JP6654307B2 - Gaming machine - Google Patents

Description

  The present invention relates to a gaming machine.

  A slot machine has been widely known as one of gaming machines. In this type of slot machine, when a player inserts a prescribed number of game media such as medals and game balls, the operation of a start switch is enabled, and when the player operates the start switch in this state, a role lottery is performed. Then, a plurality of reels on each of which a plurality of symbols are drawn start rotating. When the rotation speed of the reel reaches a certain speed, the operation of the stop switch provided corresponding to each reel becomes effective, and when the player operates the stop switch, the reel corresponding to the operated stop switch is activated. Stop control is performed.

  In the reel stop control described above, when any winning combination is won in the winning lottery, the pull-in is performed within 190 milliseconds after the stop switch is operated so that the symbol combination corresponding to the winning combination is aligned on the activated line. Control is performed. On the other hand, if the result of the lottery is a loss, kick control is performed so that the symbol combination corresponding to any combination is not aligned on the activated line. If all reels are stopped and a symbol combination corresponding to any combination is stopped and displayed on the activated line, the combination has won, and a bonus corresponding to the winning combination is given to the player. You.

  Generally, a conventional slot machine has a plurality of setting values, and a staff at a game arcade selects one setting value from a plurality of setting values, and causes a player to execute a game with the selected setting value. Like that. This set value is for setting the probability of the winning combination (winning combination) to be different by the lottery. For example, when the setting value can be selected from six types from “1” to “6”, When the set value "6" is selected, a lottery lottery most advantageous to the player is made, and when the set value "1" is selected, a lottery lottery most disadvantageous to the player is made. .

  For example, in the slot machine described in Patent Literature 1, when the power is turned on while a setting key switch provided in the housing is turned on, a current setting value is displayed on a setting value display provided inside the front door. Is displayed and the state shifts to the setting change state. When the setting / reset switch provided on the power supply box is operated in the setting change state, the value of the set value displayed on the set value display increases by one each time the switch is operated. Then, when the start switch is operated while the desired set value is displayed, the set value is determined, and when the set key switch is turned off, the game can proceed.

Japanese Patent No. 5618050

SUMMARY OF THE INVENTION It is an object of the present invention to provide a gaming machine in which setting items on a menu screen can be changed depending on whether or not the mode has shifted to a mode relating to setting values .

In order to solve the above-mentioned problem, the present invention
Predetermined display means capable of displaying a set value,
Image display means,
First operating means;
And second operating means,
When the first operation means is operated, the mode shifts to a menu mode ,
When the mode is shifted to the menu mode by operating the first operation unit when the setting mode is not the setting check mode in which the setting value can be checked, an item for displaying an error history in the menu mode is displayed on the image display unit. It is possible to display , the item for enabling the power saving setting in the menu mode is configured not to be displayed on the image display means ,
In a case where the operation mode is shifted to the menu mode by operating the first operation means in the setting confirmation mode in which the setting value can be confirmed, an item for displaying an error history in the menu mode is displayed on the image display means. to a displayable a item for enabling power saving setting in the menu mode can be displayed on the image display unit,
If the second operation means is operated while the front door is open and the item for enabling the power saving setting is selected, it is possible to shift to a state where the power saving setting is available. Yes,
Even if the front door is closed, if the second operation means is operated while the item for enabling the power saving setting is selected, the state shifts to the state where the power saving setting is available. It is characterized in that it is possible.

According to the above-described invention, when the mode shifts to the menu mode by operating the first operation unit when the setting value is not in the setting check mode, the error history is displayed in the menu mode. The item is displayed, the item for enabling the power saving setting is not displayed, and the mode is shifted to the menu mode by operating the first operation unit in the setting check mode in which the setting value can be checked. In this case, the item for displaying the error history and the item for enabling the power saving setting can be displayed in the menu mode, so the menu screen is displayed according to whether or not the mode has been shifted to the setting confirmation mode. Can be set differently . Further, since the setting relating to the power consumption can be performed even when the front door is closed, the load on the housing due to the weight of the front door can be reduced, and the setting operation can be easily performed.

As described above, according to the gaming machine of the present invention, the setting items on the menu screen can be made different depending on whether or not the mode has shifted to the mode relating to the setting value .

FIG. 2 is a perspective view showing an appearance of the slot machine according to the first embodiment of the present invention. FIG. 3 is an explanatory diagram for describing an internal structure of the slot machine. It is an explanatory view for explaining a symbol arrangement of each reel provided in the slot machine. It is an explanatory view for explaining types of condition devices and symbol combinations thereof in the same slot machine. It is an explanatory view for explaining types of condition devices and symbol combinations thereof in the same slot machine. It is an explanatory view for explaining types of condition devices and symbol combinations thereof in the same slot machine. It is an explanatory view for explaining types of condition devices and symbol combinations thereof in the same slot machine. FIG. 3 is a functional block diagram showing a functional configuration of the slot machine. It is an explanatory view for explaining types of winning combinations in the winning lottery of the slot machine and condition devices corresponding to each winning combination. FIG. 64 is an explanatory diagram for describing the contents of a winning lottery table that determines the winning probability of each winning role in the winning lottery of the slot machine. FIG. 9 is an explanatory diagram for explaining types of signals input to each input port of the main control means of the slot machine. FIG. 29 is an explanatory diagram for describing main commands among commands transmitted from the main control unit to the sub control unit of the slot machine. FIG. 4 is an explanatory diagram for explaining a part of information stored in a memory of a main control unit of the slot machine. FIG. 4 is an explanatory diagram for explaining a part of information stored in a memory of a main control unit of the slot machine. FIG. 4 is an explanatory diagram for explaining a part of information stored in a memory of a main control unit of the slot machine. FIG. 9 is an explanatory diagram for explaining the correspondence between each segment of the 7-segment display provided in the slot machine and data bits. 29 is a flowchart showing the contents of a program start process executed by the main control means immediately after the power of the slot machine is turned on. 40 is a flowchart showing the content of a setting change device process executed when the main controller of the slot machine changes the set value. 48 is a flowchart showing the content of a game progress main process executed by the main control means of the slot machine to control the progress of the game. 20 is a flowchart showing detailed contents of a game medal insertion standby display process executed in the game progress main process of FIG. 19. 6 is a flowchart illustrating the content of an error display process executed when an abnormality occurs in the slot machine according to the first embodiment of the present invention. It is a flowchart showing the contents of a timer interruption process executed by the main control means of the slot machine. 23 is a flowchart showing the detailed contents of an LED display process executed in the timer interrupt process of FIG. 22. 23 is a flowchart showing detailed contents of input port 0 to 2 read processing executed in the timer interrupt processing of FIG. 22. 25 is a flowchart showing detailed contents of input port data set processing executed in input port 0 to 2 read processing of FIG. 24. It is a flowchart showing the contents of a sub-power-on processing executed at the time of power-on in the sub-control means of the slot machine according to the first embodiment of the present invention. 27 is a flowchart showing the details of one-command processing executed in the sub-power-on processing shown in FIG. 26. FIG. 55 is an explanatory diagram for describing the contents of a system menu screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 51 is an explanatory diagram for describing the content of a volume adjustment screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 53 is an explanatory diagram for describing the contents of a game standby lamp color screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 53 is an explanatory diagram for describing the contents of a side lamp test screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 51 is an explanatory diagram for describing the contents of a user volume adjustment screen displayed on the image display device in the effect setting mode in the slot machine. It is an explanatory view for explaining contents of a game data display setting screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 41 is an explanatory diagram for describing the contents of an error etc. history display screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 55 is an explanatory diagram, illustrating contents of a screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 55 is an explanatory diagram, illustrating contents of a screen displayed on the image display device in the effect setting mode in the slot machine. FIG. 51 is an explanatory view, illustrating contents of a menu screen for a player in the slot machine. FIG. 51 is an explanatory diagram for describing the contents of a game standby screen displayed on the image display device in the game standby state in the slot machine. FIG. 53 is an explanatory view, illustrating contents of a game data display screen in the slot machine. It is a flow chart which shows the contents of the display processing at the time of waiting for a game medal insertion in the slot machine according to the second embodiment of the present invention. It is a flowchart which shows the content of the modification of the display processing at the time of the game medal insertion standby. 42 is a flowchart showing detailed contents of a startup check process executed in the game medal insertion standby display process shown in FIG. 41. 42 is a flowchart showing the detailed contents of a fall check process executed in the game medal insertion standby display process of FIG. 41. It is a flow chart which shows the contents of the setting change device processing in a 3rd embodiment of the present invention. It is a flow chart which shows the contents of the setting change device processing in a 4th embodiment of the present invention. It is a flow chart which shows the contents of the setting change device processing in a 5th embodiment of the present invention. It is a flow chart which shows the contents of the setting change device processing in a 6th embodiment of the present invention. It is a flow chart which shows the contents of the setting change device processing in a 7th embodiment of the present invention. It is a flowchart which shows the content of the error display processing in 8th Embodiment of this invention. 50 is a flowchart showing the contents of a modification of the error display processing shown in FIG. 49. 25 is a flowchart showing the contents of a modification of the input port 0 to 2 read processing shown in FIG. 24. FIG. 52 is an explanatory diagram for describing an RWM address referred to in a modification of the input port 0 to 2 read processing of FIG. 51;

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[First Embodiment]
FIG. 1 shows an external perspective view of a slot machine 10 according to one embodiment of the present invention. The housing of the slot machine 10 includes a main body 12 that accommodates various devices, and a front door 14 that can be opened and closed on the front side (player side) of the main body 12. A front panel 20 is provided substantially at the center of the front door 14, and a display window 21 is formed substantially at the center thereof. Three reels 40L, 40C, and 40R are rotatably provided inside the main body 12, and the symbols printed on the outer peripheral surface of each reel can be visually recognized from the display window 21.

  The reels 40L, 40C, and 40R are installed such that their rotation axes are aligned on the same straight line in the horizontal direction. Each reel has a ring shape, and a band-shaped reel tape on which one symbol is printed is attached to each of 20 equally divided symbol regions on the outer peripheral surface. When the reels 40L, 40C, and 40R are stopped, three consecutive symbols along the rotation direction of each reel among the twenty symbols printed on each reel can be visually recognized from the display window 21. ing. Thus, a total of nine symbols are stopped and displayed on the display window 21 (3 symbols) × 3 [reels]. Here, of the three consecutive symbols displayed when the reels 40L, 40C and 40R are stopped, the position where the uppermost symbol is stopped and displayed (also referred to as a stop display position) is the upper row U, The position where the symbol is stopped and displayed is referred to as a middle row M, and the position where the lowermost symbol is stopped and displayed is referred to as a lower row D.

  In addition, one pay line L (also referred to as an active line) crossing the lower stage D of the left reel 40L, the middle stage M of the middle reel 40C, and the upper stage U of the right reel 40R is defined. The winning line L is a line serving as a reference when determining whether or not a symbol combination corresponding to a plurality of predetermined combinations (described later) is stopped and displayed. That is, when the reels 40L, 40C, and 40R are stopped, the stop display positions (the lower row D of the left reel 40L, the middle row M of the middle reel 40C, and the upper row U of the right reel 40R) where the pay line L passes are stopped and displayed. If the combination of the three symbols corresponds to any of the combinations, the combination has won. In the following, when it is simply described that "the symbol combination has been stopped and displayed" or "the symbols (or symbol combinations) have been prepared", the symbol combination has been stopped and displayed along the pay line L. Means The lower part D of the left reel 40L, the middle part M of the middle reel 40C, and the upper part U of the right reel 40R are also referred to as "winning stop positions".

  In addition to the display window 21, the front panel 20 is provided with various lamps and indicators for notifying the player of various information related to the game. On the lower side of the display window 21, in order from the left in FIG. 1, bet number (bet number) display lamps 26a, 26b, 26c, a credit number display (also referred to as a "stored number display") 27, and 27. An acquired number display 28 is provided. The bet number display lamps 26a, 26b, 26c display the number of medals bet for one game. Here, when one medal is bet, only the bet number display lamp 26a is lit, and when two medals are bet, the bet number display lamps 26a and 26b are lit and three medals are bet. And the bet number display lamps 26a, 26b, 26c are turned on.

  Although not shown, the front panel 20 has various lamps, such as a game start display LED, an insertion display LED, a re-game display LED, and a clearing display LED, which indicate the progress of the game, in addition to the various lamps described above. An LED is provided. The game start display LED indicates whether or not the operation of the start switch 36 is permitted. Lighting indicates that the operation is permitted, and light-off indicates that the operation is not permitted. The insertion indicator LED indicates the on / off state of the blocker in the selector 80. Lighting indicates that the blocker is on (medal can be inserted), and light off indicates that the blocker is off (medal cannot be inserted). . The re-game display LED is turned on when a re-game, which will be described later, is executable, and is turned off when the re-game is completed. The settlement display LED is turned on while a credited medal is paid out by operating a settlement switch 33 described later.

  A medal bet for performing a game in the slot machine 10 is a kind of game medium. The game medium is not limited to a medal, but may be a game ball (a so-called pachinko ball), or information indicating a value recorded on a recording medium such as a magnetic card, a non-contact IC card, or a coin having a built-in IC chip. It may be. In the slot machine 10, when a prescribed number (three in this embodiment) of medals is bet, one game can be played, and the winning line L is an effective line. The credit number display 27 is composed of a two-digit seven-segment display, and is credited (stored) in the slot machine 10 (more specifically, data stored in the main control means 100 described later can be rewritten). The number of medals stored in a non-volatile memory (RWM: read / write memory) is displayed. In the present embodiment, the maximum number of medals that can be credited is 50. The acquired number display 28 comprises a two-digit seven-segment display, and displays the number of medals paid out to the player according to the result of the game.

  On the lower side of the front panel 20 described above, an operation panel section 30 which is formed substantially horizontally over the entire width of the slot machine 10 and protrudes in the player direction is provided. On the front right side of the operation panel section 30, a door key 31 for locking or unlocking the front door 14 with respect to the main body section 12 is provided. In the present embodiment, when a keypad (not shown) is inserted into the door key 31 and turned clockwise (rotated rightward toward the front door 14), the front door 14 is unlocked and turned counterclockwise (front door). 14 to the left), the error state can be released (reset). On the right side of the upper surface of the operation panel section 30, a medal insertion slot 32 for inserting a medal into the slot machine 10 is provided. Further, a selector (described later) for selecting medals is provided inside the slot machine 10, and a medal sensor (insertion sensor) provided in the selector detects a medal inserted from the medal insertion slot 32. Then, a medal detection signal is output to the main control means 100 described later. The main control means 100 counts the number of inserted medals and detects anomalies such as fraudulent acts when inserting medals, based on the input medal detection signals.

  Betting switches 34 and 35 for betting credited medals on the slot machine 10 (in other words, setting the number of bets) are provided on the upper left side of the operation panel unit 30. The 1-bet switch 34 bets only one of the credited medals each time it is operated as a game bet target. The maximum bet switch 35 bets the maximum number (specified number) of medals that can be bet in the current game, among the credited medals, as a target of the game bet. Here, in the slot machine 10, the prescribed number is three. Further, when a medal is inserted into the medal insertion slot 32 in a state where the medal has been betted to the specified number, the inserted medal is stored in the credit. When a medal is inserted into the medal slot 32 in a state where a predetermined number of medals have been bet and the number stored in the credit has reached the upper limit value (50), the medal is paid by a medal payout described later. It is returned from the outlet 60 to the tray 61.

  Between the medal insertion slot 32 and the maximum bet switch 35, a selection switch 38 and a decision switch 39 for a player to input information to the slot machine 10 are provided. The selection switch 38 includes four switches, ie, an upper switch, a lower switch, a left switch, and a right switch for designating the up, down, left, and right directions. Then, one of the upward direction, the downward direction, the leftward direction, and the rightward direction is designated in accordance with the operated switch. The decision switch 39 is formed of a member through which light passes, and a light source such as an LED is provided therein. The character “PUSH” is printed on the upper surface (operation surface) of the decision switch 39. Since the selection switch 38 and the determination switch 39 are switches capable of determining the content of the effect and the like, these switches are collectively referred to as effect switches.

  A start switch 36 is provided on the front left side of the operation panel unit 30 so as to be tiltable. The operation of the start switch 36 becomes effective when a player bets a predetermined number of medals on the slot machine 10. However, when a symbol combination corresponding to a replay, which will be described later, is aligned (wins) on the pay line, in the next game (replay), the game in which the replay combination (also referred to as “replay combination”) has won. The bet number that has been bet is automatically bet, the bet number display lamps 26a, 26b, and 26c light up by the specified number, and the operation of the start switch 36 for performing the next game becomes effective. When a medal is inserted into the medal insertion slot 32 in this state, the medal may be returned to the tray 61 or may be stored until the credit reaches the upper limit.

  When the player tilts the start switch 36 in a state where the operation of the start switch 36 is enabled, the three reels 40L, 40C, and 40R start rotating. As a result, the symbols printed on the respective outer peripheral surfaces of the reels 40L, 40C, and 40R are, in principle, displayed (scrolled) in the display window 21 from top to bottom, but during the freeze effect described later, the symbols are displayed. May be displayed fluctuating from bottom to top.

  Stop switches 37L, 37C and 37R are provided in the center of the front of the operation panel unit 30 in correspondence with the reels 40L, 40C and 40R. Here, the stop switches 37L, 37C, and 37R are so-called self-illuminated push button switches, and have a structure in which the push button portion emits light and its emission color can be changed. For example, when the operation of the stop switch is invalid (the state is not accepted), the push button portion of the stop switch has a red light emission color, and when the operation is valid (the state is acceptable), the button is blue. It becomes the emission color. The stop switches 37L, 37C, and 37R are games provided that the rotation speed of the reels 40L, 40C, and 40R reaches a predetermined steady-state rotation speed (for example, 80 rotations / minute; also simply referred to as "constant speed"). User's operation becomes effective. Note that while the operation of the stop switch by the player is disabled, the stop switch may be turned off instead of emitting red light.

