) will be described. In this built-in random number check process, if an error related to updating of built-in random numbers is detected, the process shifts to unrecoverable error process 2, and if not detected, an 8-bit random number is checked.

More specifically, as shown in FIG. 40, E7 error, which is one of unrecoverable errors, is set (S1041), and internal information register data is acquired (S1042). Further, it is determined whether or not an internal random number update-related abnormality has occurred (S1043), and if it has not occurred (S1043: NO), an 8-bit random number maximum value check table is set (S1044). Then, the RS0 soft latch random number register address is set (S1045), the 8-bit random number check process is performed four times (S1046 to S1049), and the process ends.

In addition, in the process of determining whether or not an internal random number update-related abnormality has occurred in the above S1043, if an abnormality has occurred (S1043: YES), the process proceeds to the unrecoverable error process 2. This unrecoverable error process 2 will be described later (see FIG. 49). Here, the reason why the 8-bit random number check processing is performed four times in S1046 to S1049 is that there are four corresponding registers, and these four registers are checked in order.
<Timer measurement 2>

Next, the timer measurement 2 process (S1026) used in the error check process (see FIG. 38) will be described. In this timer measurement 2 process, the timer RWM1 used for error check is subtracted (0 is set if less than 0).

More specifically, as shown in FIG. 41, the measurement start timer address is set (S1051), and the number of 1-byte timers is set to 2 (S1052). Further, the 1-byte timer value is updated (S1053), and the next timer address is set (S1054). Also, it is determined whether or not the measurement of the 1-byte timer has ended (S1055), and if it has ended (S1055: YES), the process ends. If the measurement of the 1-byte timer has not ended in S1055 (S1055: NO), the process returns to S1053 for updating the 1-byte timer value.
<Game medal insertion check>

Next, the game medal insertion check (S1027) used in the aforementioned error check processing (see FIG. 38) will be described. In this game medal insertion check process, the insertion sensor 1 and 2 signals are inspected when the medal insertion inspection flag is ON or the blocker signal is ON, and if a passage abnormality is detected, a display request for each error is made. Then, when the insertion sensor 1 passage check time or the insertion sensor 2 passage check time is exceeded, a CE error display request is made, and when the game medals are illegally passed, a CP error display request is made. Furthermore, if the input monitoring counter is not within the normal range, a C1 error display request is made.

More specifically, as shown in FIG. 42, previous blocker signal data is set (S1061), and blocker signal data is generated (S1062). Furthermore, blocker signal data is generated this time (S1063), and blocker signal data is generated (S1064). Also, it is determined whether or not the rise of the blocker signal is detected (S1065), and if detected (S1065: YES), the input monitoring counter is cleared (S1066).

Also, it is determined whether or not the medal insertion inspection flag is ON (S1067), and if it is not ON (S1067: NO), it is determined whether or not the blocker signal is ON (S1068). Furthermore, when the blocker signal is ON (S1068: YES), the data of the previous game medal passing state is acquired (S1069). Then, it is determined whether or not the insertion sensor signal is ON (S1070), and if it is ON (S1070: YES), a medal insertion inspection flag is set (S1071).

If the rise of the blocker signal is not detected in S1065 (S1065: NO), S1066 is skipped, and it is determined whether or not the medal insertion inspection flag is ON (S1067). In addition, when the medal insertion inspection flag is ON at S1067 (S1067: YES), the intermediate processing is not performed, and it is determined whether or not the insertion sensor signal is ON at S1070. If the blocker signal is not ON in S1068 (S1068: NO), the process is terminated.

After S1071, it is determined whether or not the input sensor 1 signal is ON (S1072), and if it is ON (S1072: YES), a CP error is set (S1073). Further, it is determined whether or not the game medal passing state 1 or 3 last time (S1074), and if a negative determination is made (S1074: NO), it is determined whether or not the game medal passing state 0 was the previous time. A determination is made (S1075).

If an affirmative determination is made in S1075 (S1075: YES), the input sensor 1 passage check time is set (S1076), and the CE error is set (1077). Then, it is determined whether or not the passing time of the insertion sensor 1 has passed (S1078), and if it has not passed (S1078: NO), the process is terminated. If a negative determination is made in S1075 (S1075: NO), S1076 is not performed, and a CE error is set in S1077 (1077).

At S1072, if the input sensor 1 signal is not ON (S1072: NO), as shown at S1079 in FIG. 42, it is determined whether or not the input sensor 1 and 2 signals are ON. . Further, when the insertion sensor 1 and 2 signals are ON (S1079: YES), a CP error is set (S1080), and it is determined whether or not the previous game medal passing state was 0 or 1. (S1081).

Then, if it is not the previous game medal passing state 0 or 1, it is determined whether or not it is the previous game medal passing state 2 (S1082), and if the determination is affirmative (S1082: YES) ), and the time for checking the passing of the input sensor 2 is set (S1083). Also, a CE error is set (S1084), and it is determined whether or not the input sensor 2 passing time has exceeded (S1085).

In S1085, if the input sensor 2 passing time has not exceeded (S1085: NO), it is determined whether the input sensor 1 passing time has exceeded (S1085), and if it has not exceeded (S1086: NO), the process ends. At S1082, if the game medal passing state 2 was not the previous time (S1082: NO), S1083 is skipped, and a CE error is set at S1084 (S1084).

In S1079, if the input sensor 1 and 2 signals are not ON (S1079: NO), as shown in FIG. 43, CP error is set in S1087. Furthermore, it is determined whether or not the previous game medal passing state was 0 or 2 (S1088), and in the case of a negative determination (S1088: NO), a CE error is set (S1089), and the insertion sensor 2 passes. It is determined whether or not the time has expired (S1090). Then, when the passing time of the insertion sensor 2 has passed (S1090: NO), the process ends.

If the input sensor signal is not ON at 1070 shown in FIG. 42 (S1070: NO), the process proceeds to S1091 shown in FIG. 43 to clear the token insertion inspection flag. Further, the data of the insertion sensor 1 passage check time and the insertion sensor 2 passage check time are cleared (S1092), and it is determined whether or not the previous game medal passage state is 0 (S1093).

Then, if it is not in the previous game medal passing state 0 (S1093: NO), it is determined whether or not it is in the previous game medal passing state 2 (S1094), and if a negative determination is made (S1094: NO) ), and a CP error is set (S1095). If the previous game medal passing state is 0 at S1093 (S1093: YES), or if the previous game medal passing state is 2 at S1094 (S1094: YES), the process ends. do.

After the above S1095, it is determined whether or not the situation is the previous game medal passing state 1 (S1096). It is determined whether or not the value of the monitoring counter is within the normal range (S1098). Furthermore, if the input monitoring counter is not within the normal range (S1098: NO), the error display request data is saved (S1099), and the process is terminated.

In the above S1096, if it is not the situation of the previous game medal passing state 1 (S1096: NO), or in each of the above S1074, S1078, S1081, S1086 shown in FIG. 42, and the above S1088, S1090 shown in FIG. If YES is determined, the process proceeds to S1099 and saves the error display request data (S1099). If the input monitoring counter is within the normal range at S1098 (S1098: YES), the process is terminated.
<Update game medal passing status>

Next, the game medal passage state update process (S1028) used in the error check process (see FIG. 38) will be described. In this game medal insertion check processing, as shown in FIG. 44, the game medal passage state is updated according to the insertion sensor signal. More specifically, as shown in FIG. 44, the insertion sensor signal information is acquired (S1106), the game medal passing state is updated (S1107), and the process ends.
<Input/discharge sensor error check>

Next, a description will be given of the input/discharge sensor abnormality check process (S1029) used in the aforementioned error check process (see FIG. 38). In the game medal insertion check processing, input abnormality of the insertion sensor, input abnormality of the payout sensor, and passage abnormality of the selector path sensor are monitored.

More specifically, as shown in FIG. 45, the previous error detection flag is updated (S1111), and it is determined whether or not the fall of the blocker signal has been detected (here, whether or not it has become OFF). (S1112). Further, when the trailing edge of the blocker signal is detected (S1112: YES), the time to start detecting an abnormal input from the closing sensor is set (S1113), and it is determined whether or not there is a closing-related error (S1114). .

In S1112, if the fall of the blocker signal is not detected (S1112: NO), it is determined whether or not there is a closing-related error without setting the closing sensor abnormal input detection start time (S1113). A determination is made (S1114). If it is determined in S1114 that the error is not related to the closing (S1114: NO), the ON blocker signal is inspected (S1115), and the effective inspection of the abnormal input detection start time of the closing sensor is carried out (S1116). .

Further, it is determined whether or not there has been an abnormality detection inspection of the input sensor (S1117), and if the result is affirmative determination (S1117: YES), it is determined whether or not there has been an abnormality detection of the input sensor 2 (S1118). ). If there is an abnormality detected in the closing sensor 2 (S1118: YES), the C0 error detection flag is set (S1119), and it is determined whether or not the rise of the selector passage sensor signal has been detected (S1120). ).

If it is determined in S1117 that there was no detection of an abnormality in the closing sensor (S1117: NO), or if it is determined in S1118 that there was no abnormality in the closing sensor 2 (S1118: NO), C0 Without setting the error detection flag (S1119), it is determined whether or not the rising edge of the selector passage sensor signal is detected (here, whether or not it is ON) (S1120).

At S1120, when the rise of the selector passage sensor signal is detected (S1120: YES), the input monitoring counter is incremented by 1 (S1121), and the selector passage sensor residence time is set (S1122). Then, it is determined whether or not the selector passage sensor is ON (whether or not there are accumulated cargo) (S1123). is passed (S1124).

At S1124, if the selector passage residence time has passed (S1124: YES), a CH error detection flag is set (S1125), and it is determined whether or not there is an HP error (S1126). Further, if it is determined at S1124 that the selector passage residence time has not elapsed (S1124: NO), it is determined whether or not the HP error is occurring (S1126) without setting the CH error detection flag (S1125). ).

At S1126, if it is not HP error (S1126: NO), the RWM address of payout sensor abnormality detection 1 data is set (S1127), and the RWM address of payout sensor abnormality detection 2 data is set (S1128). In S1126 above, if the HP error has occurred (S1126: YES), the process ends.

Following S1128, payout sensor 1 and 2 mask data and payout sensor 2-bit data are set (S1129). Further, it is determined whether or not the hopper motor drive signal is ON (S1130), and if it is not ON (S1130: NO), payout sensor check data is generated (S1131). Also, it is determined whether or not only the payout sensor 2 is ON (S1132), and if only the payout sensor 2 is ON (S1132: YES), payout sensor abnormality detection 1 data and payout sensor abnormality detection 2 data is cleared (S1133), and the process ends.

If it is determined in S1114 that the error is related to closing (S1114: YES), if the rise of the selector passage sensor signal is not detected in S1120 (S1120: NO), the selector passage sensor is ON in S1123. If not (S1123: NO), the process goes to S1126 without performing the intervening process, and it is determined whether or not there is an HP error.

In the above S1132, when only the payout sensor 2 is not detected to be ON (S1132: NO), as shown in FIG. 46, payout sensor 1 mask data and payout sensor 1 bit are set (S1134). In addition, payout sensor check data is generated (S1135), and abnormality detection data clear data is set (S1136).

In the above S1130 (see FIG. 45), if the hopper motor drive signal is ON (S1130: YES), the payout sensor check data generation process (S1135) shown in FIG. conduct.

Subsequently, the payout sensor abnormality detection 3 data is cleared (S1137), and the payout sensor abnormality detection data that are not checked are cleared (S1138). Furthermore, it is determined whether or not an abnormality in the payout sensor 1 or 2 is detected (S1139), and if an abnormality is detected (S1139: YES), the payout sensor abnormality detection time is measured (S1140), and processing is performed. exit. In the above S1139, when an abnormality of the payout sensor 1 or 2 is not detected (S1139: NO), the process is terminated without measuring the payout sensor abnormality detection time (S1140).
<Error display request data clear>

Next, the error display request data clearing process (S1030) used in the error check process (see FIG. 38) will be described. In this error display request data clearing process, the error display request data is cleared when an error is displayed.

More specifically, as shown in FIG. 47, it is determined whether or not an error is being displayed (S1146), and if an error is being displayed (S1146: YES), the error display request data is cleared. (S1147), and the process ends. If it is not the error display time in S1146 (S1146: NO), the process is terminated without clearing the error display request data (S1147).
<<8-bit random number check>>

Next, the 8-bit random number check process (S1046 to S1049) used in the internal random number check process (see FIG. 40) will be described. In this 8-bit random number check process, 8-bit random numbers are checked, and if the 8-bit random number is greater than or equal to the maximum random number check data and the maximum random number is set, or if all of the maximum three acquired 8-bit random numbers are If they match, the process proceeds to unrecoverable error processing 2 .

More specifically, as shown in FIG. 48, an 8-bit random value is acquired (S1151), and it is determined whether or not the random value is smaller than the random number maximum check data (S1152). Further, if the random number value is not smaller than the random number maximum check data (S1152: NO), it is determined whether or not the maximum random number value is set (S1153). (S1153: NO), the 8-bit random number is reacquired (S1154).

In S1152 above, if the random number is smaller than the random number maximum check data (S1152: YES), the 8-bit random number is reacquired ( S1154). At S1153, if there is a setting of the maximum random number value (S1153: YES), the process proceeds to unrecoverable error processing 2 (see FIG. 49), which will be described later.

After S1154, it is determined whether or not the random numbers match (S1155). If they match (S1155: YES), the 8-bit random number is reacquired (S1156). Further, it is determined whether or not the three obtained random numbers match (S1157), and if they do not match (S1157: NO), the 8-bit random number maximum value check table is updated (S1158). Then, the 8-bit random number soft latch random number register address is updated (S1159), and the process ends.

If the random numbers do not match at S1155 (S1155: N), the 8-bit random number maximum value check table is updated at S1158 without performing the intermediate process. Also, in S1157, when all the three acquired random numbers match (S1157: YES), the process proceeds to unrecoverable error processing 2 (see FIG. 49), which will be described later.
<<Unrecoverable error processing 2>>

Unrecoverable error processing 2 used in the aforementioned set value error check processing (see FIG. 39), built-in random number check processing (see FIG. 40), 8-bit random number check processing (see FIG. 48), etc. explain. In this unrecoverable error process 2, the process at the time of unrecoverable error detection is performed.

More specifically, as shown in FIG. 49, lower digit error display data is set (S1171), and upper digit error display data is set (S1172). Further, the clear output port address and port number are set (S1173), and the output ports (0 to 6) are turned off (S1174).

Also, the next output port address is set (S1175), and it is determined whether or not the output has ended (S1176). Output is performed (S1177). Then, the upper digits and the lower digits are switched (S1178), and the process returns to the clear output port address and port number setting processing of S1173. If the output has not ended in S1176 (S1176: NO), the process returns to S1174 to turn off the output ports (0 to 6).
<Action and effect of the invention related to medal insertion>

As described above, according to the slot machine 10 of the present embodiment, the game medal selector 44 is provided with the insertion sensor 45 and the selector passage sensor 46. Therefore, both the insertion sensor 45 and the selector passage sensor 46 are detected. The results can be used to determine the state of game medals. Therefore, as compared with the case where only the insertion sensor 45 is used, for example, it is possible to take countermeasures against fraud more strongly. Furthermore, since the operation state related to the insertion of game medals can be monitored using the insertion sensor 45 and the selector path sensor 46, error monitoring and operation control of the blocker 47 can be properly executed based on the various control modes described above. It becomes possible to In addition, the selector passage sensor 46 can be given various functions other than detecting the presence or absence of illegality, and the selector passage sensor 46 can be effectively used. In addition, it is possible to stop a game that is executed after detecting an abnormality at an appropriate timing in relation to other processes.

Further, according to this embodiment, the test signal output process (S762) is executed in the error management process (see FIGS. 18 and 20) related to the timer interrupt process (see FIG. 18), and the test signal output process (S762) is executed for each timer interrupt process. Perform signal output processing. Then, the test signal output processing (S762) sets a test signal corresponding to the winning combination determination result (hand drawing result), and the combination determination result can be output as a testing signal. Furthermore, the main control board 61, which has the main CPU 81 as the arithmetic processing means, is not provided with an emergency connector used for connection with the test equipment at the product development stage, but a non-connector for arranging the emergency connector is provided. A mounting area 183 remains. As a result, it is possible to provide products under the same conditions as when they were tested, and it is possible to reduce the risk of unauthorized acquisition of internal information from test signals.

Furthermore, in the power-on process (see FIG. 12), the initial setting process is first executed when the power is turned on. As the initial setting process, after initializing the register (S1), initial values are set in the register and the type of interrupt is set (not shown). Further, when such initial setting processing is finished, the RWM checksum is calculated (S3), and it is determined whether or not the designated switch (here, door switch, setting door switch, setting key switch) is operated. (S9) If the operation has not been performed (S9: NO), the power interruption recovery process (see FIG. 21) is executed.

Therefore, when the power is turned on, the initial values can be set in the registers at an early stage, and without being affected by the data remaining in the registers when the power was turned off last time, the processing at power-on (Fig. reference) can be executed (S2 to S13).

In addition, in the power-on processing, after initial values are set in the registers, the process shifts to the setting change device processing (see FIG. 13). "6") is checked (S30 in FIG. 13), and if the set value is not within the predetermined range (S30: NO), the set value is corrected (S31) and set Set value display processing for displaying the value on the game information display means is performed (S32). Further, in the display process, the information indicating that the setting is being changed and the stored setting value are output to the display device (here, the setting display LED 66 (see FIG. 4)) (S32), and the setting is made according to the operation of the setting switch. The value is updated (S33-S34).

Therefore, it is possible to properly specify the processing for displaying the setting values after turning on the power, and to display the setting values accurately. Then, it is possible to properly perform a series of processes from turning on the power to displaying the set values. Moreover, it is possible to prevent abnormal display from being displayed on the setting display LED 66 (see FIG. 4), which is a display device for displaying the setting value.

As a condition for shifting to the setting change device process (FIG. 13), for example, a condition based on the state of the built-in RWM (see FIG. 11) can be considered. More specifically, checksums are performed for all areas targeted by the built-in RWM, and if the checksum value (checksum data) is normal, this is the condition for transitioning to the setting change device processing. I can give an example. It is also possible to adopt a control mode in which checksum is performed, but the checksum result is not used as a judgment condition, and no special processing is performed even if there is an abnormality in the checksum value. .

Furthermore, the establishment of a plurality of conditions may be used as a condition for transitioning to the setting change device processing, in which case both the power-off execution processing flag being normal and the checksum result being normal may be used as a condition for transitioning to the setting change device process.

Further, according to this embodiment, when the setting change switch (setting key switch 68 in FIG. 4) is operated, the change in the switch signal (setting/reset button signal) is detected by the rise of the signal (see FIG. 4). 13 S33). Furthermore, according to this embodiment, in the game progress main process (see FIG. 14), it is determined at the start of the game whether or not there are game medals (S54). : NO), as described above, the setting value checkable state in which the currently set setting value is visibly displayed on the display device (setting display LED 66) is entered. Also, if there are game medals (if there is a bet amount) (S54: YES), the currently set setting value is not displayed on the display device (setting display LED 66) and the setting value cannot be confirmed.

Then, in the display process (S55) for waiting for game medals to be inserted, which is executed when the setting value can be confirmed, the setting value can be confirmed by operating the setting change switch (setting key switch 68). becomes. Furthermore, in this set value checkable state, blocker OFF data is set so that game medals cannot be inserted, display processing of the stored set values is performed, and a change in the switch signal is detected (detection of a falling edge). The set value display process is ended, and the process for setting the blocker ON data is executed.

Further, in this setting value checkable state, processing for progressing the game, such as the game medal management (S56 in FIG. 14) to the game end check (S68 in FIG. 14), is not performed. Furthermore, although illustration is omitted, in the set value checkable state, errors related to random numbers are detected, but other errors are not monitored. In addition, while shifting to the set value confirmation possible state by detecting a change in the switch signal, when the bet number is set (S54: YES), the change in the switch signal related to the bet number is detected. However, the game can be played (see S56 and thereafter).

In this way, by executing the process to make the setting value unconfirmable and setting restrictions on the setting value confirmation, it is possible to prevent the setting value from being confirmed without going through a predetermined procedure. becomes. Then, it becomes possible to prevent fraudulent acts of trying to check the set values by means other than proper methods.

Furthermore, according to the present embodiment, when game medals are paid out based on the display determination (S66) of the game progress main process (see FIG. 14), the display process relating to the number of paid out game medals is performed, and the game medals are displayed. Every time one medal is paid out, the value displayed on the display device (here, the number of won medal display section) is updated. Then, the value corresponding to the number finally paid out is displayed until the next time the game medals are inserted or when the aforementioned game standby display is started (when the game medals are not inserted even after a certain period of time has passed since the end of the game). be done. Also, even during the display of information relating to the number of paid out game medals, when an error occurs, the value corresponding to the displayed number is changed to display corresponding to the error that has occurred.

According to the present embodiment as described above, by setting the conditions for turning off the display of the number of won medals, the display relating to the number of game medals can be changed to another display mode at an appropriate timing. Misunderstanding of the result of the game can be prevented compared to the case where the switching is not performed or the timing of the switching is too late or too early.

Further, according to this embodiment, in the game progress main process (see FIG. 14), a predetermined value (start address) is set in the stack pointer (S51). Then, a game medal management process (S56) and a start switch input confirmation process (S58) are performed. Further, the game medal management process (S56) and the start switch input confirmation process are repeated until the start switch is effectively accepted (S58). Therefore, the stack pointer can be cleared each time at the initial stage of the game progress main process (see FIG. 14), and when some abnormality occurs, it is possible to prevent the process from looping in an abnormal state.

Furthermore, according to this embodiment, display determination (S66) is performed in the game progress main process (see FIG. 14), and if game medals are to be paid out, processing for paying out game medals (S67) is performed. Then, when the payout of the game medals is completed or when there is no payout of the game medals, a game end check (S68 or the like) is performed to perform processing according to the game state.

In the game end check processing (S68, etc.), the RWM clearing processing of the conditional device numbers other than the handover hand (clearing the conditional device of the non-carryover hand), extinguishing the regame display LED, clearing the regame operation flag, A game state such as a bonus (here, BB) or RT is set. Further, when the game completion check (S68, etc.) is completed, a predetermined value (start address) is set in the stack pointer at the beginning of the game progress main process (see FIG. 14) (S51). Therefore, the stack pointer can be cleared each time after the game end check (S68, etc.), and when some kind of abnormality occurs, it is possible to prevent the processing from looping in an abnormal state.

Further, according to this embodiment, when the power is turned off, the value of the stack pointer is stored in the first predetermined storage area (F000H to F14AH) set in the internal RWM area (F000H to F14AH) shown in FIG. area (S568), the checksum data is calculated for the RWM storage area range (F000H to F3FFH) including this work area, and the checksum value obtained by the calculation is stored in the first predetermined The storage area is stored in the second predetermined storage area (S574). Furthermore, the above-described first predetermined storage area and second predetermined storage area are set in areas other than the beginning and end of the working area. Therefore, the value of the stack pointer and the value of the checksum data can be saved while avoiding the beginning and end of the work area where the positions are easy to identify, making it difficult for a third party to identify the storage location of these values. This makes it possible to prevent fraud.

It should be noted that the present invention can adopt various control modes as described below in addition to or in place of the control modes described above.
<Control aspect related to error notification>

First, a control mode related to error notification will be described. In the error management process (see FIG. 20) subsequent to the timer interrupt process (see FIG. 18), the control mode related to the error notification is the error check (S754) related to the second control, etc. Monitoring is performed (see FIG. 38), and when an error occurs, a main command is transmitted to the sub-control board 31, and based on this main command, the sub-control board 31 controls, for example, the production section 18 (see FIG. 1). It is conceivable to perform error notification using In other words, the error notification can be performed before the progress of the game is stopped (before the error display processing in each situation).

Also, after the start lever 25 is operated, that is, when the blocker 47 is in the OFF state (returnable state), for example, when an error occurs in a situation where the effect is being executed in the effect unit 18 (see FIG. 1), the It is conceivable to cancel (discontinue) the effect and notify the error by the effect unit 18 or the like. Furthermore, as another aspect, similarly, in the state where the blocker 47 is OFF (returnable state), for example, when the effect is being executed in the effect unit 18 (see FIG. 1), while continuing the effect, for example It is conceivable to display an error on a display device capable of error notification (for example, an LED for displaying the number of cards acquired), or to issue an error notification by sound using the speaker 50 . As another aspect, similarly, when the blocker 47 is in the OFF state (returnable state), for example, in the production unit 18 (see FIG. 1), the high expectation level indicating that the expectation of winning some role is high. If an error occurs during the execution of a specific effect, such as a effect or a continuous effect that is performed continuously over multiple games, after all reels are stopped, an error notification is executed. can be considered. For example, when the sub-control means (sub-control board 31 here) receives a main command based on the input error set process (see FIG. 25), a predetermined notification mode A (liquid crystal, first lamp, and When an error is notified in the notification mode using an amplifier (speaker) and a main command based on the error display process (see FIG. 24) is received, another notification mode B (liquid crystal, first lamp, second lamp, and notification mode using an amplifier (speaker)). At this time, the second lamp is a lamp capable of navigating (navigating) the operation order during the AT game (information game), and even if an error occurs, the player will be disadvantaged in the game. It is possible to control the second lamp so that it does not occur, and so on.
<Control mode related to game stop>

In addition, as a control mode related to the game stop, for example, in timer interrupt processing, the selector path sensor 46 and the insertion sensor 45 are monitored (see FIG. 38) by error management (see FIG. 20), etc., and when an error is detected In addition, after proceeding to the error display process (Fig. 24), instead of stopping the game by performing the loop processing of S240 and S248 in Fig. 24, the game is stopped immediately in the error check (Fig. For example, it is conceivable to turn off the blocker). Further, in synchronization with the game stop timing, it is possible to execute error notification using the effect section 18, the speaker 50, etc., under the control of the sub-control board 31. FIG.
<Other control aspects related to error detection>

Also, when the blocker 47 is in the ON state (passable state), an error based on the input sensor 45 is detected by the error check (FIG. 38) in the error management processing (FIG. 20) from the timer interrupt processing (see FIG. 18). In this case, without waiting for the error display processing (FIG. 24), for example, the game can be immediately stopped in the error check (FIG. 38) (for example, blocker OFF processing). Conceivable.

Furthermore, when an error based on the input sensor 45 or the like is detected by various processes in the game progress main process (see FIG. 14), monitoring of the selector passage sensor 46 and monitoring of the input sensor 45 are performed by timer interrupt processing. It is possible not to execute the processing for Furthermore, as described above, the processing for monitoring the selector path sensor 46 and the insertion sensor 45 by the timer interrupt processing is not executed, while the payout provided in the game medal payout device 63 (see FIG. 2) Monitoring of the sensor (not shown) is performed based on the cycle of the timer interrupt, and when the payout sensor detects an abnormality such as accumulation or backflow of game medals, a command set to send an error command associated with the abnormality to the sub. It is conceivable to execute processing for

Further, when the aforementioned door (front door portion 11) is open (when the door switch is in the open state), error notification related to door opening is performed using the LED and speaker 50. FIG. However, although the main control board 61 recognizes the occurrence of the door opening error, it does not recognize it as an error corresponding to stopping the game, and sends a command related to the error occurrence to the sub control board 31. do. Then, the sub-control board 31 executes the door opening error notification. Therefore, even if the front door portion 11 is opened, it is possible to play a game involving reel control. Furthermore, when the front door section 11 is closed while the door opening error is being notified, the sub-control board 31 determines that the door opening error release condition is satisfied, and the door opening is notified by the LED or the speaker 50. End error reporting. It should be noted that the sub-control board 31 may wait for a predetermined period of time (for example, about several seconds) after the front door section 11 is closed to terminate the door open error notification.
<Production state in the slot machine>

Next, the effect state performed by the slot machine 10 will be schematically described. The effect state in the slot machine 10 is represented by moving images or still images displayed on the image display means such as the effect unit 18 or the reel display panel 28, sound output from the speaker 50, light from various LEDs, etc., alone, or It is a state created using a combination. Such a performance state can be divided into a performance state (normal performance state) for a basic normal state and a performance state (special performance state) for a special state different from the normal state.

Among these, the normal production state can be, for example, a production state in which no role is played and no production (suggestive production) is performed to arouse the expectation of winning. be. In this normal effect state, from the situation before the start of one game, bet setting (bet), start, reel rotation (symbol fluctuation), symbol combination stop display, next game bet setting (bet), It can be continued during a series of game states such as. A moving image (special state display) displayed on image display means such as the production unit 18 and the reel display panel 28 can be exemplified.

On the other hand, the special effect state can be said to be an effect that is executed when a special state different from the normal state occurs, or to arouse expectations for the special state. And as a special state, the bonus (main bonus) such as BB and RB mentioned above, RT (replay time), AT (assist time), and ART (assist replay) in which replays and bells are established with a higher probability than usual time) can be exemplified.

Of these special states, bonuses such as BB and RB and RT are managed by the main control board 61 . Other special states such as AT and ART may be managed by the sub-control board 31 (sub-bonus) or may be managed by the main control board 61 . In addition, in the game state such as AT or ART, for example, "3", "1", "2" or "2", "1", "3" are displayed on the reel display panel 28 (or the effect section 18). Alternatively, it is possible to display so-called push order navigation for navigating the operation order of the stop buttons (24L to 24R) such as "1", "3", "2".

Moreover, as a special state, an advantageous section (advantageous gaming state) in which a game state advantageous to the player is possible can be exemplified. As this advantageous section, a game state in which AT, ART, or the like can be played under the control of the main control board 61 can be exemplified. In this advantageous section, a game such as AT may or may not be performed. It is possible to perform control for games such as. Also, the advantageous section can be set to end after a predetermined period (1500 games, etc.). Further, there may be a plurality of types of periods of this advantageous section.

Furthermore, as a special state, a game state of a so-called special zone can be exemplified. This add-on specialized zone is a period of a game state in which the number of games such as AT or ART, which has been decided in advance, is likely to be added (probability of addition is increased). The period of the additional special zone may be of one type or of a plurality of types.

As a special state display related to such a special state, a series of displays can be divided into a plurality of sections arranged in chronological order. As for the special status display, there are three types of display: the start of the special state (starting special state display), the display during the special state (during special state display), and the end display related to the special state (end special state display). can be exemplified. Any of these displays can be exemplified by using a plurality of display data in chronological order to form a series of display contents. Furthermore, among these, the special state start display can be exemplified by displaying an image or outputting a sound effect as an introductory effect for several seconds to several tens of seconds. A video display may include a moving image display, a still image display, or a combination thereof. For example, it is also possible to adopt a display mode as the special state start display, in which a predetermined moving image is displayed, a predetermined still image or another predetermined moving image is displayed, and the transition is made to the display during the special state, which will be described later. be.

In addition, as an effect at the time of special state start display, other than this, for example, a freeze (start freeze) effect that can be performed in various modes as described above using the reels 51L to 51R under the control of the main control board 61. , and video display and output of effect sound under the management of the sub-control board 31 (management by the sub-main CPU 86).

Here, the relationship between the freeze effect, which is the effect managed by the main control board 61, and the effect such as image display (display effect related to the freeze effect) managed by the sub-control board 31 can be determined in various ways. is. For example, the freeze effect and the effect such as video display are started at the same timing, the effect such as video display is started before the freeze effect, or the effect such as video display is started after the freeze effect. It is possible to

More specifically, when the freeze effect is started under the control of the main control board 61, the sub-control board 31 can start the effect related to the freeze effect based on the command from the main control board 61. . In addition, before starting the freeze effect, it is possible to transmit a command related to the freeze effect from the main control board 61 to the sub-control board 31, start the effect managed by the sub-control board 31, and then start the freeze effect. be. Furthermore, after starting the freeze effect, it is also possible to transmit a command related to the freeze effect from the main control board 61 to the sub-control board 31 and start the effect managed by the sub-control board 31 .

Furthermore, as the above-mentioned display during the special state, for example, the progress status such as the number of games (the number of games played) and the number of game medals acquired during the special state are displayed by a sub-controller based on the command from the main control board 61. An example that is displayed together with an effect by management of the board 31 can be exemplified. This display during the special state can be said to be, for example, "normal display in the special state" or "normal screen in the special state".