  When the left stop switch 37L is pushed during the game, the reel stop control of the left reel 40L is performed in the game to stop the rotation. When the middle stop switch 37C is pushed, the middle reel is pushed. When the reel stop control of the 40C is performed and the rotation is stopped, and the right stop switch 37R is pressed, the reel stop control of the right reel 40R is performed and the rotation is stopped. Hereinafter, the operation of the first stop switch after all the reels start rotating is referred to as a first stop operation, the second operation is referred to as a second stop operation, and the last operation is referred to as a third stop operation. When the reels 40L, 40C, and 40R stop, the center positions of three consecutive symbol areas stopped and displayed on the display window 21 out of the 20 symbol areas set on the outer peripheral surface of each reel are displayed on the display window. The stop is performed so as to match the center positions of the upper stage U, the middle stage M, and the lower stage D set in 21. Here, a position where the center position of the symbol area matches the center position of the stop display position is called a fixed position.

  A clearing switch 33 is provided on the left side of the operation panel unit 30. When operated within the bet acceptance period for medals, all medals bet and medals that have been credited are refunded, and the number of credits indicator is displayed. The value displayed at 27 becomes “0”. Here, the term “clearing” may be described as “payment”. During the medal bet acceptance period, for example, after all reels are stopped (when medals are paid out, the payout of medals ends), a predetermined number of medals are bet and the operation of the start switch 36 is enabled. Until it becomes. When the above-mentioned settlement switch 33 is operated once, all the medals bet and credits are refunded. For example, there are medals bet and medals credited. When the clearing switch 33 is operated, only the betted medals are refunded. In this state (medals are not betted), when the clearing switch 33 is operated again, a credit is given. All medals may be paid out. Also, if the clearing switch 33 is operated when the replaying game is won in a certain game and the replaying is performed in the next game, only the credited medals are refunded and the replaying is executed as it is. It is good to make it possible.

  Below the operation panel unit 30, a lower panel 50 on which a model name of the slot machine 10, a character adopted as a motif, and the like are drawn is provided. A left side lamp 52L is provided on the left side of the lower panel 50, and a right side lamp 52R is provided on the right side. The side lamps 52L and 52R are decoration lamps that blink in a predetermined pattern according to a game standby state or a game result. A medal payout opening 60 for paying out medals to a player is provided substantially at the center below the lower panel 50.

  For example, when the reels 40L, 40C, and 40R stop and the combination of the three symbols stopped and displayed along the pay line L corresponds to the winning combination (also referred to as "small combination"), the winning The number of medals corresponding to the role is stored in the credit, or the medal payout device installed inside the slot machine 10 is operated (specifically, the hopper motor is driven) and stored in the hopper of the medal payout device. Of the medals that have been won, medals of the number corresponding to the winning prize are paid out. Further, if the clearing switch 33 is operated in a state where the medal is credited, the credited medal is paid out. Then, the medals paid out from the medal payout port 60 are stored in the receiving tray 61. Sound transmission holes 62R and 62L for passing sounds emitted from speakers 64R and 64L (described later) housed inside the slot machine 10 are provided on the right and left sides of the medal payout slot 60, respectively. I have.

  An image display device 70 including a liquid crystal display panel is provided above the front panel 20. The image display device 70 is not limited to the liquid crystal display panel, and any other display device can be used as long as the image information and the character information can be visually recognized by the player during the game. The image display device 70 includes a system menu screen to be described later, an image selected on the system menu screen, a game history, a demonstration image displayed during game standby (a so-called demonstration screen), a lottery result, and a stop switch. Effect image for notifying the operation mode (operation timing or operation order) of the slot machine, the progress of the game inherent in the slot machine (medal bet → operation of start switch 36 → reel rotation → operation of stop switches 37L, 37C, 37R → An effect image or the like according to (all reel rotation stopped) can be displayed.

  Above the image display device 70, the reels 40L, 40C, and 40R are stopped and a winning combination is won, or a medal is easily paid out by a game (an advantageous state for the player). An effect lamp 72 that blinks in a predetermined pattern in accordance with the pattern is provided. A left decorative lamp 72L is provided on the left side of the effect lamp 72, and a right decorative lamp 72R is provided on the right side. Like the side lamps 52L, 52R, the decorative lamps 72L, 72R are decorative lamps that blink according to a predetermined pattern during a game standby or according to a game result.

<Description of the internal structure of the slot machine>
Next, an internal structure of the slot machine 10 will be described with reference to FIG. In FIG. 2, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. FIG. 2 illustrates a state in which the front door 14 is opened, and illustrates the back side (the inside of the housing) of the front door 14 and the inside of the main body 12.

  In FIG. 2, above the front door 14, on the back side of the display device 70 shown in FIG. 1, sub-control means 200 for controlling the effect of a game performed in the slot machine 10 is attached in a state housed in a case. I have. The sub-control unit 200 includes a sub-control board and an image control board, which will be described later. Each of these control boards is configured with a circuit including electronic components such as a CPU and other ICs mounted on a printed board. The above-described selector 80 is provided below the display window 21 to select medals inserted into the medal insertion slot 32 shown in FIG. For example, if the inserted medals do not conform to a predetermined standard in external dimensions or material, the medals are guided to a return passage 81a connected to the medal payout port 60 in FIG.

  On the other hand, when the external dimensions and material of the inserted medals conform to predetermined standards, the medals are sent to a hopper 83a (a container for storing medals) of a medal dispensing device 83 described later. It leads to the receiving passage 81b. The selector 80 includes a first insertion sensor 48a, a second insertion sensor 48b, and a medal passage sensor 49. These sensors detect a medal guided to the receiving passage 81b and detect an abnormality related to medal insertion. ing. For example, an abnormality regarding the inserted medals is determined based on a time difference in which medals are detected by the first insertion sensor 48a and the second insertion sensor 48b, an order of detection, and the like. If the medal passage sensor 49 continues to detect medals for a predetermined period of time or more, it is determined that a medal jam has occurred in the selector 80. Note that speakers 64R and 64L are attached to the lower side of the front door 14 at positions corresponding to the sound transmission holes 62R and 62L shown in FIG.

  Next, inside the main body 12, a door switch 44 for detecting opening and closing of the front door 14 is attached at the upper right of the front. Here, the door switch 44 is provided on the main body 12 side in FIG. 2, but may be provided on the front door 14 side. A main control unit 100 for controlling a game is mounted above the back plate of the main body 12 in a state housed in a case. The main control means 100 includes a CPU, a ROM (read only memory), an RWM (read / write memory), a random number generation means (random number circuit), a timer counting means (timer circuit), and one I / O port. It is configured in a chip. The main control means 100 is also called a main control board, and a circuit for realizing the function of the main control means 100 is formed on a single printed circuit board. A 7-segment display (set value display) 87 for displaying set values is mounted on the printed circuit board. The set value is used to set a winning probability of a predetermined combination in a lottery to be described later, and generally, six settings from “1” to “6” are possible.

  The place where the set value display 87 is installed is not limited to the printed board of the main control unit 100, but may be a printed board on which the set value display 87 is mounted, for example, behind the front door 14. Further, the set value may be displayed on the credit display 27 or the acquired number display 28 described above. The set value display 87 corresponds to a display means capable of displaying the set value. When the set value can be displayed on the credit display 27 or the acquired number display 28, these displays also correspond to the display means.

  2, a power supply unit 82, a medal payout device 83, and a medal auxiliary storage 84 are arranged in order from the left side in FIG. The power supply unit 82 converts the input AC 100 V into a plurality of types of DC voltages, and supplies the DC voltages to various devices included in the slot machine 10. On the front panel surface of the power supply unit 82, a power switch 82a, which is a rocker switch for turning on / off the power of the slot machine 10, is provided on the upper left side. On the right side of the power switch 82a, a key switch 82b for enabling a change of a so-called set value is provided. A push button type setting / reset switch 82c is provided below the power switch 82a. The setting / reset switch 82c is operated when restarting the game control when the control of the game is forcibly stopped due to detection of various abnormalities described later.

  It should be noted that when the key is turned counterclockwise on the door key 31 shown in FIG. 1, the same operation as when the set / reset switch 82c is operated is exhibited. Each of the key switch 82b and the setting / reset switch 82c described above corresponds to switching means capable of switching between an off state (first state) and an on state (second state). Further, the door key 30 is also provided with switching means that can switch between a state in which the keypad is neutral (first state) and a state in which the keypad is turned counterclockwise to release the error (second state). Equivalent to. The key switch 82b and the setting / reset switch 82c are attached to the power supply unit 82 provided in the main body 12, but may be attached to the back of the front door 14. As described above, since the key switch 82b and the setting / reset switch 82c are provided inside the housing including the main body 12 and the front door 14, the operation becomes difficult when the front door 14 is closed. I have. Further, “operation is difficult” means that, for example, in a state where the front door 14 is closed, an operation must be performed by a wrongdoing using a wire or a bar-shaped member, or the front door 14 is open. , The door switch 44 cannot be detected due to fraud, and the front door 14 must be opened for operation.

  The medal payout device 83 is a device that pays out medals when a small winning combination is won as a result of a game or when returning a credited medal to a player. Specifically, when a disk-shaped disk (not shown) provided inside the medal payout device 83 is rotated by the hopper motor 46, the medals stored in the hopper 83a are ejected one by one from the discharge port 83b. It has become. On the other hand, a payout passage 81c connected to the medal payout opening 61 is provided on the back surface of the front door 14, and medals jumping out of the discharge opening 83b jump into a medal hole 81d formed in the payout passage 81c. Then, a medal is paid out to the receiving tray 61. In the medal payout device 83, a first payout sensor 47a and a second payout sensor 47b for detecting a medal to be discharged are provided near the discharge port 83b. The main control means 100 counts the paid-out medals based on the output signals of the payout sensors and detects an abnormality related to the payout of the medals.

  The medal auxiliary storage 84 is a box for receiving medals overflowing from the hopper 83a due to a large amount of medals stored in the hopper 83a of the medal payout device 83. On the vertical wall surface on the far side of the medal auxiliary storage 84, three round holes 84a are formed, two near the opening K and one near the bottom surface. When the medal auxiliary storage 84 is placed at a predetermined position in the main body 12, the two rod-shaped electrodes 85a and one rod-shaped electrode 85b attached to the main body 12 correspond to each other. Through the round hole 84a to be inserted, it penetrates into the medal auxiliary storage 84. Then, the medals are accumulated in the medal auxiliary storage 84, and when the medals are accumulated up to the position of the rod-shaped electrode 85a, the medals themselves are electrically connected between the rod-shaped electrodes 85a and 85b. The main control means 100 detects that the stored medals have reached the upper limit by detecting this conduction. The number of the rod-shaped electrodes shown in FIG. 2 is two in the vicinity of the opening K and one in the vicinity of the bottom surface. There may be a total of two near one, two near the opening K, and two near the bottom surface, for a total of four.

  An external centralized terminal board 86 is provided in the main body 12 below the door switch 44. The external centralized terminal board 86 outputs a signal including information on a game performed in the slot machine 10 to various external devices (a so-called hall computer, a game history display device installed in a game hall, and the like). It is a relay board for performing. A reel unit that includes the reels 40L, 40C, and 40R is installed substantially at the center of the main body 12. Inside the reels 40L, 40C, and 40R, stepping motors 42L, 42C, and 42R for rotating the corresponding reels, respectively, and turning sensors 43L and 43C for detecting reference positions (described later) of the corresponding reels. , 43R are provided.

[Description of symbols and symbol arrays]
Next, with reference to FIG. 3, the arrangement of the symbols printed on the reel tape attached to the outer peripheral surfaces of the reels 40L, 40C, and 40R will be described. As shown in FIG. 3A, 20 symbols are printed on each outer peripheral surface of the reels 40L, 40C and 40R. In each symbol, one symbol is printed in each symbol area divided into 20 equal parts in the longitudinal direction of the reel tape. Also, as shown in FIG. 3B, the types of symbols displayed in each symbol region include “Red 7” symbol and “White 7” symbol in which the numeral 7 is represented in red and white, and “BAR”. "Bar" design with "" character, "bell" design with yellow bell motif, "Replay A" design with blue plum motif, and "Replay B" with dark blue plum motif There are a "watermelon A" and a "watermelon B" symbol with a green watermelon motif, a "cherry" symbol with a red cherry motif, and a "blank" symbol with a tree motif.

  Further, in each of the symbol areas of the reel tape attached to each of the reels 40L, 40C, and 40R, symbol numbers "0" to "19" are predetermined as shown in FIG. The type code of the symbol corresponding to the symbol number is stored in the ROM of the main control means 100. The symbol number of each reel and the corresponding type code are used when the slot machine 10 recognizes the symbol displayed at each stop display position (upper stage U, middle stage M, lower stage D) of the display window 21 for each reel. Referenced. Each of the reel tapes shown in FIG. 3A shows a state where the symbol numbers "0" and "1" are separated and developed, and the respective reel tapes are attached to the outer peripheral surfaces of the reels 40L, 40C and 40R. , The symbols with the symbol numbers “0” and “1” are continuous.

[Description of correspondence between symbol combinations and condition devices]
Next, the correspondence between the symbol combination displayed on the winning line and the condition device when each reel of the symbol array described above stops will be described with reference to FIGS. The symbol combinations shown in FIG. 4 to FIG. 7 show those in which a privilege is given to the player when the symbol combinations are aligned on the pay line. There are three types of benefits given to the player, replay, winning, and BB, and a predetermined symbol combination is associated with these benefits. Here, the symbol combination shown in FIG. 4 (a) corresponds to the symbol combination of the bonus to which BB can be given, and the symbol combination shown in FIG. 4 (b) and FIG. The symbol combinations shown in FIGS. 6 and 7 correspond to the symbol combinations of the small winning combinations that can give a prize.

  Among the above-mentioned benefits, the re-game is a privilege that, when the corresponding symbol combinations are aligned on the winning line, a game (re-game) can be performed again without inserting medals only for the next game. The winning is a privilege in which, when the corresponding symbol combinations are aligned on the winning line, the number of medals corresponding to the symbol combinations is paid out to the player. BB is a privilege of performing a BB game (bonus game) in which an RB game advantageous to the player is repeatedly performed from the next game until a predetermined end condition is satisfied when the corresponding symbol combinations are aligned on the winning line. . The condition for ending the BB game is satisfied when the number of medals paid out during the BB game exceeds a predetermined number (456 in the present embodiment).

  The RB game executed during the BB game is a game in which a winning combination is won with an extremely high probability. During the RB game, a predetermined number of prizes or RB games are started out of a number not exceeding 8 times. When the predetermined number of games out of the number of games that does not exceed 12 has been performed, the game ends. When the RB game ends, if the BB game end condition is not satisfied, the RB game starts from the next game. If the BB game end condition is satisfied during the RB game, the RB game and the BB game are ended even during the RB game.

  In the following, when a symbol combination is expressed, the symbol name on each reel is described in the order of a left reel, a center reel, and a right reel, and is enclosed in square brackets. For example, the symbol combination corresponding to the BB game shown in FIG. 3A is represented as “white 7-white 7-white 7”.

  Condition devices are associated with the symbol combinations shown in FIGS. The condition device is a device that is a necessary condition for aligning the associated symbol combination on the winning line. When the condition device is activated, the symbol combination corresponding to the condition device is displayed on the winning line. It can be aligned. Which condition device is activated is determined by a role lottery described later. Then, as shown in FIG. 4A, the condition combination “BB01” is associated with the symbol combination “white 7-white 7-white 7” corresponding to the BB game. The condition devices corresponding to the symbol combinations of the re-games shown in FIG. 4B and FIG. 5 include “re-game 01” to “re-game 13”, and each condition device has one or more symbols. Combinations are associated.

  The condition devices corresponding to the symbol combinations of winning (small winning) shown in FIG. 6 or FIG. 7 include “winning 01” to “winning 24”. One or more symbol combinations are associated with each other. Here, when the symbol combinations corresponding to the condition devices "winning 01" to "winning 03" and "winning 24" are aligned on the winning line, nine medals are paid out. When the symbol combinations corresponding to the condition devices "winning 04" to "winning 08" are aligned on the winning line, one medal is paid out. Further, when the symbol combinations corresponding to the condition devices “winning 09” to “winning 23” are aligned on the winning line, eight medals are paid out.

[Description of control means]
Next, control means for controlling the slot machine 10 will be described with reference to a functional block diagram shown in FIG. The control means of the slot machine 10 includes a main control means 100 for controlling the progress of the game and a sub-control means 200 for controlling the effect of the game. The main control means 100 controls the progress of the game in accordance with the operation of the player, and the sub-control means 200 performs effects and the like which are executed with the progress of the game based on the information transmitted from the main control means 100. Controls notification of various information. The transmission of information exchanged between the main control means 100 and the sub control means 200 is limited to one direction from the main control means 100 to the sub control means 200, and some information is transmitted from the sub control means 200. There is no direct transmission to the main control means 100.

<< Description of main control means >>
<Main control means and peripheral hardware configuration>
The main control means 100 includes a CPU, a ROM (read only memory, also referred to as storage means), a RWM (read / write memory, also referred to as storage means), a random number generation means (random number circuit), and a timer count means ( Timer circuit) and an I / O port are formed in one chip. The main control means 100 is also called a main control board, and a circuit for realizing the functions of the main control means 100 is formed on one board. Here, the above-described CPU includes an accumulator (A register) for performing an operation, a plurality of general-purpose registers (B register, C register, D register, E register, H register, L register, and Q register), and a flag register. And Each of these registers is composed of one byte (8 bits). Of the general purpose registers, the B and C registers, the D and E registers, and the H and L registers can be used as pairs and used as 16-bit (2-byte) registers. When two general-purpose registers are used as a pair, two alphabets representing each register are collectively described. For example, when an H register and an L register are used as a pair, they are referred to as an HL register.