Also, as the above-mentioned special state end display, for example, the characters in the production (main character, ally character, etc.) are controlled by the sub-control board 31 to win or lose the enemy character in the battle production. etc., can be exemplified as being executed following the production during the special state. Furthermore, as this special state end display, any part or all of the game results such as the number of games executed during the special state, the number of game medals obtained, and the number of continuous sets, A so-called ending effect displayed based on a command from the main control board 61 can be exemplified. The above-mentioned "number of continuous sets" indicates the degree of stacking of special states by the number of sets, each set including a plurality of games (40 games, 70 games, 100 games, etc.).

In the ending effect, the display of the game results in the special state, such as the number of games, the number of obtained numbers, the number of continuous sets, etc. It is possible to switch and display them one by one. Furthermore, it is also possible to perform the ending effect in a mode in which all of the game results of multiple types, such as the number of games played, the number of wins, and the number of continuous sets, are displayed (collective result display).

Furthermore, during the ending effect, it is also possible to execute the above-described freeze effect managed by the main control board 61 as an end freeze effect. Also, an effect mode can be exemplified in which the above-described ending effect is executed after executing the effect of the story in which the main character, the ally character, etc. are defeated by the enemy character.

Furthermore, when the special state continues, for example, when transitioning from ART to bonus, the control of the sub-control board 31 based on the command from the main control board 61 allows the special state end display related to the previous special state to be displayed. Subsequently, a special state start display for a later special state may be executed.

Also, the mode of various effects is determined according to the results of the internal lottery, the progress of the effects, and the like. Furthermore, as aspects of effects performed on the display device such as the effect unit 18, effects with different background images and characters for each effect stage, scenes such as competitions and battles, and the above-mentioned battles performed in association with game results. It is possible to carry out various effects such as a mission effect which is performed by associating a scene such as an effect, a given task, a mission or a task with the result of the game.

In selecting the effect, for example, the sub control board 31 receives a command (main command) transmitted from the main control board 61 . Then, the sub-control board 31 selects one of the presentation modes from a plurality of selection targets based on the main command, and sends a command (sub-main command) to the image control board 32 for image display (including voice (sound) output). command) is transmitted, and various effects are executed under the control of the image control board 32 .

In addition, when the sub-control board 31 determines the effect mode by random number lottery, the selection ratio of various effects is determined by a predetermined random number range (the number of random numbers) and a predetermined number. For example, within the random number range of 0 to 999 (the number of random numbers is 1000), the input numbers corresponding to the predetermined effect A are 0 to 799, and the input numbers corresponding to the other predetermined effect B are 800 to 949. In addition, when the number corresponding to another predetermined effect C is 950 to 999, the selection ratio of the effect A is 80%, the selection ratio of the effect B is 15%, and the selection ratio of the effect B is 5%. .

In this case, the effect A is more likely to be executed (appears more easily) than the effects B and C, and the effect B is more likely to be executed than the effect C. In addition, the performance C is less likely to be executed (difficult to appear) than the performances A and B, and the performance B is less likely to be executed than the performance A.

Furthermore, in the case of winning a predetermined role, for example, with respect to the above-mentioned effects A to C, the effect A is selected at a rate of 80% when a certain role is won (if it is not won is selected at a rate of 20%), the effect B is selected at a rate of 15% when winning the role (selected at a rate of 85% when not winning), and the effect C is It shall be selected at a rate of 5% when winning the relevant role (selected at a rate of 95% when not winning).

In this case, it can be said that the degree of expectation for winning the role is 80% for the performance A, 15% for the performance B, and 5% for the performance C. Then, it can be said that the degree of expectation related to the win of the relevant combination is that the degree of expectation for the performance A is the highest, the degree of expectation for the performance B is the second highest after the performance A, and the degree of expectation for the performance C is the lowest.
<Control aspect related to specified number change function>

In addition, it is possible to change the above-described control mode for the specified number of bets as follows. For example, the specified number of bets is set to 2 or 3, and the tendency of the winning lottery and the performance lottery can vary according to the difference in the betting number. Then, a situation assuming a game with a two-coin bet and a situation assuming a game with a three-coin bet can occur. do. Such a function can be called, for example, a "specified number change function".

<<An example of game characteristics when the specified number change function is provided>>
The game characteristics of a slot machine having such a specified number changing function will be briefly described below. First, in a slot machine having a specified number changing function, it is possible to adopt various patterns. be something like

FIG. 51 shows the correspondence between the symbols drawn on the reels 51L to 51R and the symbol numbers. In FIG. 51, the number of symbols drawn on one reel (51L to 51R) is 20 (symbol numbers 0 to 19). In addition, the number of types of symbols on each of the reels 51L to 51R (FIG. 1) is ten.

Furthermore, various patterns can be adopted as individual patterns, but here, the number "7" is represented in red as "red 7", a black rod-shaped mass as a motif of "black BAR", and white. "White BAR" with a motif of stick-shaped lumps of white bells, "Bell A" with a white bell motif, "Bell B" with a black bell motif, "Replay" with a plum fruit motif, cherries "Cherry" with a motif, "Watermelon" with a watermelon motif, "Grape" with a motif of grapes, and "Blank" with a predetermined character (such as a star) as a motif are used.

Next, an example of the lottery will be described. The mode of the raffle draw can be as follows. For example, when the player operates the start lever 25, the hardware random number is taken in by the main CPU 81 as described above, and the process shifts to the internal lottery start process (S60). In the internal lottery start process (S60), a role lottery related to a predetermined condition device (replay, winning combination, role, and role continuous operation device) is performed.

In the example described here, there are a plurality of conditional devices (for example, conditional device numbers 0 to 12), and each conditional device is associated with a role and a symbol combination (Fig. 52(a) ~ Figure 56). When the symbol combination stop-displayed along the activated line as described above matches the symbol combination of the winning combination determined by the lottery, that combination is won.

Figures 52(a)-56 schematically illustrate the relationship between conditional devices and corresponding hands. FIG. 52(a) shows the relationship between the conditional devices with conditional device numbers 0 and 1 and the corresponding hands under different prescribed numbers (3-coin bet or 2-coin bet). In addition, FIG. 52(b) shows the relationship between the conditional units of the conditional unit numbers 2 to 4 and the corresponding hands in the 3-coin bet.

A big bonus combination (BBA) corresponding to the conditional device number 0 in FIG. 52(a) is a combination in which a BBA game is started from the next unit game when a prize is won. Also, the big bonus combination (BBB) corresponding to the conditional device number 1 is a combination in which the BBB game is started from the next unit game when a prize is won. During these BB games (during BBA, during BBB), as shown in FIG. When a total of 45 or more medals are paid out during the BBA, the BBA game ends, and when a total of 10 or more medals are paid out during the BBB, the BBB game ends.

Also, as with the slot machine 10 described above, when a winning combination is won as a result of the winning combination, the state is cleared when the unit game ends regardless of whether the winning combination wins or not. . However, when the BB role (BBA or BBB) is won, even if the BB role cannot be won in that unit game, the state of winning the BB will remain until the BB role is won after the next unit game. It is designed to be maintained (carried over). That is, the state in which the BB combination can be won continues until the BB combination is won.

In the following, the period during which the winning state of the BB hand is maintained is referred to as "during internal" or "during bonus carryover". In addition, the BB hand is not included in the lottery in the "internal middle", and the BB hand is not determined to be the winning hand again when the BB hand is the winning hand.

In addition, hereinafter, the state in which the BB hand is not won will be referred to as "non-inside" to distinguish it from the above-mentioned "inside". This "non-internal" can be called, for example, a "predetermined game state" or an "nth game state" (n is a natural number) in order to distinguish it from other game states.

FIGS. 52(b) to 55 show the relationship between the condition device and the payout when betting 3 coins. Of these, as shown in FIG. 52(b), in the case of a loss corresponding to the conditional device number 2, a symbol combination that does not constitute any combination of hands is displayed.

Furthermore, the replay combination corresponding to the condition device number 3 corresponds to the display type data 1 described above. (also called replay) can be performed. It should be noted that neither the above-described BB combination nor this replay combination does not pay out medals when the respective combination wins. On the other hand, in the case of a small winning combination, a predetermined number of medals are paid out when the player wins.

Bell 1 and 1-sheet hand 1 to 14 correspond to the conditional device role of conditional device number 4 whose conditional device name is left-center-right bell. The symbol combination corresponding to each role is the illustrated symbol combination. For example, if the symbol combination corresponding to Bell 1 is shown in the order of reels 51C, 51R, and 51L, "grape-grape - White BAR". In addition, for 1-card hands 1 to 14, symbol combinations such as "black BAR-blank-white BAR", "black BAR-bell A-white BAR", and "replay-bell A-white BAR" are defined. .

Furthermore, as shown in the "remarks" column in FIG. 52(b), when the conditional device with the conditional device number 4 hits "inside the BBB", game medals can be paid out in a predetermined stop operation order. become. For example, when the stop buttons (24L to 24R) are operated in the order of left, middle, right, the operation order is correct, and Bell 1 (the number of payouts is 8) wins with a probability of 100%.

Also, if the stop buttons (24L to 24R) are operated in the order of the left and right, the operation order is incorrect, and one of the 1-card hands (1 card) wins with a probability of 100%. Furthermore, when the stop buttons (24L to 24R) are operated in the order of middle first (the second stop button 24C, which is the middle stop button, is first), any one of 1 to 14 (the number of payouts is 1) Ka wins with a probability of 1/2. Furthermore, when the stop buttons (24L to 24R) are operated in order of the right first (the third stop button 24R, which is the right stop button, is operated first), any one of 1 to 14 (the number of payouts is 1) Ka has a 1/4 chance of winning.

Regarding the condition devices 5 to 12 shown in FIGS. 53 to 55, the relationship between the pressing order and the payout is also defined, and by performing the stop button operation or the first stop operation in the pressing order not shown, Payout is performed with a predetermined probability and number of medals.

FIG. 56 is a diagram for explaining the relationship between the condition device numbers 2, 11 and 12 and the corresponding hands in the triple bet. In the loss corresponding to the condition device number 2, a symbol combination that does not constitute any combination of hands is displayed. Bells 1 to 5 and watermelon correspond to the conditional device role of conditional device number 11 whose conditional device name is all small wins ALL, and when Bell 1 to 5 and watermelon win, there are 8 payouts. The conditional device name is 1 small hand ALL, and the conditional device hand of conditional device number 12 corresponds to 1 hand 1 to 60, and there is a payout of 1 hand when 1 hand is won.

Next, the winning probability of each lottery target in the role lottery will be described with reference to the role lottery table shown in FIG. The winning lottery table shown in FIG. 57 shows the numbers (numbers) of numerical values (lottery values) considered to be won for each lottery target of "non-internal", "BBA internal" and "BBB internal". there is The random number "0" is also included in the numerical value, and the total number of random numbers is 65536. Therefore, the winning probability of each lottery target is a value obtained by dividing the corresponding number by 65536. Also, the role drawing table shown in FIG. 57 is assumed to be a role drawing table common to "setting 1" to "setting 6" for the sake of simplicity of explanation.

In the lottery table shown in FIG. 57, the setting number of the conditional device number 0 whose conditional device name is BBA is 4300 in the "non-internal" three-coin bet and 1 in the "non-internal" two-coin bet. It's becoming The setting number of the conditional device number 1 whose conditional device name is BBB is 1 in the "non-internal" 3-coin bet, and 10000 in the "non-internal" 2-coin bet.

In addition, the setting number of the condition device number 0 whose condition device name is BBA is 0 in the double bet of "non-internal medium", and the setting number of the condition device number 1 whose condition device name is BBB is "non-internal medium ” may be set to 0. By setting the number of the conditional device number 0 whose conditional device name is BBA to 0 in the "non-internal" two-coin bet, the symbols related to the winning of the BBA are aligned in the two-coin bet game. can be reliably prevented, and it becomes possible to perform the work of "advance preparation" to be described later more smoothly. In addition, by setting the number of the conditional device number 1 whose conditional device name is BBB to 0 in the "non-internal" 3-coin bet, the symbols related to the winning of BBB are aligned in the 3-coin bet game. can be reliably prevented, and it is possible to prevent BBB from being erroneously won in a game after the "preparation" to be described later is completed.

In addition, the lottery of BBA and BBB is not performed for "inside BBA" and "inside BBB".

Next, the number set for conditional device number 2, whose conditional device name is a loss, is 30737 in the 3-coin bet "non-internal", 25037 in the 2-coin bet "non-internal", and 3 in the "BBA internal". 30737 in the bet on 3 coins, 30737 in the bet on 2 coins “inside BBA”, 30737 in the bet on 3 coins in “inside BBB”, and 30737 in the bet on 2 coins “inside BBB”.

The setting number of the condition device number 3 whose condition device name is replay is 8978 in the 3-coin bet "non-internal", 8978 in the 2-coin bet "non-internal", and 3-coin bet "BBA internal". , 13279 in the two-coin bet "inside the BBA", 13279 in the three-coin bet "inside the BBB", and 13279 in the two-coin bet "inside the BBB".

The setting number of the conditional device number 4 whose conditional device name is left-center-right bell is 3420, "non-internal", " It is 3420 in the double bet of "BBA inside" and "BBB inside". In addition, the setting numbers of condition device numbers 5 to 9 are 3420, "non-internal It is 3420 in the double bets of "medium", "inside BBA" and "inside BBB".

The setting number of the condition device number 10 whose condition device name is watermelon is 1000, "non-inside", "BBA inside" in the 3 bets of "non-inside", "BBA inside" and "BBB inside" ” and “inside the BBB” are 1,000.

The winning lottery table shown in FIG. 58(a) indicates the number of numerical values considered to be winning for each lottery target in BBA and BBB. The setting number of the conditional device number 2 whose conditional device name is loss is 100 in the 3-coin bet. The setting number of the conditional device number 11 whose conditional device name is All Minor Hand ALL is 16384 in the 3-coin bet, and the set number of the conditional device number 12 whose conditional device name is 1-card hand ALL is 49052 in the 3-coin bet. It's becoming Note that during BBA and BBB, the two-coin bet game is not performed (a control dedicated to three-coin bet is performed). Any one of Bell 1 to Bell 5 can be won in all small wins ALL, but Bell 1 to Bell 5 are composed of symbol combinations that can be won even if the player is stopped at any position. In this embodiment, it is designed so that Bell 1 wins when all small wins ALL are won. may In addition, while the game feature is exclusively for betting 3 coins during BBA and BBB, it is not limited to this. It is also possible to

In addition, the probability of winning Bell 1 is 6840/65536 when condition devices with condition device numbers 4 and 5 are won in “non-internal”, “BBA internal”, and “BBB internal” (Fig. 57). On the other hand, in "during BBA" or "during BBB", the probability of winning Bell 1 is 16384/65536 when the condition device with condition device number 11 is won (see FIG. 58(a)). Thus, the probability of winning Bell 1 during "BBA" or "BBB" is higher than the probability of winning Bell 1 during "non-inside", "BBA inside", and "BBB inside". is set. Furthermore, in "non-internal", "inside BBA", and "inside BBB", Bell 1 will not win unless the operation order is correct. Since 1 can be won, there is a higher possibility that the payout of 8 coins corresponding to Bell 1 can be obtained in the case of “during BBA” and “during BBB”.

However, from the viewpoint of symbol combinations such as Bell 1, BB is advantageous (in terms of winning probability), but non-BB has many opportunities to pay out 8-card hands. If the operation order is correct during AT, the probability of obtaining Bell 1-5 and Watermelon is 21520/65536, so the number of times that 8 payouts can be obtained is higher during non-BB than during BB. In this way, it is possible to provide game properties (game properties) with different advantages depending on the game state of the AT or the like.

Also, when the condition device of condition device number 11 is won during "BBA" or "BBB", the operation order is set, and when the stop button (24L to 24R) is operated in the order of the left first, the bell 1 (8 pieces) wins with a probability of 100%, and when operated in the middle first order, Bell 1 (8 pieces) wins with a 100% probability, and when operated in the right first order, the bell Any of the bells other than 1 (8 pieces) may win with a probability of 100%. At this time, the probability that Bell 1 will be stopped and displayed on the active line is 16384 if Bell 1 wins in the left first or middle first operation order when the conditional device with conditional device number 11 is won. is 2/3, resulting in 10923/655366 (see FIG. 58(a)). In this way, even if the operation order is set such that Bell 1 wins when the condition device of condition device number 11 is won, the probability that Bell 1 will be stopped and displayed on the activated line during BBA or BBB is "non It can be set to be higher than the probability (6840/65536) that the bell 1 is stopped and displayed on the active line during "inside", "inside BBA", or "inside BBB". Also, since the AT lottery is not executed during BBA and BBB, there is a possibility that you can get more medals than during the inside (e.g. consecutive wins for the conditional device with 8 payouts), but it is unlikely that the number of medals will increase further. Therefore, it can be said that it is in a disadvantageous state compared to inside.

In a slot machine having this specified number changing function, even if a MAX bet is made when the number of remaining credits is 2 (even if the 3-card insertion button 76 is pressed), a 2-card bet is not placed. It's not supposed to. In order to make an effective bet in this situation, it is necessary to repeat the pressing operation of the one-insert button 75 twice, or to insert game medals into the game medal insertion slot 21 (so-called care) by the player. .

<Description of game state transition diagram>
FIG. 58(b) is a diagram for explaining the transition of the game state, taking BBB as an example. BBA can be explained by replacing BBB in FIG. 58(b) with BBA as it is. Here, when it becomes "BBB inside" and the winning probability of the replay role (also called "replay role winning probability", "replay winning probability", etc.) is increased or when it becomes "BBA inside" The RT state is called "RT", and the RT state when the winning probability of the replay role before becoming inside (non-inside) is lower than "BBB inside" is "non-RT". It is called medium. Here, the RT start condition is that a conditional device related to the operation of BBA or BBB is activated, and the RT end condition is when a symbol combination that activates BBA or BBB is displayed (BBA or BBB symbol combination is displayed).

In addition, regarding the winning probability of the replay combination, the winning probability relationship may be determined so that the replay winning probability in the "non-RT" is the highest compared to the others. In addition, it is sufficient if the replay winning probability is different (the replay winning probability may be different), and even if the winning probability (combined winning probability) is the same as a whole, the individual replay winning probability It is conceivable that such selection ratios (distributions) are different from each other.

For example, the winning probability of the first re-game A in "non-RT" is 1/4, the winning probability of the second re-game B is 1/4, and the winning probability of the first re-game A of "RT1" is 1/2. Assuming that the probability of winning the second replay B is 0, the combined probability of "non-RT" and the combined probability of "RT1" are both the same (1/2).

Referring to FIG. 58(b), the transition of the game state (in other words, the game state that can be directly recognized by the main CPU 81) from the viewpoint of the winning combination will be described. Immediately after or after setting change in a predetermined gaming state (betting 3 coins during BB internal (during BBA), which is ``inside BB'' after winning in a 3-coin betting game, after setting change in ``inside BB (during BBA)'', bet 3 After changing the setting of "during BB (during BBA)" which is "during BB" which is "during BB" which is shifted by winning by a game During BB (during BBB)", the setting is changed to "non-internal" and "non-RT", and the winning probability of the replay combination is about 1/7.29 here. there is Then, when BBA or BBB is won in this game state and shifts to inside BBA or inside BBB, it shifts to "RT" where the winning probability of the replay combination is 1/4.93. In addition, after the setting is changed in "During 2-bet BB (during BBB)", which is "During BB inside" that has been shifted by winning in a double-bet game, the BB inside state and RT state are initialized. maintained without

The state during "RT" continues until BBA or BBB wins, and the symbol combination of "blank-white BAR-cherry" is aligned on the predetermined effective line, and BBA wins or "blank-" on the predetermined effective line. When the symbol combination of "blank-cherry" is complete and BBB wins, the next unit game is started as "BBA game (during BBA)" or "BBB game (during BBB)". Then, when the total number of medals paid out during the "BBA game" reaches 45 or more, or when the total number of medals paid out during the "BBB game" reaches 10 or more, the game state is resumed. Becomes "non-RT".

In this way, the slot machine of the type described here cyclically transitions between the three game states of "non-RT", "RT", and "BB game". Also, in any game state, even if the power is turned off and then on, the game state before the power is turned off is maintained, so once the state shifts to the RT state, turning the power on or off will not turn on the RT. it will be difficult to move to Also, when it is "inside the BBA", if the setting is changed, the RT state of "inside the BBA" will be cleared and it will be in the non-RT state, but even if the setting is changed, the RT state inside the BBA will be maintained. may

In addition to the above-mentioned game characteristics, for example, it is possible to win only by betting two coins (or it is easy to win). It is also possible to adopt a game property such that the RT transition is not performed inside the BBA that does (or is likely to be elected). By doing so, it is possible to provide a game feature that does not require being "inside the BBA" as an essential condition for the trigger of transition. In this case, the probability of the internal lottery if the RT does not move to "BBA inside" is the same (or the same) as "non-RT", and it is possible to allocate the winning number of "non-RT" BBA to the loser. be.
<Various measures for further optimization of pachinko and pachislot machines>

Next, various measures for further optimizing each type of slot machine described so far will be described. Specifically, with respect to the slot machine of the type having the specified number changing function, measures for improving the specified number changing function will be described. In addition, for a wider range of slot machines, including those equipped with a stipulated number change function, measures to improve the functions of various operating devices when the power is turned on will be described.
<Measures related to improving the function of changing the specified number>
<<Background of invention related to each countermeasure>>

First, we will explain the countermeasures for improving the stipulated number changing function of slot machines of the type equipped with the stipulated number changing function. After that, we will explain each improvement measure while dividing it into items.

First, many slot machine models in recent years have been provided with a specified number changing function in slot machines as illustrated in FIGS. 51 to 58(b). In addition, the prescribed number changing function enables a game with a two-coin bet (also referred to as a "two-coin bet") and a three-coin bet (also referred to as a "three-coin bet") game. Furthermore, in the slot machines of the type shown in FIGS. 51 to 58(b), there are two-coin bet game states (two-coin bet game states) and three-coin bet game states (three-coin bet game states). , the probability of winning a role, the probability of winning an AT, and the mode of presentation are made different.

One of the reasons why this type of slot machine has appeared on the market can be explained as follows. For example, it can be said that a more favorable situation for a player is to play a game under a gaming state in which he or she can expect to win as many game medals as possible. However, for example, making it possible to obtain several hundred game medals in one BB, or making it easier to continue BB, the gambling nature may temporarily become excessive.

For this reason, instead of allowing a large number of game medals to be obtained in a short period of time, the current trend is to gradually increase the number of game medals obtained over an appropriate amount of time. As for such game characteristics, for example, in a situation where BB is won in the role lottery and BB has not yet been won, a small win with a moderate number of payouts (8 payout bells, etc.) It is known that the player can win multiple times (several tens to hundreds of times), and the number of game medals obtained gradually increases as the number of games increases.

For example, using the slot machine shown in FIGS. 51 to 58(b) as an example, BB (here, BBA or BBB), during BB (during BB game), a predetermined limited number of sheets (here, 45 or 10) game medals are paid out, the game is terminated. After the BB ends, the game state returns to the "non-internal" state. In other words, even if the player hits the BB, many game medals cannot be obtained during the BB.

However, during the period of "inside the BB", in most cases, one of the winning combination (eg, 8-card combination), replay, and 1-card combination is established. Then, during the period of "inside the BB", these small winnings and replay winnings (replaying winnings) are drawn in (shifted), and symbol control (rotor control) is performed so as not to establish a combination of symbols that are out of range as much as possible. ) is to be carried out.

Furthermore, during the period of "inside the BB", the number of deviations is minimized (for example, 1/65536), or the number is set to zero (zero) so that deviations do not occur at all. there is In the slot machines shown in FIGS. 51 to 58(b), as shown in FIG. 57, the winning numbers inside the BBB are 0 (both bets of 2 and 3).

In addition, when the BB wins during ``inside the BB'', the ``inside the BB'' ends immediately and the game state shifts to the BB game. Therefore, during "inside the BB", the operation order navigation (push order navigation) relating to the stop buttons (24L to 24R) is performed, and if the stop buttons (24L to 24R) are operated according to the push order navigation, , BB winning can be avoided.

In the slot machines shown in FIGS. 51 to 58(b), there are many games in the ``inside the BB'', such as push-in roles (8-card roles, etc.), replays, and 1-card roles (several tens to several By repeating the 100 games, the player can obtain more game medals than the BB even after deducting the number of bets.

However, when "inside the BB" is utilized in this way, the number of game medals owned by the player is difficult to decrease during the "inside the BB", so the so-called base tends to increase. In addition, the number of game medals is less likely to decrease due to frequent use of the one-card combination, and the base tends to increase.

In other words, by providing a period during which the player receives the payout of game medals at a moderate pace during the "BB" period, even if the number of acquired medals is greater than or equal to the number of inserted medals, it may be less than the number of inserted medals. In both cases, it becomes difficult to create a sense of speed in the game.

Furthermore, when the one-coin hand is often used during the "BB inside", the number of medals for the player is reduced by three if the three-coin bet game is lost, but only two medals are awarded when the one-coin hand is established. It will not decrease. For this reason, when the one-card combination is frequently used, the pace of consumption of the game medals slows down, making it even more difficult for the base to drop.

For these reasons, it is difficult to provide a game that allows players to concentrate on increasing the number of medals in a relatively short period of time. There was an aspect that it was difficult to generate. In addition, there have been cases where the slot machine lacks interest due to the fact that so-called "waves" are less likely to occur.

Under such circumstances, it has become possible to improve the taste by providing the function of changing the specified number as described above and devising the uses of the two-coin bet game and the three-coin bet game.

For example, to provide a game feature such that, in a two-coin bet gaming state, a part of the three-coin betting gaming state is not won, and in a three-coin betting gaming state, a part of the two-coin betting gaming state is not won. became possible. As a result, a winless combination is provided for each game state, and it is possible to provide a loss of "inside the BB" in a new manner different from that up to that point.

Then, the difference in the game state between the period in which the game medals of the player increase and the period in which the game medals decrease can be clearly expressed, and such a difference in the game state is used to improve the amusement. became possible.

In this way, a slot machine of a type having a specified number changing function can provide players with a two-coin bet game and a three-coin bet game. ), it is common for the power supply to start up in the "non-internal" state.

Further, in a slot machine of a type having a specified number changing function, the power supply is turned off during "inside the BB" (hereinafter referred to as "inside the BB bet two") that has been won by a two-coin bet game. Even if the power is turned on from the power on or the setting is changed when the power is turned on, the information of the control state is maintained and the game state is kept as "inside the BB bet two". On the other hand, "inside the BB" (hereinafter referred to as "inside the 3-bet BB"), which has been won by a 3-coin bet game, changes the setting when the power is turned on after the power is turned off. When this is done, the control state information is initialized (cleared), and the game state returns to the minimum set value and the "non-internal" state.

In other words, even if the setting change device is activated after the power is turned off from "during 2-bet BB" and then turned on, "during 2-bet BB" is maintained without returning to "during non-inside". After the power is turned off from "inside 3 bet BB" and then turned on, if the setting change device is activated, there is one that returns to "inside inside". In addition, when the setting change device is activated after the power is turned off and then turned on during "during 2-bet BB" or "3-bet BB", the state returns to "non-internal".

The reason why there is a difference in processing between "during the 2-coin bet BB" and "3-coin bet BB", can be explained as follows. For example, basically, a slot machine developer is told that once "inside the BB bet 2", the slot machine is no longer used in the gaming arcade (until it is removed, etc.), "2 It can be said that there is an idea of wanting to maintain "inside the number bet BB".

However, if the design was made so that when the power is turned on after the power is turned off during the "double bet BB inside", it returns to "non-inside" when the setting is changed. If you do not perform "advance preparation", you cannot enter "during 2 bet BB". Therefore, when the game state is "inside the 2-bet BB", even if the setting change device is activated when the power is turned on, the state does not return to "inside the inside".

On the other hand, in the case of "3-bet BB inside", if the RT state is maintained as a gaming state without becoming "not inside" when the setting change device is activated when the power is turned on, the setting change can be performed. After the accompanying power is turned on, the game state becomes "inside 3 bet BB". In order to change from this state to ``inside the 2-bet BB'', the pattern of the 3-bet BB is aligned once to win a prize, and the game is executed (digested) until the end condition of the 3-bet BB is completed, and then ``no'' is reached. After that, it is necessary to perform a two-coin bet game and shift to "inside the two-coin bet BB".

Furthermore, the 3-bet BB can be won only when it does not win a role such as a push order (8-card hand, etc.), replay, 1-card hand, etc. (when lost). It is not always possible to win the 3-coin bet BB immediately after winning the BB bet 3-coin. In addition, the number of payouts per game is 8, 1, etc., even in the "3-bet BB mode", and the number of game medals (slot machines shown in FIGS. In the case of , it takes several tens to hundreds of games to complete the payout of 45 or 10 coins) and consume the BB, which may require a considerable amount of time.

Due to these circumstances, when the power is turned off with a setting change such as when the power is turned off, such as when the 3-bet BB is inside, initialization is performed to quickly shift to the "non-inside" state. can do. As a result, it is possible to shift from "inside the 3-bet BB" to "inside the 2-bet BB" as quickly as possible.

Furthermore, unlike the types described above, changing the setting does not initialize (clear) the information of "During 2-bet BB" and "During 3-bet BB" information, but "During 2-bet BB". Some slot machines initialize (clear) the information "Betting 3 BB".

In addition, as one of the behavior patterns often seen by players, there is a three-coin bet game during "non-inside". For this reason, when the slot machine shipped from the factory and installed in the game hall as described above is provided for the game of the player as it is in the game state, the three-coin bet game is performed in the situation where the two-coin bet game should be performed. A betting game will be played.

In such a case, it is impossible to win the combination that is assigned only to the two-coin bet game and not to the three-coin bet game, as described above. Such a situation can be said to be, for example, a situation in which the winning combination corresponding to the game played by the player cannot be performed.

Furthermore, as described above, there is a difference in the contents of effects, selection ratios, etc. between the 2-coin bet game and the 3-coin bet game. As a result, there is a discrepancy between the actions of the player and the intention of the developer, and the player cannot experience the highly entertaining performance intended by the developer.

Specifically, even though the player is playing the game as usual (three-bet game) based on the game characteristics of other machines and their previous experience, there is no change in the production. , there may be a situation where no special effect that enhances interest appears at all. Such a situation can also be said to be, for example, a situation in which an effect corresponding to the game played by the player cannot be performed.

In addition, as described above, depending on the type of slot machine, even if the power is turned off and then turned on, it does not return to "during non-inside" depending on the type of slot machine. In addition, the game characteristics of "2-bet BB inside" and "3-bet BB inside" have many changes in production (the production is rich in variety) compared to "non-bet BB". is normal.

For this reason, if the game hall operates the slot machine "inside the BB bet two", it can provide the game machine to the player with a relatively highly interesting game, and at the same time, it is possible to change the settings. can be as simple as possible.

Under these circumstances, game machine manufacturers are urging game arcades to operate slot machines in the state of "inside the BB bet two". For example, game machine manufacturers provide information to game arcades to start operations after the inside of the BB in the 2-bet game state (while the BB is in the 2-bet state).

More specifically, the gaming machine maker provides the gaming facility with information requesting non-commercial gaming in a two-coin bet gaming state over a certain number of games before it is first made available to players after installation. providing. In amusement arcades, a clerk plays several games to several tens of games with a two-coin bet and wins the BB by himself (by himself) in the two-coin bet gaming state.

In this way, the state from the factory shipment to when the game parlor clerk says "inside the 2-bet BB" is sometimes referred to as "preparing". In the following, the term "in preparation" will be used, and basically the work of the game parlor clerk to "bet two coins inside the BB" for non-commercial purposes will be referred to as "preparation".

Both the player and the gaming facility can benefit from the operation of the slot machine with such "advance preparation" in the "during the 2-bet BB" gaming state. For this reason, during the operation of the amusement arcade, the state of "inside the 2-coin bet BB" is maintained as much as possible. It can be said that the situation in which the game is played is a goal (objective) for both the player and the game arcade.