  In the flag register, each bit is a flag indicating a state relating to the operation result by the CPU. The flag register of the present embodiment includes a carry flag, a zero flag, and a second zero flag. Here, the carry flag is a flag that becomes “1” when a carry occurs when performing an operation (addition) and when a carry occurs when performing an operation (subtraction). The zero flag is a flag that becomes “1” when the operation result becomes “0”. The second zero flag is a flag that becomes “1” when the zero flag becomes “1” and when a predetermined operation (LD instruction) is performed. In FIG. 8, the same components as those shown in FIGS. 1 and 2 are denoted by the same reference numerals, and detailed description thereof will be omitted.

  The random number generating means (random number circuit) generates random numbers used in performing various lotteries, and the timer counting means (timer circuit) generates an interrupt request based on a count value of a clock signal for operating a CPU or the like. Generate a signal. Further, the I / O port includes an operation unit 300, various lamps, stepping motors 42L, 42C, 42R, body sensors 43L, 43C, 43R, a door switch 44, a blocker 45, a hopper motor 46, payout sensors 47a, 47b, A signal for each component such as the input sensors 48a and 48b, the medal passage sensor 49, and the external central terminal board 86 is output, and a signal from each component is input. The various lamps include, for example, the set value display 87 mounted on the main control board described above in addition to the one shown in FIG. The set value display 87 is composed of one 7-segment display, and displays the current set value by numerical values (1 to 6) during a setting confirmation mode or a setting change mode described later.

  Here, the stepping motors 42L, 42C, 42R rotate or stop the corresponding reels 40L, 40C, 40R according to the excitation signal output from the main control means 100. The torso sensors 43L, 43C, and 43R are provided corresponding to the reels 40L, 40C, and 40R, respectively. When detecting the index (detected member) provided at the reference position of the corresponding reel, the detection signal is transmitted. Output to main control means 100. Accordingly, the main control means 100 can determine the rotation position of the reel (and, consequently, the symbol displayed on the display window 21) based on counting the number of steps of the stepping motor based on the detected position of the index. it can. Here, in the present embodiment, since the drive control of the stepping motor is performed by the timer interruption processing, the number of steps of the stepping motor may be counted based on the number of times of execution of the timer interruption processing. For example, in this embodiment, when the stepping motor has reached the constant speed, the stepping motor is rotated by one step each time the timer interrupt processing is executed once. Therefore, if the count value of the number of times of execution of the timer interrupt processing is cleared every time the above-described reference position is detected, and if the stepping motor has reached a constant speed, the number of times of execution of the timer interrupt processing is increased from the reference position. It becomes the number of steps.

  The hopper motor 46 is provided in the medal payout device 83 (see FIG. 2), and discharges the stored medals from the medal payout outlet 60 in accordance with a drive signal output from the main control unit 100. The payout sensors 47a and 47b detect medals paid out when the hopper motor 46 is driven, and output a detection signal to the main control unit 100. The blocker 45 is provided in the selector 80 (see FIG. 2), and forms or cancels a medal flow path according to an on / off signal from the main control unit 100. When the blocker 45 is on, a medal flow path is formed, and medals inserted from the medal insertion slot 32 are stored in the hopper 83a of the medal payout device 83. On the other hand, when the blocker 45 is off, no medal flow path is formed, and medals inserted from the medal insertion slot 32 are discharged from the medal payout port 60. The door switch 44 detects opening and closing of the front door 14 and outputs a detection signal to the main control unit 100.

  The external central terminal board 86 relays various signals output from the main control unit 100 to information related to the game currently played by the slot machine 10 to an external device such as a game information display device or a hall computer. Here, the signals output from the external central terminal board 86 include a medal insertion signal in which the same number of pulse signals as the number of bets bet (betting) on the game based on the operation of the start switch 36 are output. A medal payout signal that outputs the same number of pulse signals as the number of medals paid out based on the winning of the role, a BB signal that is turned on during a BB game, and an advantageous state that is turned on during an advantageous section described later. There are section signals and the like.

  The external central terminal board 86 is provided with a relay circuit for each signal to be output, and the on / off state of the corresponding signal is switched by opening and closing these relay circuits. For example, a photocoupler is used instead of the relay circuit. You may.

  The operation means 300 includes a power switch 82a, a key switch 82b, and a setting / reset switch 82c shown in FIG. 2, in addition to the various switches provided on the front door of the slot machine 10 shown in FIG. The power switch 82a is a switch for turning on / off the power supplied to each device in the slot machine 10. The key switch 82b has a keyhole, and is turned on or off by rotating a setting change key (setting key) inserted into the keyhole. When an error is detected, the setting / reset switch 82c recovers (resets) from the error state, changes the set value (the set value data described later is not changed, and is displayed on the set value display 87). The push-button switch is operated when the value is changed. Here, in the present embodiment, the reset and the change of the set value are enabled by one push-button switch, but the reset and the change of the set value may be enabled by separate switches.

(Description of input port of main control means)
Next, with reference to FIG. 11, the types of input ports for receiving signals input from the above-described units and the content of signals input to each input port in main control means 100 will be described. The main control means 100 has three input ports of input port 0 to input port 2 for receiving 8-bit (bits 0 to 7) signals.

  First, a signal input to the input port 0 will be described with reference to FIG. A set / reset switch signal is input to bit 0 of input port 0 with negative logic (active low). That is, when the setting / reset switch 82c is turned on, the voltage of the setting / reset switch signal goes to low level, and when turned off, it goes to high level. A setting key switch signal is input to bit 1 of input port 0 with positive logic (active high). That is, when the key switch 82b is turned on, the voltage of the setting key switch signal becomes high level, and when it is turned off, it becomes low level. The door switch signal is input to bit 2 of the input port 0 with positive logic. That is, when the front door 14 is closed, the door switch 44 is turned off, the voltage of the door switch signal becomes low level, and when the front door 14 is opened, the door switch 44 is turned on, The door switch signal becomes high level.

  A power-off detection signal is input to bit 5 of input port 0 with negative logic. In other words, in the power supply unit 82, when the power supply voltage is at a normal value, the voltage of the power-off detection signal is at a high level, but when the power supply voltage falls below a predetermined value (power-off is detected), the power-off detection signal goes low. Become. A full detection signal is input to bit 6 of input port 0 with negative logic. That is, when the rod-shaped electrode 85a and the rod-shaped electrode 85b shown in FIG. 2 are not electrically connected, the full detection signal is at a high level, and when the rod-shaped electrode 85a and the rod-shaped electrode 85b are connected, the full detection signal is low. Level.

  Bit 3, bit 4, and bit 7 of input port 0 are not used, and no signal is supplied from outside.

  Next, a signal input to the input port 1 will be described with reference to FIG. Stop switch sensor signals 3 to 1 are input to bits 0 to 2 of input port 1 in positive logic. Here, the stop switch sensor 3 signal input to bit 0 corresponds to the right stop switch 37R, the stop switch sensor 2 signal input to bit 1 corresponds to the middle stop switch 37C, and the stop input to bit 2 The switch sensor 1 signal corresponds to the left stop switch 37L. Each stop switch sensor signal is at a high level when the corresponding stop switch is operated, and is at a low level when the corresponding stop switch is not operated.

  A three-sheet insertion sensor signal is input to bit 3 of the input port 1 in a positive logic. That is, when the maximum bet switch 35 is operated, the voltage of the three-sheet insertion sensor signal becomes a high level, and when not operated, it becomes a low level. A single-sheet switch signal is input to bit 4 of input port 1 with negative logic. That is, when the front door 14 is closed, the door switch 44 is turned on, and when the 1-bet switch 34 is operated, the voltage of the single-sheet switch signal becomes low level, and the door switch 44 is not operated. Goes high.

  A clearing switch signal is input to bit 5 of input port 1 with negative logic. That is, when the settlement switch 33 is operated, the voltage of the settlement switch signal becomes low level, and when not operated, it becomes high level. A start switch sensor signal is input to bit 6 of input port 1 with negative logic. That is, when the start switch 36 is tilted, the voltage of the start switch sensor signal goes to a low level, and when not tilted, it goes to a high level.

  The bit 7 of the input port 1 is not used, and no signal is supplied from outside.

  Next, a signal input to the input port 2 will be described with reference to FIG. The torso sensor (first to third torso) signals are input to bits 0 to 2 of the input port 2 in positive logic. Here, the torso sensor (first torso) signal input to bit 0 corresponds to the left torso sensor 43L, and the torso sensor (second torso) signal to be input to bit 1 is the left torso sensor A torso sensor (third torso) signal input to the bit 2 corresponding to 43C corresponds to the right torso sensor 43R. Each turn sensor signal goes high when each turn sensor detects the reference position of the corresponding reel, and goes low when no reference position is detected.

  The payout sensor 2 signal is input to bit 3 of the input port 2 in positive logic. That is, when the second payout sensor 47b detects a medal, the voltage of the payout sensor 2 signal goes high, and when no medal is detected, the voltage goes low. The payout sensor 1 signal is input to bit 4 of the input port 2 with negative logic. That is, when the first payout sensor 47a detects a medal, the voltage of the payout sensor 1 signal goes low, and when no medal is detected, the voltage goes high.

  The closing sensor 2 signal is input to bit 5 of the input port 2 with negative logic. That is, when the second insertion sensor 48b detects a medal, the voltage of the insertion sensor 2 signal becomes a low level, and when no medal is detected, the voltage becomes a high level. A closing sensor 1 signal is input to bit 6 of the input port 2 with negative logic. That is, when the first insertion sensor 48a detects a medal, the voltage of the insertion sensor 1 signal becomes low level, and when no medal is detected, the voltage becomes high level. A medal path sensor signal is input to bit 7 of input port 2 with negative logic. That is, when the medal passage sensor 49 detects a medal, the voltage of the medal passage sensor signal becomes low level, and when no medal is detected, the voltage becomes high level.

  The assignment and logic of the signals input to the input ports 0 to 2 can be changed as appropriate. For example, the door switch signal corresponding to bit 2 of input port 0 may correspond to bit 3, and the door switch signal is set to negative logic, that is, the door switch 44 is turned off when the front door 14 is closed. When turned on, the voltage of the door switch signal becomes a high level, and when the front door 14 is opened, the door switch 44 may be turned off and the door switch signal may become a low level.

<Function block of main control unit>
Returning to FIG. 8, the main control means 100 includes a winning combination determination means 110, a freeze control means 120, a reel control means 130, a state control means 140, a notification game control means 150, a winning determination means 160, It includes a detecting unit 170, a control command transmitting unit 180, and an external signal transmitting unit 190. The function of each unit described below is realized when the CPU configuring the main control unit 100 executes a control program stored in the ROM.

(Explanation of winning combination determination means)
The winning combination determining means 110 determines a winning combination by a lottery (role lottery) based on a random number (numeric value range: 0 to 65535) generated by a random number generating means included in the main control means 100. The determined winning combination is also referred to as a “lottery result based on the winning combination determining means”. FIG. 9 shows the types of winning combinations (in other words, lottery targets of the winning lottery) and the condition devices that are activated when each winning combination is determined. Also, in FIG. 9, the column A shows the value of the bonus item winning number, and the column B shows the value of the winning / replay winning number. The winning combination number and the winning / replay winning number are information indicating the result of the winning lottery, and information based on these winning numbers is transmitted to the sub-control means 200.

  In FIG. 9, the winning combination “BB01” (hereinafter, also referred to as “BB combination, special combination”) corresponds to the condition device “BB01”, and the combination BB is determined as the winning combination in the combination drawing (in other words, “BB”). When the role is won "), the condition device" BB01 "is activated, and the symbol combination" white 7-white 7-white 7 "can be aligned on the winning line. In addition, the winning combination number becomes 1 by winning the BB combination.

  Next, the winning combinations “replay-A”, “replay-B1” to “replay-B5”, “replay-C1” to “replay-C5”, “replay-D1” to “replay” -D3 "," Replay-E "," Replay-F "," Replay-G1 "to" Replay-G3 "," Replay-H1 "to" Replay-H3 "," Replay- " Each of "I" (hereinafter collectively referred to as "replay combination, replay combination") is associated with one of the condition devices "replay 01" to "replay 13". Here, only the condition device “re-game 07” is associated with the re-game-E, but a plurality of condition devices are associated with other re-games. Then, when a replaying game associated with a plurality of condition devices is won, all the condition devices associated with the replay combination are activated. For example, when the re-game-A is won, the condition devices “re-game 01” and “re-game 02” are activated.

  In addition, the winning combinations "winning-A1" to "winning-A6", "winning-B1" to "winning-B6", "winning-C1" to "winning-C6", "winning-D", "winning-E1" ”To“ winning-E6 ”,“ winning-F ”,“ winning-G ”,“ winning-H ”, and“ winning-I ”(hereinafter collectively referred to as“ winning role, small role ”). , And one of the condition devices “winning 01” to “winning 24”. Here, each winning combination is associated with a plurality of condition devices. When the winning combination with which a plurality of condition devices are associated is won, all the associated condition devices are activated. For example, when winning-A1 is won, the condition devices “winning 01”, “winning 04” and “winning 05” are activated.

  When the BB combination is won and the condition device “BB01” is activated, the operating state of the condition device “BB01” is maintained until the BB combination is won, and the value of the role item winning number is also maintained at 1. This state is referred to as “internal” or “carrying bonus flag”. Conversely, a state in which the BB combination has not been won (in other words, a state in which the condition device “BB01” has not been activated) is referred to as “non-internal” or “non-carrying bonus flag”.

  On the other hand, when the replaying or winning combination is won in the lottery, the condition device corresponding to the winning combination is operated, but when the game in which the winning is determined is completed, the operated condition device is deactivated. Return to the state. When the replaying or winning combination is determined as the winning combination, the value corresponding to the winning combination (see column B in FIG. 9) becomes the winning and replaying winning number. The value does not change. As described above, the winning item number and the winning / replay winning number are determined independently of each other.

  Next, a lottery table that defines the winning probability of each winning combination will be described with reference to FIG. The lottery table shown in FIG. 10 indicates that, for each winning combination, the number of random numbers to be won (hereinafter referred to as “placement”) out of the total number (65536) of random numbers that can be generated by the random number generating means of the main control means 100. Number "). Therefore, the value obtained by dividing the number associated with each winning combination by 65536 is the winning probability of the winning combination.

  Further, as shown in FIG. 10, in the present embodiment, six RT states of non-RT (also referred to as RT0) and RT1 to 5 are defined, and the winning probability of the winning combination described above is determined according to each RT state. Is different. Here, RT0 to RT3 are in a state in which the BB combination has not been won in the lottery drawing (non-internal), RT4 is in a state in which the BB combination has been elected but has not won (internal), and RT5 is in RT5. A BB game is in progress. The RT state shifts according to a predetermined shift condition, and the determination as to whether the shift condition is satisfied and the shift destination are controlled by an RT state shift unit 142 described later.

  In addition, with respect to the combinations to be drawn in each RT state, there is a possibility that the BB combination, re-game-A, and the prize-A to H may be won in RT0, and the BB combination, re-game-A, B1 in RT1. B5, E, F, winning-A to H may be won. In RT2, there is a possibility that the BB combination, replay-A, C1 to C5, E, F and winning-A to H will be won. In RT3, there is a possibility that the BB combination, re-games-D1 to D3, E, F, G1 to G3, H1 to H3, and winnings-A to H will be won. In RT4, there is a possibility that the BB combination, the replay-A, and the winning-A to H will be won. In RT5, the replay-I or the winning-I is always won (winning probability 100%).

  Here, in RT0 to RT3, among the 74 numbers associated with BB01, 20 is the number to be won together with the winning-F described later, and 30 is the number to be won together with the winning-G described later. . Therefore, the number of entries that BB01 wins alone is 24. In addition, among the 596 numbers set in association with Win-F, 20 is the win number together with BB01, and thus the Win-F alone wins 572. Also, among the 160 numbers associated with the winning-G, 30 is the number winning with BB01, so the number of winnings-G alone is 130.

  Each of the above-mentioned winning combinations is assigned a corresponding winning number. When one of the winning combinations is determined by the lottery drawing, the winning number corresponding to the determined winning combination is determined as the result of the role drawing by the RWM. It is stored in a predetermined storage area. Here, the winning numbers include a character winning number and a winning / replaying winning number, which are given to each winning combination in the lottery table shown in FIG. 10, and a character winning number 1 is assigned to BB01. (See column A in FIG. 10). Winning / replay winning numbers 1 to 52 are assigned to the replays-A to I and the winnings-A1 to I (see column B in FIG. 10). In addition, the role winning number 0 indicates that BB01 has not been won, and the winning / replay winning number 0 indicates that the result of the role lottery has been lost.

  When a replay or winning combination is won in the lottery, the winning / replay winning number corresponding to the winning combination is stored in the storage area of the winning / replay winning number (“predetermined storage area” in the storage means (RWM)). . "). The winning number stored in the win / re-game winning number storage area is updated to the initial value “0” at least between the end of the game and the start of the next game.

  In addition, while the BB combination is not won in the role lottery, “0” is stored in the storage area of the role winning number, and “1” is stored in the storage area of the role winning number when the BB role is won. Is done. This state is maintained until the BB combination wins, and is updated to the initial value “0” from the time the BB combination wins until the end of the BB game.

  Further, among the respective RT states, the (synthetic) winning probabilities of the replaying combinations at RT0 to RT2 are all about 1 / 7.33, the winning probabilities of the replaying combinations at RT3 are about 1 / 1.53, and The winning probability of the gaming role is about 1 / 1.94, and the winning probability of the replaying game at RT5 is about 1/1024. In the non-internal state, the winning probability of the replaying combination at RT3 is dramatically increased as compared with other RT states, so that it is possible to play a game while suppressing the consumption of medals. This increases the chances of winning the BB combination with a small investment in the RT3, which is advantageous for the player.

  Further, in this embodiment, besides the lottery table shown in FIG. 10, five lottery tables having different winning probabilities of each winning combination are provided, and the game is performed by the key switch 82b and the setting / reset switch 82c shown in FIG. Can specify the lottery table to be used. That is, one unique number is assigned to each lottery table in advance among numbers 1 to 6 (corresponding to 0 to 5 of setting value data described later), and the setting change key 82b and the setting / reset switch 82c The lottery table corresponding to the set value (0 to 5) set by is used for the game.