However, not all arcades will take the recommended action with certainty. In addition, if the provision of information to the gaming facility is insufficient, or if the gaming facility fails to carry out "advance preparation" work, both the player and the gaming facility will not be able to enjoy the benefits. . Also, it is conceivable that the RWM is initialized due to some unexpected situation (circumstances), and the game state becomes "not inside". Furthermore, as a result of these, the slot machine may receive an unfair evaluation from the market.

Under such a background, the inventor examined various countermeasures so that the stipulated number changing function could be used legally and could perform its original function more reliably. For example, the purpose of the countermeasures is to enable the staff at the amusement arcade to smoothly perform work during preparation, or to enable the players to recognize the state of the amusement machine. Various studies were conducted on concrete measures for the purpose.

Various countermeasures (prescribed number change function optimization countermeasures) examined by the inventor will be described below in order while dividing into items. It should be noted that the various countermeasures described below can be used together as long as there is no particular problem.

In addition, there are cases where proper preparations are not made, for example, a situation in which a clerk at a game parlor is playing a three-coin bet game while ``not inside'', or a player is playing a game in a ``non-inside'' state. In the sense that the game state is not "inside the 2-bet BB", it is assumed that "advance preparations" are being made. Give an explanation.
<<Prescribed number change function optimization measure 1 (selective output of payout sound)>>

First, as a first measure related to optimization of the specified number change function, the inventors considered making it possible to easily recognize the game state by devising the output mode of the payout sound of "preparing". Furthermore, during the "during preparation", it is considered that a payout sound is output in a game state advantageous to the player, and is not output in a game state disadvantageous to the player.

Specifically, a situation is assumed in which a three-coin bet game is played during "preparation" and the state has not yet reached "inside the two-coin bet BB". In this case, the situation should be such that the clerk of the amusement arcade should play the game with a two-coin bet in order to make it "inside the two-coin bet BB". However, this measure assumes that the information on "preparation" was not accurately conveyed to the staff at the amusement center, or that the habits and habits acquired even though there is an intention to bet on two coins. This is a situation in which a game is being played with a 3-coin bet during a "non-internal" period due to circumstances such as pressing the MAX bet button (three-coin button 76).

Such a situation may be referred to, for example, as a "bet 3 not inside" or "bet 3 while not inside" situation. Then, even if the "advance preparation" is not properly performed, if the player does not recognize it, as shown in FIG. is normal.

In addition, compared to the above-mentioned "during 3-bet BB", the "3-bet BB inside" that transitions from the "3-bet non-inside" to the 3-bet BB is more difficult than the "2-bet BB inside". Similar to "medium", it is easy to obtain a large number of game medals, which is advantageous for the player.

Based on these facts, when a 3-coin bet game is played during "non-internal" or "inside 3-coin bet BB" (when it is relatively advantageous for the player), a payout sound is output. to In other words, in the 3-bet game of "non-internal" or "3-bet BB internal", the combination for which game medals are paid out (here, 8-card combination, slots in FIGS. 51 to 58 (b) In the case of a machine, bells 1 to 5 and watermelons 1 to 4 correspond), and the symbol (or symbol combination) corresponding to the winning combination is stopped by operating the stop button (24L to 24R). Then, the number of game medals corresponding to the established combination is paid out (or credited). At this time, as an effect relating to the payout of game medals, a payout sound is output. The above-described speaker 50 is used for outputting the payout sound.

On the other hand, when a 3-coin bet game is played during "3-coin bet BB" (when it is relatively disadvantageous for the player), the aforementioned payout sound is not output. Here, "relatively disadvantageous to the player" means that "during the BB" is disadvantageous to the player compared to "during the BB". Specifically, in the 3-bet BB game, there are 8 payouts (Bell 1-5, Watermelon 1-4 in the example of the slot machine shown in FIGS. 51-58(b) ) is established. In addition to this, if the game can be played by betting one coin during the BB, betting three coins increases the number of game medals used during the BB. It is possible to describe the three bets as "unfavorable".

According to such prescribed number change function optimization measure 1, the output of the payout sound is selectively performed in a relatively advantageous state or a relatively disadvantageous state for the player. When a three-coin bet game is played in the "non-inside" or "inside the three-coin bet BB" which is relatively advantageous for the player, the payout sound is output, while the game is relatively disadvantageous for the player. By not outputting a payout sound when a 3-coin bet game is played during ``during 3-coin bet BB'', the game state shifts to a disadvantageous one due to an accident during the game during ``preparation''. Even if it happens, the player can easily notice it.

Here, the players who play the game during the "preparation" are assumed to be game parlor staff who are expected to play games outside the operating hours of the amusement facilities, and players who are expected to play during the operating hours of the amusement facilities. You can mention the visitors who will be. Further, when a replay (replay) symbol combination is established during the BB, the game state is deemed to be advantageous to the player, and a sound effect (replay sound) accompanying establishment of the replay is output. can be considered to be

In addition, the situation in which the player is playing the game during the "preparation" is a situation in which the performance and role lottery cannot be performed under the conditions that the player could originally enjoy. However, by informing the player whether the game state at that time is advantageous or disadvantageous depending on whether or not the payout sound is output, the player can decide whether or not to continue the game at the slot machine. It can provide information for decision making. Then, it becomes possible to help a player put in a disadvantageous situation to get out of that situation.

In addition to this, for example, when winning a 1-coin hand during "non-internal" and making a payout related to the winning hand, even if a 2-coin bet wins the 1-coin hand, a 3-coin bet is possible. It is conceivable to prevent the payout sound from being output even when the player wins the one-card combination. Also, for all game states except for "non-internal", it is conceivable not to output the payout sound when a one-card combination is won and a payout related to the winning combination is performed.

Also, it is conceivable to perform an effect according to the situation during the "during preparation" until "during the inside of the 2-bet BB" after the power is turned on. As output means for effects, the effect section 18, the lower panel 19, the speaker 50, various other LEDs, and the like can be used.

As a specific effect mode, for example, the effect unit 18 displays characters such as "bet 2" during "not inside", or the lower panel 19 is extinguished (or blinked). ), making the illumination LED of the front door portion 11 blink in a color corresponding to the situation, and the like. It is also conceivable to prevent the front door portion 11 from blinking from betting setting (betting) to completion of one game (third stop button, etc.).

Furthermore, while the reel (rotating drum) is rotating, the effect section 18 may perform effects to that effect (predetermined mark display, predetermined video display, etc.), or the lower panel 19 may start blinking. be done. It is also conceivable that the operation of the start lever 25 is used as a trigger to switch the effect from the previous effect to another effect.

It is also conceivable to perform a predetermined effect display on the effect unit 18 from the time the start lever 25 is operated, and to continue the effect display until one game is completed (third stop button, etc.). Furthermore, the number of games from the start of the ``preparation'' to ``within the BB bet 2'' (or ``within the BB bet 3'') is added (cumulatively displayed) on the effect section 18. Other things can also be considered. Furthermore, as long as there is no particular problem, it is also possible to appropriately combine the various specific aspects exemplified here.

It should be noted that such a cycle may occur when the transition from "advance preparation" to "during 2-bet BB inside" is followed by "during 2-bet BB", and then shifting again to "non-inside". In the case of repetition, or in the case of transitioning from "Preparation" to another game state ("2 bet BB inside", etc.) and then to "Preparation" again, each "non-inside" can correspond to "under preparation". Furthermore, regardless of the situation, it is possible to make the combination of the game state and the mode of the payout sound correspond to each other.

In addition, output control of the above-described payout sound, illumination of the front door section 11 and lower panel 19, and output control of the production section 18 can be processed based on a command (main command) transmitted from the main control board 61. The image control board 32 can be used by the sub-control board 31 or without the image control board 32 . This point also applies to various measures for optimizing changing functions and measures for improving functions of operation devices, which will be described below.

In addition, the basic configuration of the game machine to which such prescribed number change function optimization measure 1 (selective output of payout sound) is applied can be expressed as follows, for example.
a plurality of reels;
a start lever and
and a plurality of stop buttons,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
In a game in which a predetermined combination is won in the combination lottery, when a symbol combination related to the predetermined combination is displayed on the plurality of reels as a stop display, a predetermined number of game media (game medals, etc.) for the predetermined combination is displayed. payment becomes possible,
A predetermined payout sound can be output at the time of payout of game media,
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
A game in the first winning state (“2-bet BB” game, etc.) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state,
A game in the second winning state (such as a "3-bet BB" game) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state,
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
outputting the payout sound for the second bet number game in the predetermined gaming state;
The output of the payout sound is not executed for the second bet number game in the second winning state,
A gaming machine characterized by outputting the payout sound for the second bet number game in the second internal winning state.
<<Prescribed number change function optimization measure 2 (notification of transition to non-internal medium)>>

Subsequently, as another countermeasure, at the end of the payout related to the final game (final game) of "during 3-bet BB" in "during preparation", the effect state is changed to the effect state corresponding to "non-internal". considered doing so. In other words, when the BB game ends and the game state shifts to "non-internal", the start timing of the effect corresponding to "non-internal" is set to the completion of payout of game medals for the final game related to the BB game. It was considered to be the timing after the

For example, the player presses the stop button (corresponding one of 24L to 24R) for stopping the spinning drum (one of 51L to 51R) at the end, and presses the stop button (third stop button), game medals are paid out one by one corresponding to the stopped symbol combination, and the payout sensor (not shown) detects the number of game medals paid out corresponding to the stopped symbol combination, and the payout is completed. Then, the effect state is changed to the effect state corresponding to "non-internal".

Here, "to set the production state corresponding to 'non-inside'" means to execute the production that can be executed 'in non-inside'. Execution of the same mode as a part of the performance, or a mode similar to a part of the performance that can be executed "non-internally" in details, but similar enough to be recognized as the same by the player. , etc. can be exemplified.

Furthermore, as a mode of transition from "during 3-bet BB" to "representation state corresponding to "non-internal"", for example, as shown in FIG. Assuming that there is a screen (ending effect screen) displaying the number of game medals obtained in the basic background, as shown in FIG. Here, a mode such as shifting to a beach scene) can be exemplified.

In addition, as the “effect state corresponding to “non-inside”” here, a effect in which no sound is output, a effect in which a low sound that is normally inaudible to the player is output, etc. can be exemplified. And the "sound" as the effect here is not something that is output in accordance with the player's operation, such as the sound accompanying the player's betting operation, for example, but is automatically generated without being linked to the player's operation. Sound such as BGM (background music, background music) that progresses dynamically can be exemplified.

Further, as described above, it is possible to exemplify that the light emission mode (emission target, light emission pattern, etc.) of various light sources for presentation provided in the front door section 11 is the same as "non-inside".

According to such regulation number change function optimization measure 2, the timing of returning to the "non-internal" production state is set after the payout is completed, so that the player notices the transition to "non-internal". You can reduce the number of situations that would never happen.

In other words, during the BB, the player normally pays attention and pays attention to the acquisition of game medals, which are game values. For this reason, unless the transition to "non-inside middle" is properly notified, the player cannot accurately grasp the game state, and the player cannot determine whether or not to continue the game at the slot machine. It is conceivable that the opportunity to obtain information for making judgments will be lost.

However, as in the specified number change function optimization measure 2, the timing of returning to the "non-internal" production state is after the completion of the payout, so that the player is distracted by the game and the game state changes. It is possible to prevent the occurrence of a situation in which the player is not aware of the situation, and it is possible to make it difficult for the player to make a mistake in selecting the game method to be taken thereafter.

As for the situation in which the payout is completed, for example, if the end condition of the 3-bet BB is that 45 or more game medals have been paid out during the BB, exactly 45 game medals have been paid out. A situation in which the payout is completed can be exemplified. In addition, not limited to this, when the number of paid out cards at that time is 40, the number of paid out cards is 8, and the payout of 48 cards, which exceeds 45 cards in total during the BB, is completed. The situation can also be exemplified.

In addition, the basic configuration of a game machine that implements such prescribed number change function optimization measure 2 (notification of transition to non-internal medium) can be expressed as follows, for example. .
a plurality of reels;
a start lever and
a plurality of stop buttons;
Equipped with production output means (production unit, illumination, speaker, etc.) capable of outputting production,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
In a game in which a predetermined combination is won in the combination lottery, when a symbol combination related to the predetermined combination is displayed on the plurality of reels as a stop display, a predetermined number of game media (game medals, etc.) for the predetermined combination is displayed. payment becomes possible,
A predetermined payout sound can be output at the time of payout of game media,
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
By stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state, it is possible to play a plurality of times in the first winning state (such as a "2-bet BB" game),
By stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state, it is possible to play a plurality of times in the second winning state (such as a "3-bet BB" game),
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
The gaming machine is characterized in that, at the end of the payout for the final game in the second winning state, the game machine shifts to an effect related to the predetermined game state ("non-internal" effect, etc.).
<<Prescribed number change function optimization measure 3 (Immediate notification of inappropriate state (Part 1))>>

Subsequently, as another countermeasure, different effects are executed in the regular case of winning the 2-bet BB in the "non-internal" state during the "during preparation" and in other cases (illegal cases). I considered.

For example, when the 2-bet BB wins during the "non-internal" period, a predetermined effect (herein referred to as "first effect") is executed, and when the 3-coin bet BB wins during the "non-internal" period, another effect is executed. (Although it can be called a "specific effect" or a "second effect", it will be referred to as a "second effect" here).

Here, the above-mentioned "when you win", the main control board 61 related to the 2-bet BB or the 3-bet BB sends the condition device command (process of the condition device command set in FIGS. 15 and 16) to the sub-control board 31. is with the situation after it is received. However, it is not limited to this, and it is also possible to define "when winning" as, for example, a situation during the game in which the two-coin bet BB is won in "non-inside".

In addition, the control of various LEDs (lamp control) does not necessarily have to be performed by the sub control board 31 (sub main CPU 86). It is possible. Then, when the main control board 61 (main CPU 81) controls the corresponding LED to execute the first effect or the second effect, the above-mentioned "when winning" is performed by the main control board 61. , it is possible to set a predetermined time (timing) after the conditional device for the two-coin bet BB or the three-coin bet BB wins.

Furthermore, even if the 2-coin bet BB wins during the 'non-internal' period and the first effect is executed, if the 2-coin bet BB wins after that, the 3-coin bet BB wins in the 'non-internal period'. The second performance is executed in the same manner as when. Here, as the timing of "winning", for example, the timing after the symbols stop and the winning determination (display determination (S66)) is made in the combination related to the winning of the 2-bet BB, or the winning The period (timing) after the determination is finished and the game end process (process at the time of game end (S68)) is executed can be exemplified. These periods can be collectively referred to as, for example, a predetermined period (timing) after a predetermined combination of symbols relating to the winning combination has stopped.

By doing so, it is possible to shift from "non-inside", which is an appropriate game state transition mode (appropriate game flow) with respect to "advance preparation", to the win of the 2-bet BB (transition corresponding to the assumed game flow). ), a situation where there was a transition from the inappropriate game flow "non-internal" to a win of the 3-bet BB (a transition that does not correspond to the assumed game flow), and a situation where the 2-bet BB won a prize A different effect can be executed in a situation where there is a transition to (transition that does not correspond to the assumed game flow).

Then, when the game progresses with an inappropriate game flow, the fact can be immediately notified by the second effect. Furthermore, it is possible to prevent the player from being confused or uncertain about how to proceed with the game at that point.

In addition, if the player does not grasp the game state, it is difficult for the player to take action to get out of the game state at that time. It is possible to encourage the player to remedy the situation.

And it can be said that the second effect executed in this way notifies the outside that the "advance preparation" is not finished. Various effects can be adopted as the second effect. For example, it is an inappropriate situation, such as text display or voice output of "Aim!" It is conceivable to adopt a form in which notification to that effect can be made.

Here, if the number of types of the second effect is increased, it may become difficult for the player to know that the second effect is being performed, and it may become difficult to grasp the effect situation. For this reason, for example, it is conceivable that the second effect for winning the BB bet 3 and winning the BB bet 2 has the same content (mode) (commonization of the effect mode). In particular, when performing the second effect with LEDs, the type of effect (amount of information) that can be performed in a way that the player can identify with the LEDs is considered to be less than the effect with still images and moving images, so the effect mode Commonality is effective.

Further, the second effect may be, for example, blinking the illumination LED of the front door portion 11 in a predetermined color, turning off the lower panel 19, or the like. Furthermore, as long as there is no particular problem, it is also possible to appropriately combine the various specific aspects exemplified here.