(Explanation of freeze control means)
Returning to FIG. 8, when the predetermined condition is satisfied, the freeze control means 120 executes a so-called freeze effect of delaying the progress of the game after the start switch 36 is operated. The execution timing of the freeze effect in the present embodiment is between the time when the start switch 36 is operated and the time when the reel starts rotating, and the time between when the reel starts to rotate and the time when the operation of the stop switch can be accepted. Between the time when the operation of the stop switch can be accepted and the time when each stop switch is operated, the time between when the rotation of all reels is stopped and the time when the next game can be started, etc. is there.

  Further, in the present embodiment, as a freeze effect, an effect (reel effect) for improving the interest of the game is provided by appropriately rotating the reels 40L, 40C, 40R, and the freeze control means 120 performs the freeze effect. In addition to determining whether or not to execute, the type of reel effect to be executed may also be determined. As the type of reel effect, for example, the reel is rotated in a direction opposite to the normal rotation, a specific symbol combination is displayed by rotating the reel by a predetermined number of symbols, or a predetermined reel among a plurality of reels is stopped It is conceivable to change the state of the reel to a rotating state, change the rotation speed of the reel, or change the operation of the reel according to the operation of the player. The predetermined condition for executing the freeze by the freeze control means 120 is that a predetermined result is obtained by a lottery, that a game advantageous to a player such as a BB game or an AT game has started, or that For example, the game is over.

  The freeze period in which the freeze effect is performed is set after a so-called wait period (the shortest time from the start of rotation of the reel in the previous game to the start of rotation of the reel in the next game, for example, 4.1 seconds). Or may be set including a wait period. If a wait period is included, determine whether the freeze effect ends during the wait period, and if so, set the freeze period after the wait period elapses, or the remaining wait period after the freeze effect ends Is resumed. Alternatively, such a determination process can be omitted by providing a freeze period longer than the wait period in advance.

(Explanation of reel control means)
The reel control means 130 controls the driving of the stepping motors 42L, 42C, 42R for rotating / stopping the reels 40L, 40C, 40R. That is, the rotation of the stepping motors 42L, 42C, and 42R is started based on the operation of the start switch 36 by the player, and when the rotation speed of the reels 40L, 40C, and 40R reaches the above-described constant speed, the constant speed is reduced. Maintain speed. When any one of the stop switches 37L, 37C, and 37R is operated, stop control is performed on a reel (more precisely, a stepping motor) corresponding to the operated stop switch.

  At this time, the reel control means 130 stops the rotation of the corresponding reel within 190 milliseconds after the stop switch is operated. Thus, assuming that the reel in which 20 symbols are provided on each reel as in the present embodiment stops the rotation of the reel within 190 milliseconds from the state of constant speed (80 rotations / minute), 80 (rotation) / 60 (seconds) × 0.19 (seconds) × 20 (symbol) = The reel may be stopped until the symbol for about 5.067 is rotated. However, the reel control unit 130 does not stop the symbol passing the stop display position (winning stop position) where the winning line L passes when the stop switch is operated, at the winning stop position.

  For this reason, when the stop switch is operated, any of the symbols located one upstream from the symbols passing through the winning stop position to the symbols located four upstream is won. It can be stopped at the stop position. Here, the range from the symbol located one upstream of the symbol passing the winning stop position to the symbol located four upstream when the stop switch is operated is referred to as a "stop control range". Also called.

  When one of the winning numbers is determined by the winning combination determining means 110, the reel control means 130 stops the rotation of the reels so that the symbol combination of the winning combination corresponding to the winning number stops on the winning line L. (Perform so-called pull-in control). However, when the symbols constituting the symbol combination of the winning combination are not within the stop control range, the reels are stopped so as to prevent a winning other than the winning combination from winning (so-called kick-off control is performed).

  In the symbol combinations shown in FIGS. 4 to 7, the symbol combinations corresponding to the replays 01 to 07 and 09 and the winnings 01 to 06 are necessarily set in relation to the symbol arrangement and the stop control range of each reel shown in FIG. 3. Since they can be aligned on the winning line L, there is no missing (the symbol combination corresponding to the winning combination is on the winning line L). On the other hand, there is a possibility that the symbol combination corresponding to BB01, the replay 08, and the winnings 07 to 24 may be omitted. Here, “missing” means a state in which the symbol combination corresponding to the winning combination (more specifically, the activated condition device) cannot be aligned on the winning line L. In this case, the game result is lost. Becomes

  However, even in the case of a winning combination in which a plurality of condition devices are activated, there is also a winning combination in which a symbol combination corresponding to any one of the condition devices is arranged, even in the case of a winning combination in which a drop-out may occur, such as winnings 07 to 24. . In other words, by operating a plurality of condition devices of the symbol combination that can be missed, the winning combination can be eliminated. For example, when the winning -H (winning / replaying game winning number 51) shown in FIG. 9 is determined as the winning combination, the condition devices for winning 07 and winning 08 are operated. At this time, the symbol combination corresponding to the prize 07 and the symbol combination corresponding to the prize 08 may be missed if individual symbol combinations are viewed, but if both symbol combinations are considered together, one of them is considered. The symbol combination corresponding to the condition device of (1) can always be aligned with the winning line L (that is, winning -H can always be won).

  Also, the re-games-B1 to D3 (winning / re-game winning numbers 2 to 14), the re-games-G1 to I (win-win / re-game winning numbers 17 to 23), and the winnings A1 to C6 (winning / winning) shown in FIG. When any one of the replay winning numbers 24 to 41) and the winnings E1 to E6 (winning / replay winning numbers 43 to 48) is determined to be a winning combination, the reel control means 130 sets the stop switches 37L, 37C, 37R. The symbol combination for which the pull-in control is preferentially performed is made different according to the operation order (hereinafter, also referred to as “push order”). For example, if the first condition device and the second condition device are activated when a certain winning combination is determined by a lottery, the stop switches 37L, 37C, 37R are operated by sequentially pushing (left → middle → right). If this is done, the pull-in control is preferentially performed for the symbol combination corresponding to the first condition device. However, when the symbol combination is operated by pressing in reverse (right → middle → left), the symbol corresponding to the second condition device is operated. The pull-in control is preferentially performed for the combination.

  In this way, a combination in which the symbol combination for performing the pull-in control is different according to the pressing order of the stop switch is also called a pressing combination, and in particular, a combination such as replay-B1-D3 and replay-G1-G3 is pressed in order of replay. Winning-Roles such as A1 to A6, B1 to B6, C1 to C6 and E1 to E6 are also called pushing order bells. Further, when the lottery result by the role lottery is the winning of the pressing order, the lottery result is also referred to as “specific lottery result”.

  For example, when one of the winnings A1 to A6 is won and the stop switches 37L, 37C and 37R are operated in a predetermined pressing order for each winning combination, the reel control unit 130 sets the medal. The symbol combination corresponding to the condition device whose number of payouts is 9 is preferentially controlled. Similarly, when any of the winnings B1 to B6 and the winnings C1 to C6 is won, if the stop switches 37L, 37C, and 37R are operated in a predetermined pressing order for each winning combination. The reel control means 130 preferentially controls the symbol combination corresponding to the condition device in which the number of medals to be paid out is nine.

  Further, when the winning-E1 or the winning-E2 is determined as the winning combination, the stop switch is pushed forward (left → middle → right) or scissors (left → right → middle) (that is, the left stop switch 37L). If the first stop operation is performed), the symbol combination corresponding to any of the condition devices having the prizes 09 to 12 is preferentially controlled to be drawn in. As a result, the symbol combinations corresponding to any of the condition devices of the prizes 09 to 12 are always aligned on the prize line L. On the other hand, when a stop switch other than the left stop switch 37L is operated for the first stop, the pull-in control is preferentially performed for the symbol combination corresponding to the condition device of the winning 13 or the winning 17. At this time, if the player has failed to align the symbol combination corresponding to the winning device 13 or the winning device 17 on the winning line L (i.e., has missed), the reel control means 130 returns to any of the condition devices. Unmatched special symbol combinations are arranged on the winning line L.

  Similarly, when the player performs the first stop operation of the middle stop switch 37C when the winning combination -E3 or E4 is determined as the winning combination, any of the symbol combinations of the winning combinations 13 to 16 is always displayed on the winning line L. I get it. On the other hand, when the player performs the first stop operation of the stop switches other than the middle stop switch 37C, the symbol combination of winning 09 (when winning-E3 winning) or winning 10 (when winning-winning E4 winning) is missed. In this case, a special symbol combination that does not correspond to any condition device is arranged on the pay line L.

  Further, when the player performs the first stop operation of the right stop switch 37R when the winning combination -E5 or E6 is determined as the winning combination, any one of the winning combinations 17 to 20 is always aligned with the winning line L. . On the other hand, when the player performs the first stop operation of a stop switch other than the right stop switch 37R, the winning 11 or the winning 15 (when winning-E5 is won) or the winning 12 or winning 16 (when winning-E6 is won). If any of the symbol combinations is missed, special symbol combinations that do not correspond to any of the condition devices are arranged on the pay line L.

  When the winning combination -F is determined as the winning combination, the pull-in control is preferentially performed with respect to the symbol combination corresponding to the winning combination 22 regardless of the pressing order. At this time, if the player has missed the symbol combination corresponding to the winning prize 22, there is a possibility that the symbol combination corresponding to the other activated condition devices (winning 07, 08, 21) may not be aligned on the winning line L. Yes, in this case, the winning -F may be missed. Similarly, when the winning combination -G is determined as the winning combination, the pull-in control is preferentially performed for the symbol combination corresponding to the winning 21 regardless of the order of the pressing. At this time, if the player has missed the symbol combination corresponding to the winning prize 21, the symbol combination corresponding to the activated other condition devices (winning 07, 08, 22, 23) may not be aligned on the winning line L. In this case, the winning-G may be missed.

  When the winning combination -I is determined as the winning combination, the pull-in control is preferentially performed for the symbol combination corresponding to the winning 24 regardless of the pressing order. Then, when the player has missed the symbol combination corresponding to the winning prize 24, the reel control means 130 controls the reel stop control to align the symbol combination corresponding to another operating condition device (for example, winning 01) with the winning line L. To win the winning-I.

(Description of state control means)
Returning to FIG. 8, the state control means 140 has an RT state control means 142 and a game state control means 144. The RT state control means 142 controls the transition of the above-described RT states (RT0 to RT5). When the initial state is RT0, and when a predetermined condition is satisfied in each RT state, the RT state is shifted to another RT state. In the present embodiment, when the above-mentioned special symbol combination (a special symbol combination which may be displayed as being missed when winning -E1 to E6 is won) is displayed at RT0, the RT state is changed. Move to RT1. If the symbol combination corresponding to the replay 05 is completed at RT1, the process proceeds to RT2, and if the symbol combination corresponding to the replay 06 is completed at RT2, the process proceeds to RT3. Further, in RT2 and RT3, when the symbol combination corresponding to the re-game 03 or the re-game 04 or the special symbol combination described above is completed, the current RT state is shifted to RT1.

  Here, the transition from RT0 to RT1, the transition from RT1 to RT2, and the transition from RT2 to RT3 are referred to as “promotion”, and the transition from RT2 or RT3 to RT1 is also referred to as “fall”. Further, the fact that the RT state does not shift is also referred to as “maintenance”.

  During non-internal, that is, in any of the RT states of RT0 to RT3, the winning combination determination means 110 determines BB01 as a winning combination, and when the symbol combination corresponding to BB01 is not completed, the RT state is shifted to RT4. Let it. When the symbol combinations corresponding to BB01 are completed in RT0 to RT4, the RT state is shifted to RT5. Then, when the end condition of the BB game is satisfied in RT5, the RT state control means 142 shifts the RT state to RT0. Here, the end condition of the BB game is satisfied when the number of medals paid out during the BB game exceeds 456, as described above.

  In the present embodiment, in any of RT0 to RT3, when the symbol combination corresponding to BB01 is not completed in the game in which BB01 has been determined as the winning combination, the process is shifted to RT4. When a special combination (for example, BB01) is determined as a winning combination, the process may shift to RT4. In addition, when a symbol combination of replay 03 or 04 is displayed in RT2 or RT3, control is performed so as to shift (fall) to RT1, but a symbol combination of either one (for example, replay 03) is changed. When it is displayed, the process proceeds to RT1, and when the symbol combination of the other (for example, replay 04) is displayed, the current RT state may be maintained. Thereby, in RT2, for example, when re-game-C1 is won, when shifting to RT1 according to the pressing order (when the symbol combination of re-game 03 is displayed), and when RT2 is maintained (for re-game 04) A case where a symbol combination is displayed) and a case where the process shifts to RT3 (when a symbol combination of the replay 06 is displayed) may occur.

  The game state control means 144 controls the transition of the game state based on the result of the winning lottery and the advantageous section lottery described later. In the gaming state according to the present embodiment, a notification game (also referred to as an “AT game”) in which, when a re-game combination or a winning combination is won, a pressing order in which a game result advantageous to the player is obtained is notified. There is an advantageous section (also referred to as “during an AT game possible state”) and a normal section during which a notification game is not performed (also referred to as “during an AT game impossible state”). As the “advantageous game result”, for example, a small winning combination having a larger number of medals to be paid out receives a prize, or a re-winning winning combination whose RT state is maintained or promoted wins.

  Then, in the game of the normal section, when a predetermined winning combination is determined by the winning lottery, an advantageous section lottery for determining whether or not to start the advantageous section is performed. Processing for starting is performed. Here, the above-mentioned predetermined winning combinations correspond to, for example, three types of winning-F, G, and H. Note that these three types of winning combinations are the winning combinations in which the same number is set in all of the set value data 0 to 5, and when the winning combination is determined by the lottery, a predetermined probability (100) % Is included).

  However, inside the bonus, the probability of winning the replay combination is in the state of RT4, which is set higher than RT0, RT1, and RT2. Therefore, the above-described advantageous section lottery based on the predetermined winning combination is not performed. This is because, during the inside of the bonus (RT4), it is possible to play the game while consuming less medals than in the RT0, RT1, and RT2. Avoiding the advantageous situation caused by the player's intentional game operation of intentionally delaying the state of RT4 by not aligning the bonus and waiting for the above-mentioned predetermined winning combination to be won (preventing a so-called strategy) That's why.

(Description of notification game control means)
When the notification game control means 150 shifts to the above-mentioned advantageous section (during the advantageous section), it becomes possible to determine the pressing order to be notified according to the winning combination and to notify. The notification of the pressing order is performed by displaying a numerical value called an instruction number on the acquired number display 28 shown in FIG. Specifically, the instruction number 1 corresponds to the pressing order of left → middle → right (forward pressing) (push order 1), and the instruction number 2 corresponds to the pressing order of left → right → middle (shear pressing) (push order 2). ), The instruction number 3 corresponds to the middle-to-left-to-right (forward middle-pressing) pressing order (push-to-order 3), and the instruction number 4 corresponds to the middle-to-right-left (reverse middle pressing) pressing order (push-to-order 4). ), Instruction number 5 corresponds to the right-to-left-> middle (reverse scissors pressed) pressing order (push order 5), and instruction number 6 corresponds to the right->middle-> left (reverse pressing) pressing order (push order). 6). When the notification order is not notified by the notification game control means 150, an instruction number 0 that does not represent a specific pressing order is defined.

  When the instruction number is displayed on the acquired number display 28, “=” is displayed on the 7-segment display of the tens place (hereinafter also referred to as “upper digit”) of the acquired number display 28, The instruction number is displayed on a 7-segment display of "lower digit". In the present embodiment, the acquired number display 28 is used for both displaying the number of medals to be paid out and displaying the instruction number. By displaying “=” that is not displayed, the type of displayed information can be determined by the player. For the instruction number 0, all seven-segment displays of the acquired number display 28 are turned off.

  In the present embodiment, the display of the acquired number display 28 is turned off (that is, all segments are turned off) in response to the insertion of medals (including the case where the bet switches 34 and 35 are operated), and the start switch 36 is turned off. When the instruction number is determined according to the operation, the instruction number is displayed. When all the reels are stopped and the winning combination is won, the display of the instruction number is turned off once, and then the number of payouts is displayed.

  On the other hand, in the sub-control means 200 described later, it is possible to report the pressing order based on the current gaming state transmitted from the main control means 100, information based on the winning combination (production group number), and the like. Becomes In the present embodiment, the notification of the pressing order by the sub-control means 200 (pressing order navigation effect) is performed using the image display device 70. As an example of the pressing order navigation effect, display positions corresponding to the left stop switch 37L, the middle stop switch 37C, and the right stop switch 37R are determined on the screen of the image display device 70, and the corresponding display positions are set. Displays a number indicating the order in which the stop switch should be operated. For example, when displaying the pressing order corresponding to the instruction number 1, "1.2.3" is displayed on the image display device 70. This display means that the left stop switch 37L is displayed first, the middle stop switch 37C is displayed second, and the right stop switch 37R is displayed last.

  When the instruction number and the payout number are displayed using the acquired number display 28, “00” is displayed according to the insertion of medals (including the case of operating the bet switches 34 and 35), and the start switch 36 is operated. When the instruction number is determined in accordance with, the instruction number is displayed, and when all the reels stop and the winning combination wins, the display is returned to "00" once, and the payout number is displayed. You may. In this case, it is preferable to display “00” on the acquired number display 28 when a medal is inserted again. On the other hand, when the winning combination does not win, the display of the acquired number display 28 is returned to "00" when all reels have stopped, and the display number is kept until the instruction number is determined in the next game. The state may be maintained.

  In the above two examples, before the payout number is displayed, the display of the instruction number is temporarily turned off or "00" is displayed. However, the display of the instruction number is directly changed to the display of the payout number. Is also good. Although “00” is displayed on the acquired number display 28 at the time of inserting a medal or the like, “no light” may be used instead of “00”.