In addition, "preparing" is assumed to be a game state before the game hall opens, and the production for "preparing" is the overall production performed during the game hall's business. It is considered that the usage frequency (appearance frequency, execution time, etc.) will be less than that. By creating and storing still image data and moving image data that can be displayed by the rendering section 18 for renderings that are used infrequently, problems such as an increase in cost and data capacity restrictions can arise. . Therefore, as the second effect, it is conceivable to perform (or frequently use) effects using LED illumination or sound without performing (or suppressing) effects by displaying still image data or moving image data.

It should be noted that the common second effect can be performed at the same timing in the case of winning the 3-coin bet BB during "non-internal" and the case of winning the 2-coin bet BB in "non-internal". . However, when the 3-coin bet BB is won during the "non-internal" period, and when the 2-coin bet BB is successful during the "non-internal" period, the timing of switching to the second effect (starting time of the second effect) may be different.

For example, if you win the 3-coin bet BB during "non-inside", it does not immediately shift to the second effect, but the final stop operation (pressing the third stop button, or pressing the third stop button) The second effect is executed with a predetermined operation (for example, operation of the start lever 25) after the operation of releasing the finger from. On the other hand, if the 2-coin bet BB is won during the "non-internal" operation, the final stop operation is used as a trigger to execute the second Allow the performance to run.

Further, it is also possible to provide a plurality of modes of the second effect, for example, to distinguish them as the second effect 1, the second effect 2, the second effect 3, etc., and to call them the second effect group or the like. However, these second effects include common display elements (backgrounds, characters, etc.) that are not included in the first effects, so that the player can combine the first effects and the second effects (group). It is desirable to be identifiable.

Furthermore, for example, it is possible to output a predetermined sound as the first effect, and perform an effect in which the "predetermined sound" is not output as the second effect (the "predetermined effect" is silent). is. Specifically, the first production is to produce a production accompanied by voice output such as "Complete", and the second production is to produce a production that does not accompany the output of "Complete". is possible.

It should be noted that the basic configuration of a gaming machine that implements such prescribed number change function optimization measure 3 (immediate notification of inappropriate state (part 1)) can be expressed as follows, for example. It is possible.
a plurality of reels;
a start lever and
and a plurality of stop buttons,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
A game in the first winning state (“2-bet BB” game, etc.) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state,
A game in the second winning state (such as a "3-bet BB" game) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state,
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
executing a first effect in a situation in which the first bet number game wins during the predetermined game state (such as a situation in which the game is played in an appropriate game flow);
In a situation where there is a win in the second bet number game during the predetermined game state (such as a situation in which the game is played with an inappropriate game flow), a second production different from the first production is executed,
When there is a win in the first bet number game during the predetermined game state, and when there is a stop display of the symbol combination related to the first winning state in the game in the first internal win state, the second effect is executed. A gaming machine characterized by:
<<Prescribed number change function optimization measure 4 (relief when inappropriate)>>

Subsequently, as another countermeasure, when a three-coin bet game is performed during "during preparation" and "during three-coin bet BB", functions such as AT and ART (the above-mentioned so-called instruction function) are activated. We considered making such processing (lottery, production, etc.) executable. Then, in a predetermined situation of "during the 2-bet BB" or during a 2-bet game in a situation other than "during the 2-bet BB", it is considered not to execute the processing related to the instruction function. . As the 'predetermined situation' in the above-mentioned 'inside the 2-bet BB', there is a situation in which a 2-bet game is played.

In this manner, the instruction function is executed during a three-coin bet game "inside the two-coin bet BB", but during a two-coin bet game "inside the two-coin bet BB" or "two-coin bet" It is possible to provide a slot machine that does not execute processing related to the instruction function in situations other than "while inside the betting BB". In addition, it is possible to provide a user-friendly slot machine that does not cause a loss to the player as much as possible (does not put the player at a significant disadvantage) even when the game is not in a game state in which the game should normally proceed during the "preparation". It becomes possible.

Further, as described above, visitors other than the game parlor clerk can also be players who play a game during "preparation". For this reason, as described above, the instruction function is executed during the three-coin bet game "during the two-coin bet BB", and during the two-coin bet game "during the two-bet BB" By not executing the processing related to the instruction function only in cases other than "inside the BB", the situations where the performance related to the instruction function and the lottery are not performed can be reduced as much as possible, and the taste for the visitors can be improved. can be prevented from decreasing.

It should be noted that, by adopting countermeasure 4, the processing related to the instruction function is valid only for one (one type) prescribed number such as "three bets". However, in the case of a slot machine equipped with a BB exclusively for betting two, the processing relating to the instruction function may be executed only during the BB, even in a situation where a two-coin betting game is played.

In addition, the basic configuration of the game machine to which such prescribed number change function optimization measure 4 (improper remedy) is applied can be expressed as follows, for example.
a plurality of reels;
a start lever and
a plurality of stop buttons;
Equipped with production output means (production unit, illumination, speaker, etc.) capable of outputting production,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
Has an instruction function (such as a push order navigation function) that instructs the operation order of the stop button in the production,
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
A game in the first winning state (“2-bet BB” game, etc.) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state,
A game in the second winning state (such as a "3-bet BB" game) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state,
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
A gaming machine characterized in that an effect related to the instruction function can be executed in the second bet number game in the second internal winning state.
<<Prescribed number change function optimization countermeasure 5 (Immediate notification of inappropriate state (Part 2))>>

Subsequently, as another countermeasure, different effects are executed in the regular case of winning the 2-bet BB in the "non-internal" state during the "during preparation" and in other cases (illegal cases). I considered. Furthermore, when preparations have been completed, we considered notifying the completion without confusion. Then, in this countermeasure, it is assumed that after the BB wins, the situation is such that the BB is "inside the BB" without allowing the BB to win.

For example, in the state of ``preparing'', when the player releases the third stop button in the third stop situation in the game in which the 2-bet BB is won, the game state changes to ``inside the 2-bet BB''. At that time, the above-described first effect (effect when the game flow is appropriate) is executed.

On the other hand, when the player releases the third stop button in the state of the third stop in the game in which the 3-coin bet BB is won during the "preparation", the game state changes to "3-coin bet BB inside". At that time, the above-described second effect (effect when the game flow is inappropriate) is executed.

By doing so, it is possible to provide the player with information for judging whether or not advance preparations have been completed without any problems, depending on the type and mode of presentation at the end of the game.

In other words, if the execution timing of the first effect when the game flow is appropriate and the execution timing of the second effect when the game flow is inappropriate are not properly determined, it is necessary to determine whether the advance preparations have been completed without any problems. It is unclear whether the player can recognize the material without misunderstanding.

Furthermore, if the start timings of the first effect and the second effect do not match, the player may erroneously recognize the timing of determining whether the advance preparations have been completed without any problems.

However, as in this countermeasure, both the first effect and the second effect are started at the timing when the third stop button is released. , can provide information for judging whether advance preparations have been completed without problems. Furthermore, by making the start times of the first effect and the second effect the same, it is possible to prevent the player from erroneously recognizing the timing of judging whether or not the advance preparations have been completed without problems.

By executing the first effect and the second effect after the completion of the stop operation, it is possible to establish a one-to-one correspondence between the situation after the end of the game and the effect indicating the propriety of the game flow. In addition, since the effect is started at the end of one game, the player may be surprised by the first effect or the second effect executed during the course of one game and may miss the subsequent stop operation. can be prevented.

In addition, this measure 5, for example, is designed to immediately notify whether or not the player has shifted to a game state not desired by the player (and whether or not the player has not shifted) when the advance preparation is performed. It can be said that there is Furthermore, in this measure 5, since the effect is started at the same timing for the 2-bet BB and the 3-bet BB, the notification timing (timing of start of notification, timing of execution, etc.) by the first effect and the second effect ) is hard to be misunderstood by the player.

It should be noted that the basic configuration of a game machine that implements such prescribed number change function optimization measure 5 (immediate notification of inappropriate state (part 2)) can be expressed, for example, as follows. It is possible.
a plurality of reels;
a start lever and
a plurality of stop buttons;
Equipped with production output means (production unit, illumination, speaker, etc.) capable of outputting production,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
A game in the first winning state (“2-bet BB” game, etc.) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state,
A game in the second winning state (such as a "3-bet BB" game) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state,
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
When the operation of the last operated stop button in the first bet number game (such as a game played in a proper game flow) is completed, a first effect is executed,
When the operation of the last operated stop button in the second bet number game (the game played in an inappropriate game flow, etc.) is completed, a second effect different from the first effect is executed. Characteristic game machine.
<<Prescribed number change function optimization measure 6 (Notification of prescribed number using continuity of production (Part 1))>>

Next, as another countermeasure, the inventors considered making it possible for the player to intuitively grasp the proper prescribed number (bet 2 or 3) during the "during preparation". For example, in the "during preparation", the 3-bet BB is not won in the "non-internal" 3-bet game, and BGM (background music, background music) is looped as an effect to be executed. It is assumed that the player hits the effect pattern of the effect (hereinafter referred to as "BGM loop effect").

Here, as the "BGM loop effect", for example, when the melody of a predetermined musical piece is reproduced (output) from the beginning to the end, it automatically returns to the beginning and repeats the melody. This "BGM loop effect" can be repeated until there is a scene or development of the effect, or a game state transition. Furthermore, the above-mentioned melody in the "BGM loop effect" is relatively short, for example, about several seconds (3 to 10 seconds) so that the player can easily recognize that it is looping even within a limited period of time. can be considered. Further, the "BGM loop effect" is such that the BGM continues to loop even after the game in which the "BGM loop effect" is executed ends (after the final stop operation is released), and the start switch for the next game is played. , the continuing BGM can be terminated. In other words, by operating the start switch for the next game, the continuing BGM is terminated when switching to another performance state, and when the performance state is not switched, the BGM continues as it is. Also, it is conceivable that the "BGM loop effect" ends after a predetermined period of time has elapsed after the end of the game in which the "BGM loop effect" was executed (predetermined timing after the final stop operation was released). When a predetermined period of time has elapsed, the BGM may be ended by transitioning to a demo screen, or the BGM may be ended by decreasing the volume of the BGM to 0. .

Then, as described above, in the "non-internal" three-coin bet game, the three-coin bet BB is not won, and the "BGM loop effect" is won, and the "BGM loop effect" is output. Then, when the next game is started with a 3-coin bet, it is assumed that the situation is a 3-coin bet game that is relatively advantageous to the player, and the BGM is changed from the output "BGM loop effect" to another effect. , at a predetermined rate.

However, similarly, in the situation where the 3-coin bet BB is not won in the 3-coin bet game of "non-internal", and the 'BGM loop effect' is won and the 'BGM loop effect' is output, When the next game is started with a 2-coin bet, the ``BGM loop effect'' is continuously output as it is, assuming that the game situation is a 2-coin bet that is relatively disadvantageous to the player. Such presentation shall continue with continuity. A lottery (drawing lottery) for determining a new performance is performed during the three-bet game, but the performance lottery is not performed during the two-bet game, so that the BGM can be played during the two-bet game. It is also possible to prevent a change from the "no BGM" situation in which BGM is not output to the "with BGM" situation in which BGM is output. In this case, it is possible to prevent the effect from being switched and the effect display (display in the effect section 18) from changing (changes in background, scene, characters, etc.).

By doing so, the "advance preparation" is completed, the effect is continuous in the 2-coin bet game which is the game of the prescribed number which is disadvantageous to the player, and the 3-coin bet which is the game of the prescribed number which is advantageous to the player. In the game, it is possible to make it so that there is a case where the performance is not continuous. Then, depending on the presence or absence of continuity of such effects, it is possible for the player to intuitively grasp the prescribed number when proceeding with the game. Also, in the case of a two-coin bet game, the background music continues, but the effect display does not change, which is a situation that cannot normally occur. becomes possible.

Here, the above-mentioned "advantageous to the player" is expressed as an advantage in the sense that it is easy to win the bell role with a large number of payouts, that the effect is easy to change, and that AT lottery can be executed. ing. Conversely, "disadvantageous to the player" is relatively disadvantageous in the sense that it is relatively difficult to win the role of the bell, it is difficult to change the effect, and the AT lottery cannot be executed.

Note that the effect with continuity is not limited to the "BGM loop effect", and for example, a continuous effect that is performed continuously over a plurality of games as described above can also be applied. In this case, when the first game of the continuous effect is executed by betting 3 coins and the next game is executed by betting 2 coins, the effect of the first game is not switched, so the player can intuitively proceed with the game. It is possible to grasp the specified number when doing.

Furthermore, as one aspect of the continuous performance, the ``BGM loop performance'' is performed in the previous game executed with the 3-coin bet, and the ``BGM loop performance'' is also performed in the next game with the 3-coin bet. It is also possible to consider the case In this case, when the "BGM loop effect" is executed in the preceding game and the 3-coin bet game is executed in the next game, the "BGM loop effect" is newly executed (BGM is output from the beginning). It is also possible to say that

It should be noted that the basic configuration of a gaming machine that implements such prescribed number change function optimization measure 6 (notification of prescribed number using continuity of effects (part 1)) is as follows. can be expressed as
a plurality of reels;
a start lever and
a plurality of stop buttons;
A production output means (speaker, etc.) capable of outputting production,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
The production includes predetermined background music (such as BGM),
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
A game in the first winning state (“2-bet BB” game, etc.) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state,
A game in the second winning state (such as a "3-bet BB" game) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state,
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
When the next game is started with the second bet number in a situation where there is no win in the second bet number game during the predetermined game state, but the effect of repeatedly outputting the background music is selected ( When the game is relatively advantageous to the player, etc.), the effect in which the background music is repeatedly output may be switched to another effect. The game machine is characterized in that the effect of repeatedly outputting the background music is not switched to another effect when a relatively disadvantageous game is being played.
<<Prescribed number change function optimization measure 7 (Notification of prescribed number using continuity of production (Part 2)) >>

Subsequently, as another measure, further development of the above-mentioned specified number change function optimization measure 6 (notification of specified number using continuity of presentation (part 1)) was examined. For example, during ``preparing'', the 3-bet BB is not won in the ``non-internal'' 3-bet game, and the ``BGM loop effect'' wins, and the ``BGM loop effect'' is output. When the next game is started by betting two coins in a state where the player is in a state where the player is playing, the 'BGM loop effect' is continuously output as it is. This point is the same as the specified number change function optimization measure 6 (notification of specified number using continuity of presentation (part 1)) described above.

Furthermore, when the 2-bet BB wins in the started 2-bet game, and the 3-bet game is performed during the 2-bet BB game which is the next game, the 3-bet game is originally a game. However, here, the "BGM loop effect" is continued as it is. Then, when the ``BGM loop effect'' loops and a 3-coin bet is made in a game immediately after the 2-coin bet BB is completed (a ``non-internal'' game), it is assumed that the game is advantageous to the original player. , BGM can be switched (switched if the condition for switching is satisfied).

By doing so, it is possible to configure such that the performance does not progress (is not switched) until the 2-bet BB game, which is more disadvantageous to the player than "inside the 2-bet BB", is completed. Then, due to the difference in the progress of the presentation, the player can continuously recognize that the situation is disadvantageous to the player from ``inside the BB bet 2'' to ``during the BB bet 2'', and stay there. It becomes possible to intuitively grasp the situation in which the player is in an inappropriate game state. Furthermore, by not executing the effect lottery for switching the effect during the "double bet BB", it is possible to prevent the change of the effect from occurring.