  Further, in the above-described example, when a winning combination that does not cause a change in the profit given to the player according to the pressing order is determined, the pressing order to be notified may be determined by the sub-control unit 200. The “profit” described above includes, for example, whether or not to perform the advantageous section lottery, promotion or maintenance of the RT state, the number of paid out medals, and the like. However, even for a winning combination in which the profit given to the player does not change according to the pressing order, the main control means 100 may determine the pressing order. It may be displayed.

  Further, when a predetermined condition is satisfied during an advantageous section (for example, when a predetermined combination is won in a combination lottery), a shortened lottery (falling lottery) for determining whether or not to shorten (end) the current advantageous section. , And when a shortened lottery (falling lottery) is won, the advantageous section may be ended or the end of the advantageous section may be advanced.

(Explanation of winning determination means)
Returning to FIG. 8, when all of the reels 40L, 40C, and 40R stop, the winning determination means 160 determines that the symbol combination stopped and displayed on the winning line L corresponds to any of the symbol combinations shown in FIGS. It is determined whether or not to perform. Thereby, when it is determined that the BB combination has won, the BB game is started from the next game, and when it is determined that the re-game combination has won, the re-game is performed in the next game, and the winning combination is performed. Is won, medals of the number corresponding to the winning combination that has won are paid out. Here, in the payout of medals, the number of medals corresponding to the winning prize is added to the current number of credits until the upper limit of the number of credits (for example, 50) is reached, and the upper limit of the number of credits (for example, 50) After reaching ()), the medals may be discharged from the medal payout exit 60 shown in FIG.

(Description of abnormality detection means)
The abnormality detecting means 170 detects an abnormal state that may occur in the slot machine 10 during the game or a situation that becomes an obstacle to the progress of the game, and detects the detected abnormality or failure (hereinafter, also collectively referred to as “error”). The corresponding error code is displayed on the acquired number display 28, and is also transmitted to the sub-control means 200, which will be described later, depending on the type of the error code. As a result, the sub-control unit 200 displays an error message corresponding to the received error code on the image display device 70, and generates an error sound from the speakers 64L and 64R.

  The types of errors detected by the abnormality detecting means 170 are roughly classified into non-recoverable errors and recoverable errors. Non-recoverable errors include power failure recovery errors, stop symbol combination errors, set value errors, and random number errors. Recoverable errors include medal clogging errors, empty errors, payout errors, insertion sensor passing errors, and medal insertion. There are errors, medal retention errors, insertion sensor errors, medal passing errors, medal full errors, and the like.

  The power failure recovery error (error code: E1) indicates that when the power of the slot machine 10 is turned on, the content of the RWM is not normal (for example, the content of the RWM when the power is turned off and the content of the RWM when the power is turned on). This error is detected when they do not match (parity check error). Further, for example, by determining whether or not the value of the stack pointer stored in a predetermined storage area of the RWM (stack pointer temporary storage area) when the power is turned off is a value in the stack area, it is possible to determine whether a power failure recovery error has occurred. It may be determined whether or not. In this case, if the value of the stack pointer is not in the stack area, it means that an abnormality has occurred in the RWM between the time when the power is turned off and the time when the power is restored. When determining whether or not the contents of the RWM at power-off and the contents of the RWM at power-on match, the determination is made based on the checksum of the entire storage area of the RWM (F000 to F3FF in the present embodiment). Although it is possible, as described above, the data stored in the stack pointer temporary storage area is included in the numerical range (F1D9 to F200 in this embodiment) that the stack pointer can take when there is no abnormality. Whether or not an abnormality has occurred in the RWM can be more accurately determined based on whether or not the abnormality has occurred. In other words, the power failure recovery error can be determined based on the result based on the checksum and / or the result based on the value of the stack pointer temporary storage area.

  Here, the “stack area” is a data area having a characteristic that data input first is taken out last (FILO). Pointer (also referred to as an SP register) ". That is, the “stack pointer” points to the last referenced (accumulated) position in the stack area. For example, the data stored in the stack area when the stack pointer is F200 is the RWM address F1FF.

  More specifically, when an instruction (e.g., a PUSH instruction) for saving the data stored in the register is executed, the data stored in the register is stored in the stack area, and the stack pointer is also updated (here, In order to stack data from the upper address to the lower address, the data amount (byte number) saved from the stack pointer is subtracted). For example, when 1-byte data is stacked, 1 is subtracted from the stack pointer. When executing an instruction (CALL instruction) for executing a program (module) for timer interrupt processing, the return address is stored in the stack area and the stack pointer is updated (subtracted).

  On the other hand, when an instruction (POP instruction) for storing (restoring) data stored (saved) in the stack area in the register is executed, the data is stored in the register and the stack pointer is updated (added). Data is taken out of the stack area, set in a register, and the data amount (the number of bytes) is added to the stap pointer SP. For example, when 1-byte data is extracted, 1 is added to the stack pointer SP. When a program (module) called by the CALL instruction is terminated and a return instruction (RET instruction) for returning to the original program (return address) is executed, the program is restarted from the return address and the stack pointer is updated ( to add. In the present embodiment, the range of the RWM addresses F1D8 to F1FF is the stack area because the maximum amount of data saved in the stack area along with the execution of the program is 40 bytes. Note that RWM addresses F146 and F147 are allocated as the above-mentioned stack pointer temporary storage area.

  A stopped symbol combination error (error code: E5) is detected when an unintended symbol combination (for example, a symbol combination corresponding to a condition device that is not operated) is displayed when all reels are stopped. Error. The set value error (error code: E6) is an error detected when the set value data (address: F000) stored in the RWM has a value outside the predetermined range (other than 0 to 5). For example, in the case of a set value error, a process of determining whether or not the set value data is out of a predetermined range is performed based on the operation of the start switch 36 after a predetermined number of medals have been bet, and the determination is made that the set value data is out of the predetermined range. Error processing (processing for stopping the progress of the game) is executed based on the result. It is preferable that the process of determining whether or not the set value data is outside the predetermined range is performed after the start switch 36 is operated and before the combination lottery process and the advantageous section lottery process are performed.

  The random number error (error code: E7) indicates that the frequency value of the random number generation clock (RCK) supplied to the random number generation unit in the main control unit 100 is half the frequency of the system clock (SCLK) supplied to the CPU. An error that is detected if the value is less than.

  The medal clogging error (error code: HP) is an error detected when the first payout sensor 47a and the second payout sensor 47b detect a medal for more than a predetermined time (for example, 224 milliseconds). The empty error (error code: HE) is an error detected when the first payout sensor 47a does not detect a medal even after a predetermined time has elapsed since the hopper motor 46 was driven. The payout error (error code: H0) indicates that the second payout sensor 47b detects a medal for more than a predetermined time while the first payout sensor 47a does not detect a medal when the hopper motor 46 is driven. This is an error detected when the first payout sensor 47a detects a medal for a predetermined time (for example, 6.72 milliseconds) when the hopper motor 46 is not driven and when the hopper motor 46 is not driven.

  In the present embodiment, two sensors, the first payout sensor 47a and the second payout sensor 47b, are provided as payout sensors. (HP) and payout (H0) error). Specifically, during execution of the payout process (while the hopper motor 46 is being driven), an empty error is detected when the payout sensor is continuously turned off for 2249 milliseconds (1000 interrupts) or more. When the payout sensor is continuously turned on for 224 milliseconds (100 interruptions) during execution of the payout process (during the driving of the hopper motor 46), a medal jam error (HP) is detected. Further, a payout error (H0) is detected when the payout sensor is continuously turned on for more than 6.72 milliseconds (3 interrupts) except during execution of the payout processing (when the hopper motor 46 is not driven). I do.

  Here, conventionally, when a signal indicating that the payout of medals has been completed does not return even after a predetermined time has elapsed since the main control unit instructed the medal payout device to pay out a predetermined number of medals. There is a slot machine that detects an error related to payout of medals (for example, see Japanese Patent Application Laid-Open No. 2008-246059). However, in this case, an error is not detected unless a predetermined time (at least, a time required for normal payout of a predetermined number of medals) has elapsed. Therefore, even if medals are jammed during payout, the error can be promptly detected. Was difficult to detect. Further, when the main control means does not instruct the medal payout device to pay out, if the medal payout device pays out the medals by fraud, it cannot be detected as an error.

  Therefore, in the present embodiment, as described above, a medal jam error is detected when the first payout sensor 47a and the second payout sensor 47b detect a medal for more than a predetermined time (for example, 224 milliseconds) during the payout process. By doing so, the medal clogging can be detected as soon as possible. When the hopper motor 46 is not driven by detecting a payout error when the first payout sensor 47a detects a medal for a predetermined time (for example, 6.72 milliseconds) when the payout processing is not being performed. It is designed to detect fraudulent activities.

  When the medal clogging error (HP) and the payout error (H0) are compared, it is common that the error is detected by detecting that the payout sensor is ON, but the medal clogging error is The difference is that while the payout process is being executed, the payout error is not being executed. Since the payout error is an abnormality in which the paid-out medals are detected when the hopper motor 46 is not driven, it is more likely that the payout error is a fraud than a medal clogging error. Therefore, the time (6.672 ms) that is a condition for detecting a payout error is set shorter than the time (224 ms) that is a condition for detecting a medal clogging error, so that fraudulent acts can be quickly detected. Also, if the time for detecting a medal clogging error and the time for detecting a payout error are set to the same time, medals will be jammed for a very short time during normal payout. In this case, even if there is no problem in paying out, there is a possibility that an error may be determined, which is not preferable.

  Further, since it is possible that the detection of the payout sensor may be determined due to noise such as static electricity or the like, an error may be determined. (Two times or more of 2.235 milliseconds). This makes it possible to determine a payout error when at least the input from the payout sensor is acquired a plurality of times, and to prevent an error from being determined after installation at a game store even though the error is not originally abnormal. In addition, frustration for the clerk and the player of the game store can be reduced. Here, the time serving as the payout error detection condition is set to 6.672 milliseconds, and a payout error is determined when the payout sensor continuously detects a medal in three timer interrupt processes. .

  The insertion sensor passage error (error code: CE) is detected when the ON state and the OFF state of the first insertion sensor 48a and the second insertion sensor 48b, which change with the passing of the medal, exceed a predetermined time. Error. A medal insertion error (error code: CP) indicates that a transition of the on / off state of the first insertion sensor 48a and the second insertion sensor 48b that changes with the passing of a medal is a predetermined pattern (when the medal passes normally). (On / off pattern). The medal retention error (error code: CH) is an error detected when the inserted medal is continuously detected by the medal passage sensor 49 for more than a predetermined time.

  A predetermined time (224 milliseconds (100 interrupts in this embodiment)) has elapsed since the blocker was turned off (the medal channel in the selector 80 was not formed) after the insertion sensor error (error code: C0). This error is detected later when a medal is detected by the second insertion sensor 48b. During this predetermined time (224 milliseconds), it is determined that an error has occurred because a medal passed immediately before the blocker was turned off and the medal was detected by the second insertion sensor 48b when the blocker was turned off. This is a grace period to prevent this. Furthermore, even if the blocker is off, there is a risk that the first insertion sensor 48a may detect a medal depending on the speed at which the medal passes, so that the insertion sensor error (error code: C0) indicates the second insertion. The detection is performed based on the output signal (the closing sensor 2 signal) from the sensor 48b. If the first insertion sensor 48a does not detect a medal when the blocker is off due to the mechanism of the selector, the insertion is performed based on the output signal (insertion sensor 1 signal) from the first insertion sensor 48a. A sensor error (error code: C0) may be determined.

  A medal passing error (error code: C1) occurs when the difference between the number of times the medal is detected by the medal passage sensor 49 and the number of times the medal is detected by the second insertion sensor 48b exceeds a predetermined value (for example, “3”). Error detected. In the medal full error (error code: FE), the state in which the rod-shaped electrode 85a and the rod-shaped electrode 85b shown in FIG. 2 are electrically connected is from the start of the previous game to the start of the current game. Is an error detected if it exceeds 112 milliseconds (50 interrupts). Note that the timing for detecting the medal full error may be an appropriately determined timing such as a predetermined timing during a game (for example, during reel rotation). Also, the medal full error is not a serious error that is likely to be caused by fraudulent acts or breakdowns, so even if the notification is detected at a predetermined timing during the game, other errors (for example, insertion sensor error or Unlike a medal jam error of a hopper, etc., the game is not notified by a liquid crystal or the like during the game, but is notified after the game is completed (after all reels are stopped).

  As described above, when an error is detected, an error code corresponding to the detected error is displayed on the acquired number display 28. When a recoverable error is detected, an error code corresponding to the error is transmitted to the sub-control unit 200 by the control command transmitting unit 180 described later. Further, when a recoverable error is detected during the rotation of the reels, the slot machine 10 is brought into a game-disabled state when all the reels are stopped according to the operation of the stop switches 37L, 37C, 37R. On the other hand, if a random number error (unrecoverable error) is detected during the rotation of the reels, the game is disabled even during the rotation of the reels. Here, as a method of making the game impossible state, it is conceivable that the spinning reel is stopped, and control by operation of a stop switch, a bet button, and / or a settlement button is not executed.

  The error detected by the abnormality detection means 170 is not limited to the above-described one. For example, when the front door 14 is opened and the state continues for a predetermined time, a door opening error occurs (in other words, the door opening error occurs). (An error has been detected).

(Description of control command transmission means)
The control command transmitting means (information transmitting means) 180 transmits various information related to the game determined by each unit of the main control means 100 to the sub-control means 200. Information exchanged between the main control means 100 and the sub-control means 200 is limited to one direction from the main control means 100 to the sub-control means 200. No information is sent directly. Information transmitted from the main control means 100 to the sub-control means 200 is transmitted by a control command through serial communication. The control command includes a first control command (1 byte) indicating the type of information to be transmitted and a second control command (1 byte) indicating the content of the information to be transmitted. The control command may be transmitted not only by serial communication but also by parallel communication (for example, 16 harnesses).

  Here, FIG. 12 shows a part of a control command transmitted from the main control unit 100 to the sub control unit 200. As shown in this figure, the first and second control commands are represented by a two-digit hexadecimal number (hexadecimal number). The outline of the processing performed by the sub-control means 200 when it is received is shown. The remarks column mainly shows the content of information transmitted as the second control command. In addition, what is described as “##” as the value of the second control command is substituted with a numerical value determined according to the content described in the remarks column. However, if the numerical value determined according to the content of the remarks column is one digit, the value of the upper digit is “0”. In addition, in the hexadecimal four-digit numerical value representing each control command, the letter “H” added to the end is omitted.

  In FIG. 12, a “setting change device operation start” command (8038) is a control command transmitted when the mode shifts to a setting change mode (corresponding to a setting change state in which setting values can be changed). Specifically, when the power switch 82a of the slot machine 10 is turned on while the front switch 14 of the slot machine 10 is open and the key switch 82b is turned on, a setting change device process described later (FIG. 18) Reference) is started. By executing the setting change device processing, the mode shifts to the setting change mode, and a “setting change device operation start” command is transmitted to the sub control means 200. Upon receiving this control command, the sub-control unit 200 starts the initialization process of the sub-control unit 200, and then notifies that the setting change operation is being performed by the image display device 70 shown in FIG. Notify. Further, based on the fact that the sub-control means 200 has received the “setting change device operation start” command, the effect setting mode described later may be made executable.

  Note that the method of shifting to the setting change mode is not limited to the above-described method. It may be. In this case, the key switch 82b corresponds to the first switching unit, and the setting / reset switch 82c corresponds to the second switching unit.

  The “setting change device operation end” command (8000 to 8005) is a value of a set value set by a staff at a game hall or the like in the above-described setting change mode (also referred to as “set value data” in the present embodiment). Is transmitted to the sub-control means 200. The numerical value of the second control command is a value corresponding to the set value. Specifically, the values of the second control command correspond to 0 to 5 for the set values “1” to “6” displayed on the set value display 87. In the setting change mode, when the start switch 36 is operated after the staff at the game hall or the like operates the setting / reset switch 82c in the setting change mode and then operates the start switch 36, the selected setting value is determined. When the key switch 82b is turned off from on, the setting change mode ends, and the setting change mode is transmitted to the sub control unit 200. Upon receiving this command, the sub-control means 200 starts game standby display (so-called demonstration screen display) and ends the above-described effect setting mode. Note that the setting change mode is terminated by confirming the set value selected by operating the start switch 36 and turning off the key switch 82b. However, after operating the start switch 36, the key switch 82b is turned off. Thus, both the setting of the set value and the end of the setting change mode may be performed.

  Therefore, for example, when the effect setting mode is being executed by the sub-control means 200, the effect setting mode is ended based on the reception of the "setting change device operation end" command. In addition, as the content of the notification that the game is in a standby state (a state in which the game is enabled), not only a so-called “demo screen” is displayed on the image display device, but the player can play the game. An image (including a so-called movie) indicating the presence may be displayed on the image display device. Furthermore, even after receiving the setting change device operation end command, the notification indicating that the setting change has ended may be continued by a lamp or sound for a predetermined period of time. This means that a change in the set value cannot occur during normal business hours, and the terminal does not have a terminal for transmitting a signal indicating that the set value has been changed as an external signal (transmitted as an external signal). This is because it is desirable that the clerk of the game store designs a gaming machine that is as noticeable as possible for such serious acts. It should be noted that the predetermined period in which the notification is continued may be configured so that the staff of the game arcade can select from a plurality of periods, for example, in the effect setting mode.

  When any abnormality is detected by the abnormality detecting unit 170 shown in FIG. 8, the control command transmitting unit 180 determines that the value of the first control command is 81H and the value of the second control command is A corresponding error display start command is transmitted. That is, when an empty error is detected, an “empty error display start” command (8101) is issued. When a medal jam error is detected, a “medal jam error display start” command (8102) is issued, and a payout error is detected. In this case, a “payout error display start” command (8103) is transmitted to the sub control unit 200, and when a medal full error is detected, a “medal full error display start” command (8104) is transmitted.