It should be noted that the basic configuration of a game machine that has such a specified number change function optimization measure 7 (notification of specified number using continuity of effects (part 2)) is as follows. can be expressed as
a plurality of reels;
a start lever and
a plurality of stop buttons;
A production output means (speaker, etc.) capable of outputting production,
A plurality of patterns are attached to the reel,
On the condition that a predetermined number of bets has been set, a game involving a lottery can be executed,
The production includes predetermined background music (such as BGM),
The predetermined number of bets includes a first number of bets (such as 2) and a second number of bets (such as 3) different from the first number of bets,
A first bet number game (such as a two-bet game) contingent on the setting of the first bet number, and a second bet number game (three bets, etc.) on the condition that the second bet number is set. gambling games, etc.) are possible,
Winning the role lottery in the first bet number game enables a first internal win state game (such as a game of "2-bet BB inside"),
Winning the role lottery in the second bet number game enables a second internal win state game (such as a "3-bet BB internal" game),
A game in the first winning state (“2-bet BB” game, etc.) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the first internal winning state,
A game in the second winning state (such as a "3-bet BB" game) becomes possible by stopping display of a predetermined symbol combination on the plurality of reels in the game in the second internal winning state,
The first number of bets in a predetermined gaming state (such as "non-internal") different from any of the first internal winning state, the first winning state, the second internal winning state, and the second winning state The game flow in which the game is shifted to the first internal win state and the second bet number game is performed is defined as an assumed game flow (appropriate game flow, etc.) which is one assumed game flow,
During advance preparation in which a game is played in the predetermined game state until the transition to the first internal winning state,
When the next game is started with the second bet number in a situation where there is no win in the second bet number game during the predetermined game state, but the effect of repeatedly outputting the background music is selected ( If the game is repeated with an inappropriate game flow, etc., the effect in which the background music is repeatedly output may switch to another effect, but if the first bet number is started (with an appropriate game flow (such as when returning to the game), the effect in which the background music is repeatedly output does not switch to another effect,
The next game is started with the first bet number, and the second bet number game in the first winning state is played in the next game after shifting to the first winning state through the first internal winning state. In the case (such as when a BB game is played in an appropriate game flow), the effect of repeatedly outputting the background music is not switched to another effect, and the game in the first winning state is completed. When the second bet number game is played in the game (when the game is played with an inappropriate game flow, etc.), the effect of repeatedly outputting the background music is switched to another effect. It is a game machine characterized by obtaining.
<<Prescribed number change function optimization measure 8 (facilitating double bet BB winning)>>

Subsequently, as another countermeasure, it was examined to make the winning of the 2-bet BB (establishment of a symbol combination) easier than the winning of the 3-bet BB (establishment of a symbol combination). For example, the symbol combination for winning the 2-bet BB and the symbol combination for winning the 3-bet BB are different from each other only in the symbols of one reel, and the 2-bet BB is the winning symbol. is easier to pull in.

Here, as a mode for making it easier to attract symbols related to winning, the symbols necessary for winning are set within the maximum number of symbols (here, 4) that can be drawn (shifted) (so-called number of frames). Alternatively, it can be exemplified by arranging a large number (two or more) within the number of symbols (five frames, six frames, etc.) close to the number of symbols (here, four frames).

More specifically, for example, the win of the 2-bet BB is established by "Bell A, Watermelon, White BAR" and "Bell A, Watermelon, Black BAR". , "bell A, black BAR, white BAR" and "bell A, black BAR, black BAR".

The relationship between the win of the 2-coin bet BB and the win of the 3-coin bet BB is different from each other only by the pattern of one reel (in this case, the middle reel) (“Watermelon” and “Black BAR”). Furthermore, both symbols ("black BAR" and "watermelon" in this case) are designed so that the "watermelon" associated with the winning of the 2-bet BB is easier to attract than the "black BAR" associated with the winning of the 3-bet BB. ”) determines the number of symbols and the arrangement of the symbols. For example, in the example of FIG. 51, there are two "watermelons" (symbol numbers 14 and 18) on the middle reels making up the 2-bet BB, and "black BAR" on the middle reels making up the 3-bet BB. ” (symbol number 19), it is easier to win a prize in the 2-bet BB than in the 3-bet BB.

By doing so, it is possible to realize a game property such that winning a 2-bet BB can be shifted to the BB more easily than winning a 3-bet BB. In addition, only one reel (in the above example, only the middle reel in the above example) is different in the symbol combination related to the winning of the 2-bet BB and the 3-bet BB, and furthermore, "black BAR" and "watermelon" on the middle reel are adjacent to each other. Since it is correct, in both cases when winning the 2-bet BB during the 2-bet game and when winning the 3-bet BB during the 3-bet game, aim for the 4th "blank" on the middle reel. It is possible to make it inside by the same procedure such as. Therefore, it is possible to standardize the procedure for internalization.
<<Prescribed number change function optimization measure 9 (example of combination of measures related to inappropriate notification)>>

Next, an example of a combination of countermeasures when the game is progressed with an inappropriate game flow during "during preparation", "during BB", etc. will be described. For example, when a three-coin bet game is performed in the next game after a two-coin bet game is performed in the "non-inside" mode, the above-described second effect such as "Aim!" Furthermore, the screen of the production section 18 is turned black.

Darkening here is, for example, displaying the screen so that it becomes dim, and even if the text "Aim!" and other display contents (background, characters, symbols (including user interface), etc.) are dim It is conceivable to make it visible. Here, examples of the above-described user interface include various selection buttons on the menu screen (FIG. 60(a)) and symbols for informing the player of the state of the gaming machine. Further, as the darkening, a mode such as a black display in which characters, symbols, etc. cannot be visually recognized can be exemplified.

Furthermore, since a game flow in which a three-coin bet game is performed "during the two-coin bet BB" is regarded as an appropriate game flow, when a two-coin bet is performed "during the two-coin bet BB", It is possible to notify the fact that it is inappropriate by means of a presentation. As an effect in this case, it is possible to exemplify a blackout.

It should be noted that the following can also be considered as an effect mode when the screen is turned dark. For example, "BB bet 2" or "BB bet 3" is performed as an inappropriate game flow, and the production unit 18 displays the remaining number of medals (the number of remaining game medals) related to the BB game end condition. is displayed (e.g., when the characters "remaining _3" are displayed), only the predetermined display such as the remaining number of sheets is selectively maintained in a clear state without being dimmed, and the screen Darken the rest of the inside.

Also, when a 3-bet game is played "not inside", a voice message such as "Please bet 2" is output, and 2-bet is made during "during 2-bet BB". When done, it is possible to output a voice such as "Please bet 3 coins". The output timing of these voices can be, for example, the operation timing of the start lever 25 . Furthermore, even if the operation of the start lever 25 is performed before the predetermined time (here, 4.1 seconds), which is the minimum game time (shortest game time), the operation of the start lever 25 It is conceivable to output these voices with timing. As a result, it is possible to notify immediately without waiting for the rotation of the reel (rotating drum), and to quickly inform the operator that the operation was erroneous.

Furthermore, it is conceivable to determine the relationship between the image, illumination, and sound (including BGM here) during "inside the 2-bet BB" and "inside the 3-bet BB". For example, during "during BB bet 2" and "during BB bet 3", some of the effects (here, video and illumination) do not progress (no change). However, it is conceivable that other effects (here, voice) are made to progress. For example, when a two-coin bet game is played "inside the two-coin bet BB", or when a two-coin bet game is played "inside the three-coin bet BB", the moving speed of the background image, It is conceivable that the blinking cycle of the illumination is the same as before, but the BGM is changed.

Also, it is conceivable to determine the relationship among the three items of the specified number, the payout sound, and the sound effect (replay sound) accompanying establishment of the replay symbol combination. For example, it is conceivable to output both the payout sound and the replay sound during the 3-bet game, and to output the replay sound without outputting the payout sound during the 2-bet game.
<Measures to improve the functions of various operation devices when the power is turned on>

Next, countermeasures for improving functions of various operation devices when power is turned on will be described below. The countermeasures for improving the functions of various operation devices at the time of power-on described here are the slot machines of the type having the specified number changing function as described above and the slot machine 10 of the type not having the specified number changing function. and so on.

In addition, as a mode of turning on the power, for example, in an island facility in which slot machines are installed (there may be a plurality of slot machines or a single slot machine), a mode in which power is started to be supplied to a plurality of slot machines all at once; A mode in which power supply is started by operating the power switch 72 for the base can be mentioned.

Furthermore, from a different point of view, the power can be turned on while the door (front door section 11) is open, or when the door (front door section 11) is closed. can be mentioned. In addition, power-off and power-on in a state where game medals are not betted, and power-off and power-on in a state where game medals are being betted can also be mentioned. Power-off and power-on in a situation where there is a number of credits exceeding a prescribed number (3, 2, 1, etc.) related to the number of bets can also be mentioned.

Furthermore, while one game hall clerk turns on the power supply of the aforementioned island facility, the other game hall clerk operates the 3-insert button 76, the 1-BET button 75, the sub-input switch 78, the settlement button 74, and the like. It is also possible to consider situations in which various operating devices such as the stop buttons 24L to 24R are being operated. It is also possible to consider a situation in which a visitor, a player, is operating the above-described various operation devices when a game parlor clerk turns on the power of one slot machine.
<<Measure 1 (MAX bet button) related to functional improvement of operation devices>>

First, as a first measure related to the functional improvement of the operating device, measures for the 3-insert button (hereinafter referred to as "MAX bet button") 76 were examined. It is used when a maximum of three stored game medals are inserted within a range not exceeding the number of stored game medals and the prescribed number (here, 50, which is the storage limit number) related to the insertion.

For example, the MAX bet operation is possible (between the end of one game and the bet operation), and the MAX bet button 76 was not pressed when the power was turned off (before the power was turned off). ), a power outage occurs, and then the MAX bet button 76 is pressed in a situation where the power is completely turned off. In the situation where there are three or more cards and the previous MAX bet button 76 continues to be pressed, the MAX bet lamp (the above-mentioned 3 bet display LED) lights up, but after turning on the power Such a MAX bet (three-card throwing process) is not automatically performed as it is. Here, as the "three-sheet throwing process", for example, the storage throwing process shown in FIG. 27 can be mentioned. In the example of the slot machine 10 shown in FIGS. 1 to 50, the storage insertion process shown in FIG. 27 corresponds to S324 in the game medal management process shown in FIG. It can be migrated after

A new MAX bet after the power is turned on is not automatically placed, but if three game medals are inserted into the game medal insertion slot 21 by the player's finger, a MAX bet is made. make it possible to Furthermore, if more than 4 cards are put in, the 4th and subsequent cards are credited (reserved) without being returned. Here, in the example of the slot machine 10 shown in FIGS. 1 to 50, when insertion of game medals into the game medal insertion slot 21 is detected (S322 of FIG. 26: YES), a game medal insertion check is performed. (FIGS. 42 and 43) to execute a process related to the inserted game medals or to execute a stored insertion process.

By doing so, it is possible to accurately notify that the bet processing is effective by using the MAX bet lamp (the above-described 3-bet-throw-in display LED). Furthermore, since the automatic 3-coin bet is not made, even if the player makes an erroneous operation (such as keeping the finger on the MAX bet button 76) when the power is turned on, an unintended bet is prevented. can do. Furthermore, since the MAX bet lamp (the above-described 3-card insert display LED) lights up, it is possible to inform that the MAX bet is possible from the control point of view.

It should be noted that the basic configuration of a gaming machine that implements countermeasure 1 (MAX bet button) related to the functional improvement of such operating devices can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
A maximum number bet setting button (such as a MAX bet button) that is pressed by the player when setting the maximum number of bets (such as a MAX bet) and is illuminated by lighting of a light source (such as a MAX bet lamp) in a predetermined case;
a control means (such as a main CPU) capable of setting the maximum number of bets when the maximum number of bets setting button is pressed;
After the power is turned on while the maximum number of bets setting button is being pressed, the light source is lit and bets are not set when the maximum number of bets setting button continues to be pressed. .
<<Measure 2 (MAX bet button) related to the functional improvement of the operation device>>

Next, as another countermeasure, another countermeasure for the 3-insert button (hereinafter referred to as "MAX bet button") 76 was examined. For example, the MAX bet operation is possible (between the end of one game and the bet operation), and the MAX bet button 76 was not pressed when the power was turned off (before the power was turned off). ), a power outage occurs, and then the MAX bet button 76 is pressed in a situation where the power is completely turned off. In a situation where there are three or more cards and the previous MAX bet button 76 continues to be pressed, the MAX bet lamp (the above-mentioned three-bet display LED) lights up, but the above countermeasure 1 and In contrast, a new one-card bet (one-card bet setting) after power-on is made possible. In other words, the one-bet operation is enabled, and when the 1-bet button (hereinafter referred to as "one-bet button") 75 is operated, the one-bet process is performed. In this case, as with Countermeasure 1 described above, automatic MAX bets should not be made.

Also in this countermeasure, if three game medals are inserted into the game medal slot 21 by the fingers of the player, a MAX bet is made.

By doing so, it is possible to accurately notify that the bet processing is effective by using the MAX bet lamp (the above-described 3-bet-throw-in display LED). Furthermore, since the one-coin bet is not invalidated, even if the number of coins (bet number) is limited, which is smaller than the MAX bet, the progress of the game can be prevented as much as possible. Furthermore, since the MAX bet lamp (the above-described 3-card insert display LED) lights up, it is possible to inform that the MAX bet is possible from the control point of view. Also, even if the MAX bet button 76 is out of order, it is possible to proceed with the game using the one-insert button 75 .

It should be noted that the basic configuration of a gaming machine that implements countermeasure 2 (MAX bet button) relating to the functional improvement of such operating devices can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
a first bet setting button (such as a one insert button) pressed by the player when setting a first bet (such as one);
A second bet setting button (a second bet setting button ( MAX bet button, etc.) and
A control that enables the bet setting of the first bet amount when the first bet setting button is pressed, and the bet setting of the second bet amount when the second bet setting button is pressed. means (main CPU, etc.),
After the power is turned on while the second bet setting button is being pressed, in a situation where the second bet setting button continues to be pressed, the light source is lit and bet setting by the first bet setting button is possible. A gaming machine characterized by:
<<Measure 3 (1 bet button) related to functional improvement of operation devices>>

Next, as another countermeasure, a countermeasure for the one-sheet insertion button 75 was examined. For example, the one-card insertion button 75 can be operated (from the end of one game until the betting operation is performed), and the one-card insertion button 75 is not pressed when the power is turned off (before the power is turned off). When the power is turned off (not pressed), the one-sheet insert button 75 is pressed while the power is completely turned off. In the state, the number of credited cards is 3 or more, and the previous 1-card insertion button 75 continues to be pressed, the MAX bet lamp (the above-mentioned 3-card insertion display LED) lights up. However, a new 1-card bet (1-card bet setting) after power-on should not be made. Also, as with the measures 1 and 2 described above, if three game medals are inserted into the game medal insertion slot 21 by the fingers of the player, a MAX bet is made.

By doing so, it is possible to accurately notify that the bet processing is effective by using the MAX bet lamp (the above-described 3-bet-throw-in display LED). Furthermore, since one card is not betted, even if the player makes an erroneous operation (such as keeping his or her finger on the one card input button 75) when the power is turned on, an unintended bet can be prevented. can be done. Furthermore, since the MAX bet lamp (the above-described 3-card insert display LED) lights up, it is possible to inform that the MAX bet is possible from the control point of view.

It should be noted that the basic configuration of a gaming machine that implements countermeasure 3 (1-bet button) related to the functional improvement of such operating devices can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
a first bet setting button (such as a one insert button) pressed by the player when setting a first bet (such as one);
A second bet setting button (a second bet setting button ( MAX bet button, etc.) and
A control that enables the bet setting of the first bet amount when the first bet setting button is pressed, and the bet setting of the second bet amount when the second bet setting button is pressed. means (main CPU, etc.),
After the power is turned on while the second bet setting button is being pressed, in a situation where the second bet setting button continues to be pressed, the light source is lit and a bet is not set by the first bet setting button. Characteristic game machine.
<<Measure 4 (1 bet button) related to functional improvement of operation equipment>>

Next, as another countermeasure, another countermeasure for the 1BET button (hereinafter referred to as "one insert button") 75 was examined. For example, the one-card insertion button 75 can be operated (from the end of one game until the betting operation is performed), and the one-card insertion button 75 is not pressed when the power is turned off (before the power is turned off). When the power is turned off (not pressed), the one-sheet insert button 75 is pressed while the power is completely turned off. In the state, the number of credited cards is 3 or more, and the previous 1-card insertion button 75 continues to be pressed, the MAX bet lamp (the above-mentioned 3-card insertion display LED) lights up. Then, a new MAX bet can be made after the power is turned on.

By doing so, it is possible to accurately notify that the bet processing is effective by using the MAX bet lamp (the above-described 3-bet-throw-in display LED). Furthermore, since the MAX bet is not invalidated, the progress of the game can be prevented as little as possible. Furthermore, since the MAX bet lamp (the above-described 3-card insert display LED) lights up, it is possible to inform that the MAX bet is possible from the control point of view.

It should be noted that the basic configuration of a gaming machine that implements measure 4 (1-bet button) relating to the functional improvement of the operating device can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
a first bet setting button (such as a one insert button) pressed by the player when setting a first bet (such as one);
A second bet setting button (a second bet setting button ( MAX bet button, etc.) and
A control that enables the bet setting of the first bet amount when the first bet setting button is pressed, and the bet setting of the second bet amount when the second bet setting button is pressed. means (main CPU, etc.),
After the power is turned on while the first bet setting button is being pressed, in a situation where the first bet setting button continues to be pressed, the light source is lit and bet setting by the second bet setting button is possible. A gaming machine characterized by:
<<Measure 5 (menu button) related to functional improvement of operation devices>>

Next, as another countermeasure, a countermeasure for the sub-input switch (hereinafter referred to as "menu button") 78 was examined. For example, when the menu button 78 can be operated (from the end of one game until the betting operation is performed), when the power is turned off (before the power is turned off), the menu screen (an example is shown in FIG. 60(a)) ) is not displayed and is hidden, and the menu button 78 is not pressed (unpressed). When the power is turned on while the button 78 is being pressed, the menu button lamp is lit, and the menu screen (Fig. 60(a) shows an example) should not be displayed. Furthermore, even if an operation other than pressing the menu button 78 is performed, the menu screen is not displayed.

By doing so, it is possible to accurately notify by using the menu button lamp that the operation of the menu button 78 is effective. Furthermore, since the menu screen is not displayed, even if the player makes an erroneous operation (such as keeping his finger on the menu button 78) when the power is turned on, an unintended menu screen is not displayed. can be prevented. Furthermore, since the menu button lamp lights up, it can be notified that the menu button 78 is ready for operation. Also, the lighting of the menu button lamp allows the player to understand that the sub-control function by the sub-main board 1301 or the like is electrically operating.

Here, as in this countermeasure, the menu button lamp lights up and the menu screen is not displayed, but in order to display something other than the menu screen, if there is an operation on the operation device, the corresponding display is performed. It is possible. For example, by operating the cross key 77, an image indicating that the volume can be adjusted (an example of the volume setting screen is shown in FIG. 60(b)) is displayed, or an image indicating that the brightness of the screen can be adjusted. (an example of the light amount setting screen is shown in FIG. 60(c)) can be exemplified.

It should be noted that the basic configuration of a gaming machine that implements countermeasure 5 (menu buttons) related to the functional improvement of such operation devices can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
an image display means (such as a production unit) capable of displaying a menu screen;
a menu button that is pressed by the player when the menu screen is displayed and is illuminated by lighting of a light source (such as a menu button lamp) in a predetermined case;
A game machine according to claim 1, characterized in that after the power is turned on while the menu button is being pressed, the light source is turned on and the menu screen is not displayed when the menu button is continuously pressed.
<<Measure 6 (Payment button) related to functional improvement of operation devices>>

Next, as another countermeasure, a countermeasure for the settlement button 74 was examined. For example, the settlement button 74 was in a state in which it was possible to operate (from the end of one game until the start operation was performed), and the settlement button 74 was not pressed (unpressed) when the power was turned off (before the power was turned off). ), and in a situation where there are credited game medals and no number of bets has been made, power is cut off, and then the settlement button 74 is pressed in a situation where the power is completely turned off, When the power is turned on while the settlement button 74 is being pressed, and in the state after the power is turned on and the previous settlement button 74 is still being pressed, the accumulated game medals are cleared (thrown in). (including refund of game medals received) shall not be performed.

Furthermore, although the MAX bet lamp (the above-mentioned three-bet display LED) lights up, in a situation where the previous settlement button 74 is being pressed, even if the MAX bet button 76 is pressed, after the power is turned on , no new MAX bets will be made. Also, even if the one-card insertion button 75 is pressed, a new one-card bet (one-card bet setting) after power-on is prevented.

Furthermore, it is possible to carry out the control processing as invalid even for the insertion of game medals into the game medal insertion slot 21 . However, not limited to this, it is also possible to carry out the control processing assuming that the insertion of game medals into the game medal insertion slot 21 is effective.

By doing so, it is possible to prevent settlement (including refund) from being performed due to an erroneous operation (such as keeping a finger on the settlement button 74) when the power is turned on. Furthermore, even in a situation where a bet cannot be made with the MAX bet button 76, the lighting of the MAX bet lamp informs the player that the game medals have been accumulated in a credit amount sufficient for a MAX bet, so that the player can leave the accumulation. It is possible to prevent leaving the seat unattended.

Here, as a precondition for the countermeasure against the main body, a situation in which no number of bets has been made is taken as an example, but the situation is not limited to this, and a situation in which a bet is made may be assumed. In this case, the power is turned on while the settlement button 74 is being pressed, and in the state after the power is turned on and the previous settlement button 74 is continuously pressed, the Game medals are not cleared (including refund of inserted game medals), but it is conceivable that the number of game medals betted is cleared. In addition to this, in a similar situation when the power is turned on, both the number of game medals betted and the number of credits are cleared (all at once). It is conceivable to prevent the number of game medals betted and the number of credited game medals from being settled (at once) in the situation at the time of insertion.

It should be noted that the basic configuration of a game machine that implements countermeasure 6 (settlement button) related to the functional improvement of the operating device can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
a first bet setting button (such as a one insert button) pressed by the player when setting a first bet (such as one);
A second bet setting button (a second bet setting button ( MAX bet button, etc.) and
a checkout button pressed by the player at the time of checkout;
When the first bet setting button is pressed, the bet setting for the first bet amount can be executed, and when the second bet setting button is pressed, the bet setting for the second bet amount can be executed, A control means (main CPU, etc.) capable of clearing the game value when the clearing button is pressed,
After the power is turned on while the settlement button is pressed, if the settlement button continues to be pressed, settlement is not performed, the light source is lit, and bet setting by the second bet setting button is not performed. A game machine characterized by
<< Measure 7 related to functional improvement of operation devices (settlement button) >>

Next, as another countermeasure, a countermeasure for the settlement button 74 was examined. For example, in the same way as countermeasure 6 described above, the settlement button 74 can be operated (from the end of one game until the start operation is performed), and when the power is turned off (before the power is turned off), the settlement button 74 is A power outage occurred in a state where the key was not pressed (non-pressed), there were credited game medals, and no number of bets had been made, and then the power was completely turned off. is pressed, the power is turned on while the settlement button 74 is being pressed, and in the state after the power is turned on and the previous settlement button 74 is still being pressed, Settlement of game medals (including refund of inserted game medals) is not performed. Furthermore, the MAX bet lamp (the above-described 3-bet display LED) lights up so that a new MAX bet can be made after the power is turned on.

By doing so, it is possible to prevent settlement (including refund) from being performed due to an erroneous operation (such as keeping a finger on the settlement button 74) when the power is turned on. Furthermore, since the MAX bet is not invalidated, the progress of the game can be prevented as little as possible. Furthermore, since the MAX bet lamp lights up, it can be informed that the MAX bet is possible in terms of control.

It should be noted that the basic configuration of a game machine that implements countermeasure 7 (settlement button) related to the functional improvement of the operating device can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons;
a first bet setting button (such as a one insert button) pressed by the player when setting a first bet (such as one);
A second bet setting button (a second bet setting button ( MAX bet button, etc.) and
a checkout button pressed by the player at the time of checkout;
When the first bet setting button is pressed, the bet setting for the first bet amount can be executed, and when the second bet setting button is pressed, the bet setting for the second bet amount can be executed, A control means (main CPU, etc.) capable of clearing the game value when the clearing button is pressed,
After the power is turned on while the settlement button is being pressed, in a situation where the settlement button continues to be pressed, settlement is not performed, the light source is lit, and betting can be set by the second bet setting button. It is a gaming machine characterized by
<<Countermeasure 8 (stop button) related to functional improvement of operation devices>>

Next, as another countermeasure, a countermeasure for the stop buttons 24L to 24R was examined. For example, when the power is turned off (before the power is turned off), all three reels (reels, 51L to 51R) are rotating, and the stop buttons 24L to 24R are active. Any one of the stop buttons 24L to 24R is pressed in a depressed state, power is turned on while any one of the stop buttons 24L to 24R is being pressed, and the state after the power is turned on, In addition, when the previous stop button (any one of 24L to 24R) continues to be pressed, all three reels (reels, 51L to 51R) rotate due to the acceleration process executed after the power is turned on. However, none of the reels (51L to 51R) are stopped, including the reel corresponding to the stop button (any one of 24L to 24R) that continues to be pressed. Furthermore, the stop button LED is in an ineffective mode, and other stop buttons cannot be used to stop the rotation of the reels. After that, when the finger that has been continuously pressed is released and the stop button (any one of 24L to 24R) is pressed again, the corresponding reel (reel, 51L to 51R) stops.

Examples of the ineffective mode of the stop button LED include, for example, when the light emission mode (effective mode) when the stop button LED is enabled is white light or orange (orange) light, it is made blue light, turned off, or the like. .

By doing so, even if the player erroneously operates (such as continuing to place his or her finger on any of the stop buttons 24L to 24R) when the power is turned on, the reels (51L to 51R) are unintentionally turned on. It is possible to prevent the player from being disadvantaged, such as losing a small winning combination due to a stoppage. In addition, for example, if the stop buttons 24L to 24R have some kind of problem, the spinning drum cannot be stopped according to the player's operation, and an unintended game result occurs, giving the player an unforeseen disadvantage. can be prevented.

Here, the basic configuration of the game machine to which the countermeasure 8 (stop button) related to the functional improvement of the operating device is applied can be expressed as follows, for example.
a power supply;
a reel;
a start lever and
a plurality of stop buttons that are sequentially pressed by the player when rotation of each reel is stopped;
It is possible to illuminate each stop button individually, and it is possible to emit light in at least a mode indicating that the pressing operation of the corresponding stop button is valid and a mode indicating that the pressing operation of the corresponding stop button is invalid. with a light source (such as a stop button LED),
After turning on the power while pressing any stop button, if the stop button continues to be pressed, the rotation of the corresponding reel is not stopped, and the light source corresponding to the stop button presses the stop button. light is emitted in a manner indicating that the operation of is invalid, and the rotation of the corresponding reel is not stopped even if a stop button other than the stop button is pressed.

In addition, when the power is turned off (before the power is turned off), all three reels (reels, 51L to 51R) are rotating, and the power is turned off in a situation where the stop buttons 24L to 24R are effective, and then the power is turned off. Any one of the stop buttons 24L to 24R is pressed in a depressed state, power is turned on while any one of the stop buttons 24L to 24R is being pressed, and the state after the power is turned on, In addition, in a situation where the previous stop button (any one of 24L to 24R) is being pressed continuously, by detecting the pressing of the previous stop button after the power is turned on, the number of times corresponding to the previous stop button is restarted. A mode in which the cylinders (reels, 51L to 51R) are stopped is also conceivable.

In this case, the acceleration process is executed after the power is turned on, but even during the acceleration process, the reel corresponding to the previous stop button is stopped. In other words, the stop control is executed without detecting the index of the reel. For this reason, there is a possibility that an unexpected symbol will stop on the reel corresponding to the previous stop button. is not determined (when a minor winning combination is won, a minor winning combination is paid out).

By doing so, even if the player's stop operation order is interrupted by a power failure between the stop operations, the player's stop operation order and the actual stopping order of the reel can be prevented from being deviated. It is possible to suppress the disadvantage that the payout of small winnings is reduced due to a mistake in the order (failure in the pressing order).

In addition, when the power is turned off (before the power is turned off), all three reels (reels, 51L to 51R) are rotating, and the power is turned off in a situation where the stop buttons 24L to 24R are effective, and then the power is turned off. Any two of the stop buttons 24L to 24R are pressed in a depressed state, power is turned on while any two of the stop buttons 24L to 24R are being pressed, and the state after the power is turned on, In addition, in a situation where the previous stop button (any two of 24L to 24R) is being pressed continuously, the pressing of the previous stop button (any two of 24L to 24R) is detected after the power is turned on. Also, a mode in which none of the reels (reels, 51L to 51R) are stopped is also conceivable.

By doing so, it is possible to prevent the control from being more advantageous than expected. For example, since it is usually not assumed that two stop buttons will be operated at the same time, it is possible to suppress strategies that make use of this inconvenience.

Next, as another countermeasure, a countermeasure for the start lever 25 was examined. For example, when the power is turned off (before the power is turned off), 3 bets are made, the power is turned off in a state where the start lever 25 is valid, and then the start lever 25 is pressed in a state where the power is turned off. 25 is being pressed, in a state after the power is turned on, and in a situation in which the previous start lever 25 is still being pressed, the previous pressing of the start lever 25 is detected after the power is turned on. However, the reels (reels 51L to 51R) are not rotated.

By doing so, even if the player makes an erroneous operation (such as keeping his or her finger on the start lever 25) when the power is turned on, the reel (51L to 51R) will be rotated unintentionally. Moreover, it is possible to prevent the player from being disadvantaged.

Various modifications can be made without departing from the scope of the invention. For example, there is no particular problem with other types of gaming machines, such as other types of slot machines, pachinko gaming machines, and pachinko gaming machines in which the player has the function of stopping reels and symbols in the same way as slot machines. It is possible to apply as long as

10 slot machine, 11 front door section, 12 housing section, 15 drum display section,
16 game medal payout port, 17 tray, 18 production unit, 21 game medal slot,
24L ~ 24R 1st stop button ~ 3rd stop button, 25 start lever,
31 sub-control board, 51L to 51R first to third drums, 61 main control board,
62 setting unit, 68 setting key switch, 74 checkout button,
75 1BET button (1 insert button),
76 3 insert button (MAX bet button),
78 sub-input switch (menu button), 81 main CPU.

Claims (1)

a plurality of reels;
a start lever and
and a plurality of stop buttons,
A winning lottery can be executed according to a predetermined number of bets,
the predetermined number of bets includes a first number of bets and a second number of bets greater than the first number of bets;
a first bet number game in which the first bet number is set is executable;
a second bet number game in which the second bet number is set is executable;
In the next game when the first specific combination is won in the role lottery in the first bet number game, and there is no stop display of the predetermined symbol combination related to the first specific combination in the first bet number game, A game can be executed in the first internal winning state,
In the next game when the second specific combination is won in the role lottery in the second bet number game, and there is no stop display of the specific symbol combination related to the second bet number game in the second bet number game, A game can be executed in the second internal winning state,
When the stop display of the predetermined symbol combination related to the first specific combination is displayed, the game can be executed in the first bonus state,
When the specific symbol combination relating to the second specific combination is stopped and displayed, the game can be executed in the second bonus state,
a game can be executed in a predetermined game state different from any of the first internal win state, the first bonus state, the second internal win state, and the second bonus state;
Even if the setting is changed in the first internal contact state, the first internal contact state can be maintained,
Giving rate of the predetermined privilege in the game with the second number of bets in the second bonus state<Give rate of predetermined privilege in the game with the second number of bets in the predetermined gaming state,
The grant rate of the predetermined bonus in the game with the second number of bets in the second bonus state<the rate of grant of the predetermined bonus in the game with the second number of bets in the second internal winning state,
When there is no stop display of the predetermined symbol combination related to the first specific hand in the game in which the first specific hand is won in the hand lottery in the first bet number game in the predetermined game state, the last The display mode of the display means becomes the first mode at a predetermined timing after the stop button that has been operated to stop is released,
When there is no stop display of the specific symbol combination related to the second specific combination in the game in which the second specific combination is won in the combination lottery in the second bet number game in the predetermined game state, the last The display mode of the display means becomes a second mode different from the first mode at a predetermined timing after the stop button that has been operated to stop is released,
A situation in which predetermined BGM is continued to be output after all the reels are stopped in a game in which a predetermined combination other than the second specific combination is won in the combination lottery in the second bet number game in the predetermined gaming state. below, when the second bet number game is executed, the output of the predetermined BGM can be terminated,
The output of the predetermined BGM is continued after all the reels are stopped in the game in which the predetermined combination other than the second specific combination is won in the combination lottery in the second bet amount game in the predetermined gaming state. When the game with the first number of bets is executed under the condition that the first number of bets is played, the output of the predetermined BGM is continued even during the game with the first number of bets.
A gaming machine characterized by:

Images