  If a medal insertion error is detected, a “medal insertion error display start” command (8105) is issued. If an insertion sensor error is detected, a “insertion sensor error display start” command (8106) is issued. If detected, a “medal passing error display start” command (8107) is used. If a medal staying error is detected, a “medal staying error display start” command (8108) is used. A “start sensor passing error display start” command (8109) is transmitted to the sub-control means 200, respectively.

  Upon receiving the various commands described above, the sub-control unit 200 notifies an error according to the content of the second control command. After the error is detected, when the cause of the error is removed and the setting / reset switch 82c is operated or the keypad inserted into the door key 31 is turned counterclockwise, the control command transmitting means 180 Transmits an “error recovery” command (8100) to the sub control means 200. Thus, the sub-control unit 200 ends the error notification being executed.

  The “set value specification” command (8200 to 8205) and the “operation state” command (8301 / 830C) are control commands transmitted each time a game is played. The second control command of the “set value designation” command is a value corresponding to the set value, like the second control command of the “setting change device operation end” command described above. 00H to 05H correspond to "1" to "6" displayed on the display 87. The second control command of the “operation state” command is information indicating that the game to be performed is a re-game, an RB game, or a BB game. Here, BIT0 (least significant bit) of the second control command corresponds to the replay, BIT2 corresponds to the BB game, and BIT3 corresponds to the RB game. Accordingly, when the game to be started is a re-game, BIT0 is “1”, and when the game is a BB game, BIT2 and BIT3 are “1”.

  The “set value display start” command (8F5A) is a control command transmitted when shifting to the setting check mode (corresponding to a set value check state in which the current set value can be displayed). More specifically, when the slot machine 10 is in a state where it can accept insertion of medals and no medals have been inserted, a game medal insertion standby display process described later (see FIG. 20). ) Is executed, and when the key switch 82b is switched from off to on at that time, the mode shifts to the setting confirmation mode. Upon receiving the “set value display start” command, the sub-control means 200 displays a message (setting confirmation screen) indicating that the current setting value is being checked on the image display device 70. Further, based on the fact that the sub-control means 200 has received the “set value display start” command, the effect setting mode described later may be made executable. The method of shifting to the setting confirmation mode is not limited to the above-described method. For example, the key switch 82b may be turned on when a medal is not bet, and the setting / reset switch 82c may be operated. .

  The “set value display end” command (8F00) is a control command transmitted to the sub-control unit 200 when the key switch 82b is switched from on to off in the above-described setting confirmation mode. Thus, when the effect setting mode is being executed, the sub-control means 200 ends the effect setting mode based on the reception of the “set value display end” command.

  The “clearing start” command (8F02) is transmitted when the clearing switch 33 is operated. Thereby, the sub-control means 200 generates a medal payout sound in accordance with the received control command. The "clearing end" command (8F03) is transmitted when all credited medals and / or betted medals have been paid out. Thereby, the sub-control means 200 terminates the payout sound in accordance with the received control command, or displays an effect indicating a standby state of the game (a state in which the game is enabled).

  As described above, each of the above-mentioned commands is only a part, and in addition to these commands, commands relating to a role lottery or an advantageous section lottery, commands relating to an RT state or a game state, commands relating to reel rotation / stop, a start switch 3 and commands relating to the operation of the stop switches 37L, 37C and 37R, commands relating to the game results, and the like are transmitted to the sub-control means 200.

(Description of external signal transmission means)
Returning to FIG. 8, the external signal transmitting means 190 performs the timer interrupt processing (described later) executed at a predetermined cycle (every 2.235 milliseconds) in the main control means 100 via the external centralized terminal board 86 through the external central terminal board 86. The medal insertion signal, the medal payout signal, the BB signal, the advantageous section signal, and the like are output to the outside. In the present embodiment, when the BB combination is won, the BB signal is turned on, and when the BB game ends, the BB signal is turned off (level output). Also, when the advantageous section starts, the advantageous section signal turns on, and when the advantageous section ends, it turns off (level output).

<Description of Information Stored in RWM of Main Control Means 100>

  Next, the contents of various data stored in the RWM of the main control means 100 will be described with reference to FIGS. The RWM used in the present embodiment can store one byte of data at each address, and the values of the addresses shown in FIGS. 13 to 15 are all expressed in hexadecimal notation. When the address is represented by a four-digit number in the modulus, the letter “H” added to the end is omitted. The types of data shown in FIGS. 13 to 15 are only a part of the data stored in the RWM, and in addition to these data, data necessary for controlling the game are stored in the RWM. Needless to say.

  In FIG. 13, a value (set value data) corresponding to the set value displayed on the set value display 87 is stored in the RWM address F000. That is, 0 is displayed when the set value displayed on the set value display 87 is “1”, 1 is displayed when the set value displayed on the set value display 87 is “2”, and displayed on the set value display 87. When the set value displayed on the set value display 87 is “3”, 2 when the set value displayed on the set value display 87 is “4”, and 3 when the set value displayed on the set value display 87 is “5”. 4. If the set value displayed on the set value display 87 is "6", 5 is stored.

  In a conventional slot machine, when a set value can be in a range of “1” to “6”, the set value data is managed with “1” to “6” corresponding to the set value. However, when the minimum value of the set value data is “1”, it may be difficult to perform efficient control processing. Therefore, when the set value can take a range of “1” to “6”, the minimum value of the set value data is set to “0”, and the numerical value range is set to “0” to “5”. Effect.

  First, error checking of set values is facilitated, and error checking can be performed with a small program capacity. For example, as a calculation process of the set value error check, when 6 (maximum value of the set value data + 1) is subtracted from the set value data, and it is determined that the calculation result has no borrow (the carry flag is off), An error (out of the set value range) can be determined. That is, when the set value data is 0 to 5, an error is not determined because a digit occurs, but when any other value (for example, 6 or 100) is stored, an error is determined because the digit does not occur. can do. As described above, by checking the value of the carry flag, it can be determined whether or not the set value data stored in the RWM is within a normal numerical range.

  On the other hand, if the set value data is stored as “1” to “6”, it cannot be determined that an error has occurred in the same processing as the above-described subtraction. That is, when 7 (maximum value of the set value data + 1) is subtracted from the set value data, for example, even if the set value data is “0”, a digit borrow occurs, so that it is determined to be normal. For this reason, when "0" is stored in the set value data, another process for determining an error is required, and the program capacity is reduced.

  Secondly, as an effect of storing the set value data as “0” to “5”, a winning combination having different winning probabilities in the winning lottery depending on the setting value (hereinafter also referred to as “winning combination having a setting difference”). ) Can be easily performed. For example, assuming that the winning combination having a setting difference is winning-D, the numerical value when the setting value data is “0” (hereinafter also referred to as “judgment value”) is 3904 (winning probability: about 1/16. 79), when the set value data is “1”, 3914 (winning probability: about 1 / 16.74), when the set value data is “2”, 3924 (winning probability: about 1 / 16.70), the set value data Is 3934 (winning probability: about 1 / 16.66), when the setting data is "4", 3944 (winning probability: about 1 / 16.62), and when the setting value data is "5", 3954 (Winning probability: about 1 / 16.57).

At this time, the numeral data referred to when determining whether or not the winning-D is won may be stored in the addresses XXX0 to XXXA of the ROM as follows.
Address XXX0 DEFW 3904; (Setting value data 0)
Address XXX2 DEFW 3914; (Setting value data 1)
Address XXX4 DEFW 3924; (Setting value data 2)
Address XXX6 DEFW 3934; (Setting value data 3)
Address XXX8 DEFW 3944; (Setting value data 4)
Address XXXA DEFW 3954; (Setting value data 5)
Here, the above-mentioned “address XXX0” and the like are for simplifying the description and are different from the actual addresses. DEFW means 2-byte data, and the following value means numeric data. Although the above-mentioned numerical data is indicated by a decimal value, it is assumed that the data is stored in the ROM by a hexadecimal value. Furthermore, "; (set value 0)" and the like describe the set value data corresponding to the numeric data, and are not data that is actually stored in the ROM.

  If the data that can be stored in one address of the ROM is one byte, the data is stored in two ROM addresses separately into the upper byte and the lower byte of the numeral data. For example, when the numeric data “3904” (= 0F40H) when the set value data is “0” is stored in the ROM, the lower byte value 40H is stored in the address XXX0, and the upper byte value 0FH is stored in the address XXX1. Remember. Further, when the numeral data “3954” (= 0F72H) when the set value data is “5” is stored in the ROM, the lower byte value 72H is stored in the address XXXA and the upper byte value 0FH is stored in the address XXXB. Remember.

  As described above, each set number is stored in each address so that the set values are in ascending order. For example, when the set value data is “0”, the 2-byte data (0F40H) stored in the address XXX0 and the address XXX1 is acquired in a register (for example, a pair register of a DE register), and the calculated value is compared with a random value. It is determined whether or not Win-D has been won. On the other hand, when the set value data is “5”, the 2-byte data (0F72H) stored in the address XXXA and the address XXXB is obtained in the register, and is compared with a random value to determine whether or not the winning-D is won. judge. That is, the numeral data is obtained from different addresses according to the set value data.

  At this time, when the 2-byte data is stored as the numeric data, the address is set to XXX0 as the reference, and the address is specified as the offset value by doubling the set value data as the offset value, thereby corresponding to the set value data. Can be obtained. For example, when the set value data is "3", 6 is added to the address XXX0 to obtain the numeral data 0F5EH ("3934") from the addresses XXX6 and XXX7. When the number data is represented by 1-byte data, an address is designated by using the set value data itself as an offset value without doubling the set value data, and a corresponding number (for example, an A register) is obtained. be able to.

  On the other hand, if the set value data is stored as “1” to “6”, and if the above-mentioned numerical value is stored, the set value data cannot be directly adopted as the offset value. . In this case, the offset value must be calculated as (set value data-1) × 2. Therefore, the lottery process is more complicated than when the set value data is changed from “0” to “5”.

  As described above, the set value displayed on the set value display 87 and the set value data stored in the address F000 of the RWM are different from each other by one, so that an advantageous effect can be obtained. Instead, the set value displayed on the set value display 87 and the set value data stored at the address F000 may be the same value. For example, when the set value displayed on the set value display 87 is “3”, the set value data stored in the RWM address F000 may be set to 3. Furthermore, in this embodiment, since the range of the set value exists from “1” to “6”, six types of data from “0” to “5” can be stored in the RWM as the set value data. , The setting value display 87 can display six types of “1” to “6”. For example, the setting value range is set to “1” to “4”, and the setting value data is changed from “0” to “4”. Four types of data up to “3” may be stored, and four types of display “1” to “4” may be displayed on the set value display 87.

  Address F00A stores input port 0 level data. Specifically, the D0 bit stores a setting / reset switch signal, the D1 bit stores a setting key switch signal, the D2 bit stores a door switch signal, the D5 bit stores a power-off detection signal, and the D6 bit stores a full detection signal. Is done. These signals are the same as the signals input to the input port 0 shown in FIG. The D3 bit, D4 bit and D7 bit are not used.

  Address F00B stores input port 1 level data. Specifically, the D0 bit has a stop switch sensor 3 signal, the D1 bit has a stop switch sensor 2 signal, the D2 bit has a stop switch sensor 1 signal, the D3 bit has a three-sheet sensor signal, and the D4 bit has a 1 signal. A sheet insertion switch signal, a clearing switch signal is stored in the D5 bit, and a start switch sensor signal is stored in the D6 bit. These signals are the same as the signals input to the input port 1 shown in FIG. The D7 bit is not used.

  Address F00C stores input port 2 level data. Specifically, the D0 bit is a torso sensor (first torso) signal, the D1 bit is a torso sensor (second torso) signal, the D2 bit is a torso sensor (third torso) signal, The payout sensor 1 signal is stored in the D3 bit, the payout switch 2 signal is stored in the D4 bit, the closing sensor 1 signal is stored in the D5 bit, the closing sensor 2 signal is stored in the D6 bit, and the medal passage sensor signal is stored in the D7 bit. These signals are the same as the signals input to the input port 2 shown in FIG.

  Address F00D stores the edge data of the setting key switch signal and the setting / reset signal input to input port 0. Specifically, the D0 bit stores falling data of the setting key switch signal, the D1 bit stores rising data of the setting / reset signal, and the D2 bit stores rising data of the setting key switch signal. You. The bits D3 to D7 are not used.

  Here, the falling data is 1 when the corresponding signal changes from the on state to the off state, changes when the corresponding signal maintains the on state or the off state, and changes from the off state to the on state. It means data that becomes 0 when done. The rising data is 1 when the corresponding signal changes from the off state to the on state, and when the corresponding signal maintains the on state or the off state, and when the corresponding signal changes from the on state to the off state. Means data which becomes 0.

  Next, in FIG. 14, the rising data of each signal input to the input port 1 is stored in the address F00E of the RWM. Specifically, the D0 bit has the rising data of the stop switch sensor 3 signal, the D1 bit has the rising data of the stop switch sensor 2 signal, the D2 bit has the rising data of the stop switch sensor 1 signal, and the D3 bit has three data. The rising data of the closing sensor signal, the rising data of the one-sheet closing switch signal is stored in the D4 bit, the rising data of the clearing switch signal is stored in the D5 bit, and the rising data of the start switch sensor signal is stored in the D6 bit. The D7 bit is not used.

  The address F00F stores the rising data of each signal input to the input port 2. Specifically, the rising data of the torso sensor (first torso) signal is set to the D0 bit, the rising data of the torso sensor (second torso) signal is set to the D1 bit, and the turning sensor (the first torso) signal is set to the D2 bit. R3 data rising data, D3 bit rising sensor 1 signal rising data, D4 bit rising switch 2 signal rising data, D5 bit rising sensor 1 signal rising data, D6 bit closing. The rising data of the sensor 2 signal and the rising data of the medal passage sensor signal are stored in the D7 bit. These signals are the same as the signals input to the input port 2 shown in FIG.

  Note that various rising data and falling data stored in the addresses F00D, F00E, and F00F correspond to changes in the level data of the corresponding signals (low to high for rising data and high to low for falling data). ) Is set to 1 when it is detected in the timer interrupt processing, and is returned to 0 in the next timer interrupt processing.

  The value of the number of medals credited to the slot machine 10 is stored in the address F010. The numerical value range of the value that can be stored at this address is 0 to 32H (0 to 50 in decimal notation). A numerical value to be displayed on the acquired number display unit 28 is stored in the address F011. That is, when the small win is awarded, any one of 1H, 3H, and 9H is stored as the payout number (acquired number). When the set value is changed (the setting change device is operating), a value of 58H (88 in decimal) is stored. Further, when the pressing order is notified in the notification gaming state, any value of 65H to 6AH (101 to 106 in decimal notation) is stored. More specifically, 65H (101 in decimal notation) when announcing forward push (left to middle to right), and 66H (102 in decimal notation) to notify scissor press (left to right to middle). , 67H (103 in decimal notation) to notify forward middle press (middle → left → right), 68H (104 decimal notation) to notify reverse middle press (middle → right → left), reverse scissors press 69H (105 in decimal notation) is stored when informing (reverse scissors pressing), and 6AH (106 in decimal notation) is stored in order to notify reverse pressing (right → middle → left).

  The address F012 stores the value of the LED display counter. The LED display counter is 1-byte data consisting of 8 bits, and the count value is represented by an upper digit and a lower digit of the credit amount display 27, an upper digit and a lower digit of the acquired number display 28, and a set value display. Of the five five-segment displays of 87, the seven-segment display subject to display control is shown. The value of the LED display counter is set to 10H (00010000B) → 08H (00001000B) → 04H (00000100B) → 02H (00000010B) → 01H (00000001B) → 00H (00000001B) → 10H every time the timer interrupt processing described later is performed. (00010000B) →... In a cyclical manner. Here, the change from 01H to 00H and the change from 00H to 10H are performed in one timer interrupt process.

  As a result, when the value of the LED display counter is 01H, it is set to the upper digit of the credit number display 27, when it is 02H, it is set to the lower digit of the credit number display 27, and when it is 04H, it is set to the upper digit of the acquired number display 28. , 08H, the number is displayed on the lower digit of the acquired number display 28, and 10H, the set value display 87 is displayed sequentially. That is, in each of the 7-segment displays, a number is displayed at a rate of one out of five times of the timer interrupt processing that is periodically executed, so that so-called dynamic lighting control is performed.

  The address F013 stores the value of the LED display request flag. The LED display request flag is a flag indicating a 7-segment display that can perform display control, and is stored as 1-byte data of 8 bits. Each bit of this data corresponds to the above-mentioned five 7-segment indicators, specifically, the D0 bit is the upper digit of the credit indicator 27, the D1 bit is the lower digit of the credit indicator 27, and the D2 bit Represents the upper digit of the acquired sheet display 28, the D3 bit corresponds to the lower digit of the acquired sheet display 28, and the D4 bit corresponds to the set value display 87.

  The value of the LED display request flag is 000011111B because the set value display 87 cannot be displayed and the other 7-segment display can be displayed during normal times (during game play and game standby). During the setting change mode (that is, during operation of the setting change device), the set value display 87 and the acquired number display 28 can be displayed, and the other 7-segment display cannot be displayed. In the setting change mode, for example, when it is desired to display “88” on the credit amount display 27, 58H is stored in the RWM address F010, and 0111111B is stored in the RWM address F013. You may.

  As described above, in the setting change mode, the acquired number display 28 (and the number of credits display 27) displays a special mode ("88" in the present embodiment) which is not displayed during a normal game. The fact that the setting change mode is being performed becomes visible from the front of the front door 14. As a result, the staff at the game hall can quickly detect that the set value has been changed due to fraud. In addition, during the setting confirmation mode (during confirmation of the set value), the above-described special mode (“88” in the present embodiment) is not displayed on the acquired number display 28 (and the number of credits display 27). The staff at the game hall can easily identify whether the mode is in the setting change mode or the setting confirmation mode.

  Thus, for example, if the set value is not updated by operating the set / reset switch 82c after turning on the key switch 82b to change the set value, the acquired number display 28 (and the number of credits display) According to the display mode of 27), it is possible to confirm whether or not the shift to the setting confirmation mode is caused by mistake instead of the setting change mode. Further, by notifying the setting change mode by the display mode of the acquired number display 28 (and the number of credits display 27), the setting change mode is compared with the case of notifying the setting change mode only by voice. Can be easily identified. Although the special mode indicating the setting change mode is “88”, it goes without saying that other display modes may be used as the special mode. However, it is desirable that the mode is different from numerical values from 0 to 50 and error numbers that can be displayed (HP, HE, H0, CE, CP, CH, C0, C1, FE, etc.).

  The address F014 stores data (error number) for displaying the error code corresponding to the error detected by the abnormality detecting means 170 on the acquired number display 28. Specifically, when a medal clogging error (error code: HP) is detected, “14” is detected, when an empty error (error code: HE) is detected, “13”, and a payout error (error code: H0). Is detected, "15" is detected when an insertion sensor passing error (error code: CE) is detected, "4" is detected when a medal insertion error (error code: CP) is detected, and a medal is detected. "1" when a stay error (error code: CH) is detected, "5" when a throwing sensor error (error code: C0) is detected, and a medal passing error (error code: C1) is detected. Is “6”, a medal full error (error code: FE) is “23”, and if none of the above nine errors is detected, “0” is set. It is stored.

  Here, the value stored in the address F014 is referred to for reading out the segment data for displaying the error code on the acquired number display 28 from the LED segment table stored in the ROM of the main control means 100. . Here, the contents of the LED segment table will be described with reference to FIG. The LED segment table is a table in which segment data for specifying which segment is to be lit when displaying numbers, alphabets, and symbols on a 7-segment display. The segment data is 8-bit data (D0 to D7). As shown in the column of "binary number" in FIG. 16, each bit of D0 to D6 corresponds to segments a to g of the 7-segment display. ing. Then, control is performed so that the segment corresponding to the bit of 1 among the bits D0 to D6 is turned on.

  The LED segment table includes a first table (TBL_SEG_DATA1) and a second table (TBL_SEG_DATA2). As shown in FIG. 16A, the first table includes segment data for displaying “C”, “H”, “F”, “E”, and “P” in order from an address 1211 of the ROM to an address 1215. Is stored. As shown in FIG. 16B, the second table stores segment data for displaying “0” to “9” and “=” from the ROM address 1216 to the address 1220 in order.

  Designation of desired segment data from the first table and the second table is performed by using an offset value based on the start address of each table. Here, when the error code is displayed on the acquired number display 28, the top address of the first table is used as a reference, and when the obtained number (payout number) or the pressing order is displayed, the top address of the second table is used as the reference. Become. Therefore, for example, when an error code “HP” is displayed, since the reference start address is 1211, the offset value for specifying the segment data for displaying the upper digit of the acquired number display 28 is “ 1 "(corresponding to ROM address 1212), and the offset value designating segment data for displaying the lower digit is" 4 "(corresponding to ROM address 1215).

  Here, the error number stored in the address F014 of the RWM in FIG. 14 is the offset value of the segment data displayed in the upper digit of the acquired number display 28 and the segment displayed in the lower digit when the error code is displayed. It is a value that can specify the data offset value. That is, the value of the quotient obtained by dividing the stored error number by "10" is the offset value of the segment data displayed in the upper digit of the acquired number display 28, and the remaining value is the segment value displayed in the lower digit. This is the data offset value.

  For example, if “15” (corresponding to the payout error) is stored as the error number, 15 ÷ 10 = 1, and the remainder is 5, so the offset of the segment data displayed in the upper digit of the acquired number display 28 The value is “1”, and the offset value of the segment data displayed in the lower digit is “5”. Therefore, the upper digit of the obtained number display 28 refers to the segment data stored in the ROM address 1212, and “H” is displayed, and the lower digit refers to the segment data stored in the ROM address 1216. "0" is displayed.

  Next, data (LED display data) for controlling the lighting / extinguishing of the game start display LED, the insertion display LED, the re-game display LED, and the clearing display LED provided on the front panel 20 are stored in the address F015 shown in FIG. ) Is stored. Specifically, the D0 bit is the LED display data for the game start display LED, the D2 bit is the LED display data for the insertion display LED, the D3 bit is the LED display data for the replay display LED, and the D4 bit is the clearing display LED. LED display data. When the value of each LED display data is "1", the corresponding display LED is turned on, and when the value is "0", it is turned off.

  At the address F01C, data indicating the operating state of the blocker in the selector 80 and the hopper motor 46 in the medal payout device 83 is stored. Specifically, the value of the D6 bit indicates the on / off state of the blocker signal, and the value of the D7 bit indicates the on / off state of the hopper motor drive signal. At the addresses F02A and F02B, values for measuring the time until the game standby display is started are stored. Specifically, when the previous game is completed and the current game can be started, the value of "27101" (= 69DDH) is stored in two addresses F02A and F02B in decimal. . Specifically, DDH is stored in the address F02A, and 69H is stored in the address F02B. Thereafter, each time the timer interrupt processing is executed, “1” is decremented. If the medal is not inserted before the value becomes "0", the game standby display is started.

  The game standby display here indicates that the display displayed on the acquired number display unit 28 is set to “00”. For example, when a small winning combination with payout of nine pieces wins, “09” is displayed on the acquired number display device 28. Thereafter, when the player wants to end the game and operates the settlement switch 33 to pay out medals such as credits, the acquired number display 28 keeps displaying “09”. In this state, since "09" is displayed on the acquired number display 28, there is a possibility that the next player may be uneasy about whether to play a game (whether or not the slot machine has no player). is there. For this reason, after a predetermined time (about 1 minute) has elapsed, the display on the acquired number display 28 is set to “00” (or turned off), so that the rotation rate of the player (in other words, the slot machine 10 operation rate).

  Note that the game standby display (so-called demonstration display) by the sub-control means 200 is executed when the sub-control means 200 determines that a predetermined time (about 1 minute) has elapsed after a timer measurement from a predetermined timing after the end of the game. Is also good. Further, the main control unit 100 may transmit a command indicating the start of the game standby display to the sub control unit 200 at the start of the game standby display, and execute the command when the sub control unit 200 receives the command.

<< Explanation of sub-control means >>
<Sub-control means and peripheral hardware configuration>
The sub-control unit 200 includes a CPU, a ROM, a RWM, and the like, and based on a control command transmitted from the main control unit 100, controls the effect to be executed, and transmits from the sub-control substrate 202 On the basis of the sub-control command, the image display device 70, the image control board 204 for driving the production means such as the speakers 64L and 64R and the production lamp 72 are configured.

<Functional block of sub-control board>
The sub-control board 202 determines an effect or notification content based on the control command transmitted from the main control unit 100, and an effect control unit 210 that generates a sub-control command for executing the determined effect or notification, A control command receiving unit 220 for receiving a control command transmitted from the main control unit 100, and a sub-control command transmitting / receiving unit 230 for transmitting a sub-control command generated by the effect control unit 210 to the image control board 204. Have been.

(Explanation of production control means)
The effect control means 210 is a means for controlling an effect according to the game, and includes an effect lottery means 212 and an effect state control means 214. Here, the effect according to the game means an effect according to the set value, the RT state, the game state, the presence or absence of the freeze effect, the result of the role lottery and the advantageous section lottery, and the like.

  The production control means 210 is based on the control command received from the main control means 100, the production lottery means 212 for determining the production according to the current production state by lottery, and the control command transmitted from the main control means 100. And effect state control means 214 for performing transition control of the effect state. Here, in the effect state controlled by the effect state control means 214, an effect state similar to the game state in the main control means 100 may be provided, and the same transition control as the game state control means 144 may be performed.

(Description of control command receiving means)
The control command receiving unit 220 receives a control command transmitted by serial communication from the main control unit 100, converts the received control command into parallel data, and receives a command buffer (for example, RWM) included in the sub-control unit 200 in the order of reception. Part of the storage area). As a result, the effect control unit 210 sequentially performs processing based on the control command stored first in the control commands stored in the command buffer.

(Explanation of sub-control command transmission / reception means)
The sub-control command transmission / reception unit 230 transmits the sub-control command generated by the effect control unit 210 to the image control board 204 by serial communication at a predetermined cycle (for example, 1 millisecond). The sub-control command transmitting / receiving means 230 receives a command transmitted from a sub-control command transmitting / receiving means 240 described later.

<Function block of image control board>
The image control board 204 includes a sub-control command transmitting / receiving means 240 and an image / sound output means 240, and based on the sub-control command transmitted from the sub-control board 202, the image display device 70, the speakers 64L and 64R, and various lamps. (Side lamps 52L, 52R, effect lamp 72, decorative lamps 74L, 74R) are driven and the effect determined by effect control means 210 is executed.

(Description of sub-control command transmission / reception means)
The sub-control command transmission / reception unit 240 receives the sub-control command transmitted by serial communication from the sub-control command transmission / reception unit 230, converts the received sub-control command into parallel data, and stores it in the sub-command buffer in the order in which it was received. I will do it. The sub-control command transmitting / receiving means 240 is a command indicating whether the image control board 204 is operating normally or a command indicating whether the command transmitted from the sub-control command transmitting / receiving means 230 has been normally received. Is transmitted to the sub-control command transmitting / receiving means 230. Thus, the sub-control board 202 can detect an abnormality that has occurred in the image control board 204, and can retransmit the sub-control command when the image control board 204 fails to receive the sub-control command. .

(Description of image / sound output means)
The image / sound output unit 250 outputs the image signal and sound signal for presentation generated by the image control board 204 to the image display device 70 and the speakers 64L and 64R. As a result, the effect image is displayed on the image display device 70, and sound is generated from the speakers 64L and 64R. On the other hand, from the image display device 70 and the speakers 64L and 64R, a normal operation signal indicating whether or not a normal operation is possible is output to the image control board 204 (or the sub control board 202). If the normal operation signal cannot be received, the image / audio signal may be held without being sent, or may be discarded as the game progresses.

[Explanation of processing by control means]
<< Description of control processing in main control means >>
<Description of program start processing>
First, a program start process executed by the main control means 100 when the power switch 82a of the power supply unit 82 is turned on from off will be described with reference to the flowchart shown in FIG. When the power switch 82a is turned on, first, the main control means 100 sets fixed value data F0H which is referred to when specifying an RWM address in the Q register of the CPU (step S10). In the present embodiment, most of the data related to the control of the game is stored in the FWM to F0FF of the RWM address. Therefore, the RWM address specified during the execution of the process related to the game has a value of F0xx (x is 0 to FH). Either).

  Therefore, when the power is turned on, the value of F0H is set in the Q register in advance, and when accessing the FWM to F0FF of the RWM address, the value of the upper 1 byte (F0H) of the address accessed from the Q register is set. ) To get. As a result, for example, the data capacity of the program and the processing load on the CPU are reduced as compared with the case where the RWM address to be accessed is described in two bytes each time in the program or the case where the value of the upper 1 byte of the RWM is read from the ROM. can do. Also, 00H is set in the E register. The significance of this process will be described later in step S32.

  Next, the main control means 100 sets the value (F000) of the RWM head address in the HL register of the CPU (step S12). Specifically, the value (F0H) read from the Q register is set in the H register, and 00H is set in the L register. Then, a checksum of an RWM address (for example, F000 to F3FF) within a predetermined range is calculated. Specifically, after adding the data stored in the RWM address indicated by the value of the HL register to the data stored in the A register, 1 is added to the value of the HL register to specify the next RWM address. (Step S14). Then, it is determined whether the calculation of the checksum regarding the range of the RWM address has been completed (step S16). If the calculation has not been completed, the determination result is NO, and the process of step S14 is executed again.

  Here, whether the calculation of the checksum is completed is determined by calculating the checksum when the value of the third bit (the third bit counted from the least significant bit) of the H register becomes 1. It is determined that the process has been completed. That is, since the last address for calculating the checksum is F3FF, when the value of the H register changes from 11110111B to 11111000B, that is, when the value of the third bit of the H register changes from 0 to 1, The result of the determination in step S16 is YES. As described above, it is possible to determine whether or not the checksum in the predetermined address range has been completed only by determining whether or not the value of the specific bit of the H register is 1.

  When the result of the determination in step S16 is YES, the main control means 100 determines whether or not the checksum of the RWM is normal (step S18). Specifically, if the value of the A register is 0 (that is, the zero flag of the flag register is 1), the checksum of the RWM is normal and the result of the determination in step S18 is YES. On the other hand, if the value of the A register does not become 0 (that is, the zero flag of the flag register is 0), the check sum of the RWM is determined to be abnormal, and the determination result of step S18 is NO.

  If the decision result in the step S18 is YES, the main control means 100 decides whether or not a power-off process has been performed (step S20). Specifically, the value of the power-off processing completed flag stored at the predetermined address of the RWM is read and set in the A register, and the value obtained by subtracting the predetermined value (for example, 55H) from the value is 0 (ie, When the zero flag of the flag register becomes 1), it is determined that the power-off processing has been performed, and the determination result in step S20 is YES. On the other hand, if the result of the subtraction is that the value of the A register does not become 0 (that is, the zero flag of the flag register is 0), it is determined that the power-off processing has not been performed and the determination result of step S20 is NO. become.

  When the result of the determination in step S20 is YES, the main control means 100 sets data for determining whether the power-off recovery is normal in step S32 described later in the E register of the CPU (step S22). Specifically, the current value of the A register (for example, 55H) is stored in the E register. In other words, the value of the E register is updated from “00H” stored in step S10 to “55H”.

  When the determination result of step S18 or S20 is NO, or when the process of step S22 is completed, the main control unit 100 reads the values of various input signals (see FIG. It is set in the A register (step S24). Then, from the value of the signal set in the A register, the door switch signal and the setting key switch signal are converted into positive logic signals and extracted (step S26). Specifically, first, an XOR (exclusive OR) operation between the value set in the A register and the predetermined value 01100001B is performed to correct the set key switch signal (D1 bit) and the door switch signal (D2 bit). Convert to logical signals. Then, an AND (logical product) operation of the value obtained as a result of the operation and the predetermined value 00000110B is performed to extract the values of the door switch signal and the setting key switch signal.

  Note that the door switch signal and the setting key switch signal are used in the determination of the processing in step S28 described later. As in the present embodiment, when the setting key switch signal (D1 bit) input to the input port 0 is on (rotating to the right), the value is “1”, and the door switch signal (D2 bit) is on. If "1" is input when the front door is open, these signals are positive logic signals, so that the above-described process of converting to a positive logic signal need not be performed. . Furthermore, when each signal is acquired from another input port when performing the processing of step S28 described later, the efficiency is low (the capacity of the program is increased). For example, when a door switch signal is assigned to a predetermined bit of input port 0 and a set key switch signal is assigned to a predetermined bit of input port 1, signals must be obtained individually for these two input ports. ineffective. For this reason, as in the present embodiment, by making it possible to acquire input data used in the processing of step S28 described later from the same input port, the capacity of the program can be reduced.

Next, the main control means 100 determines whether or not all signals designated in advance among the input signals of the input port 0 are turned on (step S28). Here, the "prespecified signal" is a door switch signal and a setting key switch signal. Specifically, the following processes (1) to (3) are performed in steps S26 to S28.
(1) Perform comparison operation processing (subtraction processing) with the predetermined value 00000110B of the data set in the A register. If the result of this operation is “0”, the zero flag of the flag register becomes “1”.
(2) The data set in the E register is set in the A register. The value of the E register at this time differs depending on whether or not the processing in step S22 described above has been performed. For example, when the processing in step S22 is performed, 55H is set, and when the processing in step S22 is not performed. Is set to 00H by the processing in step S10. Therefore, 55H or 00H is set in the A register. The process (2) is a process for step S32 described later.
(3) It is determined whether or not the zero flag of the flag register according to the result of the arithmetic processing in (1) is “1”, and if the zero flag is “1” (the result of the arithmetic processing of (1) is “0”) If there is, the determination is YES, and if the zero flag is not "1", the determination is NO.

  If the decision result in the step S28 is YES, the main control means 100 sets, in the HL register, the value of the RWM initialization start address to be executed when the return state from the power failure is abnormal, and sets the number of initialization bytes (initialization byte). Is set in the BC register (step S30). Here, the range in which the RWM is initialized differs depending on whether the state of return from power-off is normal or abnormal. If abnormal, the range of addresses F000 to F3FF (range of 400H) is initialized and normal. If so, the range of addresses F005 to F3FF (range of 3FBH) is initialized. Therefore, in the process of step S30, the value of F000H is set in the HL register, and the value of 0200H is set in the BC register.

  Next, the main control means 100 determines whether or not the power-off recovery is normal (step S32). Specifically, if the power-off recovery is normal, the result of the comparison operation (the process of subtracting the predetermined value from the A register) between the value of the A register and the predetermined value 55H becomes 0 (the zero flag is 1), and the judgment is made. The result is YES. That is, when the value of the A register is 00H, the determination result is NO, and when the value of the A register is 55H, the value stored in the A register is Set before. If the decision result in the step S32 is NO (the zero flag is 0), the process shifts to a setting changing device process described later (see FIG. 18). On the other hand, if the determination result in step S32 is YES (the zero flag is 1), the value of the RWM initialization start address to be executed when the return state from the power-off is normal is set in the HL register, and the initialization is performed. The value of the number of bytes (initialization range) is set in the BC register (step S34). That is, the value of F005H is set in the HL register, and the value of 03FBH is set in the BC register. Then, the process proceeds to a setting change device process (see FIG. 18) described later.

  If the result of the determination in step S28 is NO, the main control means 100 sets data for displaying the error code (E1) of the power failure recovery error on the acquired number display 28 in the D register (step S28). S36). Then, it is determined whether or not the value of the power-off recovery data set in the A register is "normal" (that is, 55H) (step S38). If the processing is not normal, the result of the determination is NO, and an unrecoverable error processing is executed.

  Here, in the power-off recovery processing, the data stored in the stack pointer temporary storage area set in the RWM of the main control unit 100 is set in the stack pointer (SP register), and then the timer shown in FIG. The interrupt processing is started, and the value of the power-off processing completed flag stored at a predetermined address of the RWM is cleared to 0. Then, it is determined whether or not the return address is stored in the stack area. When the return address is stored in the stack area (for example, when the power-off process or the like is normally performed), the return address is stored. Processing is resumed from the return address. On the other hand, when the return address is not stored in the stack area (for example, in an initial state such as factory shipment), the processing is executed from the beginning of the game progress main processing of FIG. 19 described later. In the non-recoverable error processing, after all output ports for outputting signals from the main control unit 100 to various external devices are turned off, an error code corresponding to the acquired number display 28 (power-off recovery) is performed. If the data is abnormal, E1) is repeatedly displayed to stop the progress of the game. Also, unlike the recoverable error, the non-recoverable error cannot be canceled even when the setting / reset switch 82c is operated, and can be recovered by a setting change device process described later. . In other words, it is possible to return after clearing F3FF to F3FF of the RWM address.

  In the program start process of FIG. 17, after it is determined in step S28 whether all the designated signals are on, it is determined in step S32 whether the power-off recovery is normal. However, it is also possible to determine whether or not all the specified signals are turned on after determining whether or not the power recovery is normal. Specifically, after performing the processing in step S26, the processing in steps S30 and S32 is performed. If the determination result in step S32 is YES, the processing in step S34 is performed, and then the determination processing in step S28 is performed. . If the determination result in step S32 is NO, the determination process in step S28 is performed without performing the process in step S34. Then, when the determined result in the step S28 is YES, the process shifts to the setting changing device process in FIG. 18, and when the determined result is NO, the processes in the steps S36 and S38 are performed.

<Description of setting change device processing>
Next, with reference to the flowchart shown in FIG. 18, the contents of the setting change device processing executed when the determination result in step S32 in FIG. 17 is NO will be described. First, the main control means 100 sets an initial value of the stack area in an SP register (corresponding to a stack pointer) (step S50). Here, the value of F200H is set in the SP register. Next, the main control means 100 initializes the RWM address set in the HL register (step S52). Here, since the value of F000 is set in the HL register in step S30 of FIG. 17, 0 is stored in the RWM address F000.

  The main control means 100 sets an RWM address to be initialized next in the HL register (step S54), and determines whether or not the RWM initialization has been completed (step S56). Specifically, after adding 1 to the value of the HL register, subtracting 1 from the value of the BC register, it is determined whether or not the value of the BC register is 0 (that is, the zero flag is 1). If it is 0, the decision result in the step S56 is NO, and the process shifts to a step S52. On the other hand, when the zero flag is set to 1 by the process of step S54, the determination result of step S56 is YES, and a timer interrupt process described later is started (step S58).

  Next, in order to transmit the setting change device operation start command (8038H) to the sub control means 200, the main control means 100 sets a predetermined value 0038H in the DE register as an output request of the command (step S60). Then, the main control means 100 generates a setting change device operation start command (8038H) based on the value set in the DE register, and sets a predetermined RWM ring buffer area (a storage used as a ring buffer). The generated setting change device operation start command is stored in an area (for example, a designated address among the RWM addresses F106 to F145) (step S62). The commands stored in the ring buffer area are transmitted to the sub-control unit 200 in order from the oldest stored command by a timer interrupt process described later.

  Next, the main control means 100 sets a value (E0H) for measuring a waiting time until the start of operation of the setting change device in the BC register (step S64), and performs a waiting process for two bytes (step S66). This 2-byte waiting process is a process of waiting until the value of the BC register set in step S64 is set to 0 by a timer interrupt process described later. The timer interrupt process is executed every 2.235 milliseconds, and each time the timer interrupt process is executed, one is subtracted from the value set in the BC register. Therefore, since the value of E0H (decimal 244) is set in the BC register in step S64, the standby state is set for about 0.5 second.

  This standby process is caused by the difference between the RWM initialization range of the main control unit 100 and the RWM initialization range of the sub-control unit 200. That is, since the initialization range of the RWM of the sub-control unit 200 is wider than the initialization range of the RWM of the main control unit 100, the initialization of the sub-control unit 200 has not been completed yet, If the game progress main process is started on the 100 side, the control process of the main control unit 100 and the control process of the sub control unit 200 may not be synchronized, and this is to avoid such a situation. Therefore, by the time the main control unit 100 completes the above-described standby processing, the “setting change device operation start” command is transmitted to the sub control unit 200, and the sub control unit 200 transmits “setting change device operation start”. The initialization of the RWM is started based on the reception of the command, and the control processing of the main control means 100 and the control processing of the sub-control means 200 after the start of the setting change can be synchronized as much as possible.

  After waiting for a predetermined time (approximately 0.5 seconds) in the process of step S66, the main control means 100 stores 88 as the value of BCD (binary decimal notation) in the RWM address F011 (see FIG. 14) ( Step S68). This value is used as an offset value of the second table (start address: 1216) shown in FIG. 16B, and as a result, “8” is displayed in the upper digit and the lower digit of the acquired number display 28, respectively. Will be. Then, by storing 0111100B as the value of the LED display request flag in the RWM address F013 (see FIG. 14), the upper digit and lower digit of the acquired number display 28 and the set value display 87 are displayed. (Step S70). In the process of step S70, the address value (F000) of the set value data is set in the HL register.

  Next, the main control means 100 acquires setting / reset button signal rising data (step S72), and updates the setting value data (step S74). Specifically, first, the setting key and the setting / reset button signal edge data stored in the RWM address F00D are set in the A register, and the value is shifted by one digit to the lower digit side, thereby setting / resetting the button signal. Is moved to the least significant bit (D0 bit). Next, an AND operation is performed on the value of the A register after the shift and the predetermined value 00000001B to invalidate the rising data bit of the setting key switch signal (which is originally D2 bit but is shifted to D1 bit). Then, only the rising data of the setting / reset button signal is extracted and set in the A register. Then, the setting value data is read from the RWM address (F000) set in the HL register by the processing in step S70, and is added to the A register.

  The above process is a process for adding 1 to the set value data stored in the RWM when the value of the rising data of the set / reset button signal becomes 1 when the set / reset switch 82c is operated. For example, in a situation where “2” is stored in the set value data, if the value of the rising data of the set / reset button signal is 1 (the value of the A register = 01H), the value of the A register becomes 03H. When the value of the rising data of the setting / reset button signal is 0 (the value of the A register = 00H) under the condition that “2” is stored in the set value data, the value of the A register becomes 02H. . Also, in a situation where “5” is stored in the set value data, if the value of the rising data of the set / reset button signal is 1 (the value of the A register = 01H), the value of the A register becomes 06H. If the value of the rising data of the setting / reset button signal is 0 (the value of the A register = 00H) under the condition that “5” is stored in the set value data, the value of the A register becomes 05H. .

  Next, the main control means 100 determines whether or not the set value is within the normal range (step S76). Specifically, when 6 is subtracted from the value of the A register and the carry flag becomes 1 (that is, a carry-down occurs), the determination result is YES assuming that the set value is within the normal range. If the decision result in the step S76 is NO, the main control means 100 sets the value of the A register to 0 (initial value of the set value data). Specifically, the value of the A register is set to 0 by performing an XOR operation on the value of the A register with the same value of the A register. For example, when the value of the A register becomes 06H in the process in step S74, the value can be set to 00H by exclusive OR of 06H and 06H. As described above, when the value of the A register becomes any value from 00H to 05H by the process of step S74, the result is YES, and when the value of the A register becomes 06H, the value can be set to 00H. That is, the value of the A register (the set value data in this case) can be cyclically updated within the range of 00H to 05H by a simple process.

  When the result of the determination in step S76 is YES or when the processing in step S78 is completed, the main control means 100 sets the value of the set value data set in the A register to the RWM address ( F000) (step S80). Next, the main control unit 100 performs an interrupt waiting process for waiting for one interrupt (step S82), and then, among the rising data of the input port 1 stored in the RWM address F00E, the D6 bit start switch sensor signal rising. It is determined whether the value of the data is 1 (step S84). When the value of the start switch sensor signal rising data is 0, the determination result is NO, and the process returns to step S72.

  Here, if the interrupt wait standby process in step S82 is not executed, and if the set / reset button signal rising data is 1, the setting / reset button signal rising data becomes 0 in the next timer interrupt process. The processing of steps S72 to S84 is repeatedly executed until the value is changed to a value, and the setting value stored in the RWM may become an unintended value. Therefore, in order to avoid such a situation, the process of step SS82 is executed, and after the setting / reset button signal rising data is set to 0 by the timer interrupt process, the determination process of step S84 is performed. ing. In the present embodiment, in the interrupt waiting standby process in step S82, the process waits until the timer interrupt process is performed once. However, the present invention is not limited to this. You may make it wait until it is performed.

  If the value of the start switch sensor signal rising data is 1 in the determination processing of step S84, the determination result is YES, and the main control unit 100 sets the setting key switch and the setting / reset stored in the RWM address F00D. It is determined whether or not the value of the falling data of the set key switch signal of the D0 bit among the button signal edge data is 1 (step S86). When the value of the falling data of the setting key switch signal is 0, the determination result is NO, and the determination process of step S86 is performed again. As a result, while the value of the falling data of the setting key switch signal is 0, the determination processing of step S86 is repeatedly executed, and when the value of the falling data of the setting key switch signal becomes 1, the determination result becomes YES. , The value of the acquired number data (88H indicating that the setting change obtaining device is operating) stored in the RWM address F011 is cleared by updating it to 00H (step S88).

  Next, the main control means 100 updates the value of the LED display request flag stored in the RWM address 013 to 000011111B, disables display of the set value display 87, upper and lower digits of the credit number display 27, and The upper digit and the lower digit of the acquired number display 28 are displayed (step S90). Then, the main control means 100 sets 80H in the D register, sets 00H (lower one byte of the RWM address of the set value data) in the E register, and outputs the set value changing device operation end command (see FIG. 12). An output request is set (step S92).

  Next, the main control means 100 reads the set value data from the RWM address F000 based on the value (00H) set in the E register in step S92, and generates a second control command of the set value changing device operation end command, It is stored in the ring buffer area of the RWM together with the first control command (80H) (step S94). As a result, the set value changing device operation end command stored in the ring buffer area is transmitted to the sub control means 200 by the timer interrupt processing. Then, when the process of step S94 is completed, the main control means 100 shifts to a game progress main process described below.

<Explanation of game progress main processing>
Next, the contents of the game progress main process will be described with reference to the flowchart shown in FIG. First, the main control means 100 performs a game start process (step S100). In this game start processing, the game standby display start time is set ("27101" is stored in the RWM addresses F02A and F02B), the current setting value for the sub control means 200, and the game state (whether a re-game or BB game is being performed). No), information such as the current RT state and whether or not the vehicle is in an advantageous section is transmitted. Next, the main control means 100 determines whether or not a medal for playing a game has been inserted (step S102). If there is no inserted medal, the determination result is NO, and a game medal insertion standby display process is performed in which the current set value can be confirmed according to the ON / OFF state of the key switch 82b (step S104). ).

  When the result of the determination in step S102 is YES (medals have been inserted), or when the processing in step S104 is completed, the main control means 100 performs processing associated with the insertion of medals (game medal management processing). (Step S106). This process includes, for example, a clearing process when the clearing switch 33 is operated, a process of detecting a medal inserted into the medal slot 32, and the like. Next, the main control means 100 determines whether or not the operation of the start switch 36 can be accepted and whether or not the start switch 36 has been operated (step S108). Here, the operation of the start switch 36 is set in a receivable state when a prescribed number (three) of medals are inserted or when a re-game combination is won in the previous game. If the start switch 36 has not been operated, the determination result of step S108 is NO, and the process returns to step S102.

  If it is determined in step S108 that the start switch 36 has been operated (YES), the blocker of the selector 80 is turned off to invalidate the medal insertion from the medal insertion slot 32 (step S110). Then, a role lottery process is performed based on the role lottery table shown in FIG. 10 (step S112), and the instruction data (one of 101 to 106) corresponding to the pressing order to be notified based on the current gaming state and the result of the role lottery. Is performed, and a game state process for performing an advantageous section lottery or the like is performed (step S114). Then, an instruction display process of displaying a number corresponding to the instruction data determined in the game state process on the acquired number display 28 is performed (step S116), and the advantageous section (AT) related information (for example, the result of the advantageous section lottery, The result of the shortened lottery (falling lottery) performed during the advantageous section is transmitted to the sub-control means 200 (step S118).

  Next, the main control means 100 performs a mask process for generating an effect group number indicating an effect to be executed by the sub-control means 200 in accordance with the winning / replay winning number determined by the winning lottery (step S120). A winning / re-game winning number and an effect group number corresponding to the gaming state and the result of the lottery are transmitted to the sub-control means 200 (step S122). Then, after performing a reel rotation start preparation process performed before the rotation of the reels 40L, 40C, 40R is started (step S124), a reel stop management process is performed (step S126). In this reel stop management process, when the rotation of the reels 40L, 40C, 40R is started and the stop switches 37L, 37C, 37R are operated, stop control is performed on the reel corresponding to the operated stop switch.

  Here, the reel stop control is performed based on an operation flag generated based on a winning / re-game winning number and an accessory winning number. This operation flag is associated with flag information indicating whether or not to be a target of the pull-in control, for each symbol combination shown in FIGS. 4 to 7. Is stored in Further, every time the stop switch is operated, the information indicating the operated stop switch and the fact that the reel corresponding to the operated stop switch has been stopped are transmitted to the sub-control means 200.

  Next, when all the reels stop, the main control means 100 performs a display determination process of determining whether or not one of the symbol combinations shown in FIGS. 4 to 7 matches (step S128). The information about the symbol combination displayed based on the processing result is transmitted to the sub control means 200 (step S130). If the symbol combination stopped and displayed on the winning line L matches any of the symbol combinations of the winning combination, the medal payout number corresponding to the winning combination that has won is stored in a predetermined address of the RWM. Then, the hopper motor 46 is driven to perform payout processing for paying out the number of medals corresponding to the matched winning combination (step S130). Further, at the start of payout of medals and at the end of payout, information indicating this is transmitted to the sub-control means 200.

  Next, the main control means 100 performs a game end check process (step S132), and performs transition control of the RT state and the game state based on the stopped and displayed symbol combination and the like. When the symbol combination corresponding to the condition device “BB01” (hereinafter, also referred to as “symbol combination of BB01”; the same applies to the symbol combinations corresponding to the other condition devices), the external centralized terminal board is displayed. The BB signal is turned on via 86. Then, information indicating that the game has ended is transmitted to the sub control means 200. Further, when the BB game has ended, information indicating that the BB game has ended is also transmitted to the sub control means 200.

  When one game is completed by the above processing, the main control means 100 returns to the game start processing of step S100 again and performs processing for the next game.

<Explanation of game medal insertion standby display processing>
Next, the content of the game medal insertion standby display process executed in step S104 of FIG. 19 (game progress main process) will be described with reference to the flowchart shown in FIG. First, the main control unit 100 determines whether or not the value of the D2 bit setting key switch signal rising data is 1 among various data stored in the RWM address F00D (step S140). If the value of the setting key switch signal rising data is 1, the determination result is YES, and the blocker of the selector 80 is turned off (step S142). Specifically, this is a process of turning off the D7 bit of the address F01C of the RWM. Although the details will be described later, since the on / off state of the blocker is actually controlled by the port output processing (step S516 in FIG. 22) of the timer interrupt processing based on the data at the address F01C, the processing in step S142 is performed. Can be said to be a process for turning off the blocker.

  Next, the main control means 100 requests the sub-control means 200 to output a set value display start command (step S144). Specifically, 8FH is set in the D register and 5AH is set in the E register. Thereby, the main control means 100 generates a set value display start command (8F5A) based on the values set in the D register and the E register and stores it in the ring buffer area of the RWM (step S146). As for the stored set value display start command, the set value display start command is transmitted to the sub-control unit 200 by a timer interrupt process described later. Next, the main control unit 100 sets the value of the D4 bit among the values of the LED display request flag stored in the RWM address F013 to 1 so that the set value display 37 can be displayed (step S148). .

  Next, the main control means 100 determines whether the value of the falling data of the set key switch signal of the D0 bit is 1 among the various data stored in the FWM of the RWM address (step S150). If the value of the D0 bit is 0, the determination result is NO, and the process of step S150 is performed again. If the value of the D0 bit is 1, the determination result is YES, and the LED display request stored in the RWM address F013 is determined. Of the flag values, the value of the D4 bit is set to 0 (step S152). As a result, the current set value is continuously displayed on the set value display 87 until the key switch 82c is turned off.

  Next, the main control unit 100 requests the sub-control unit 200 to output a set value display end command (step S154). Specifically, 00H, which is the value of the second control command of the set value display end command, is set in the E register. As a result, the main control means 100 generates a set value display end command (8F00) based on the value of the D register set in step S144 and the value of the E register set in step S154, and generates an RWM ring. The data is stored in the buffer area (step S156), and the blocker of the selector 80 is turned on (step S158). As a result, a set value display end command is transmitted to the sub-control unit 200 by a timer interrupt process described later, and the medal insertion can be accepted.

  When the result of the determination in step S140 is NO or when the process in step S158 is completed, the main control means 100 determines whether or not to start the game standby display (step S160). That is, it is determined whether or not the values stored in the RWM addresses F02A and F02B are 0. If the value is 0, the determination result is YES; if not, the determination result is NO. If the decision result in the step S160 is YES, 0 is stored in the RWM address F011 to clear the acquired number data (step S162), and the process shifts to a game medal management process in the step S106 shown in FIG. On the other hand, if the decision result in the step S160 is NO, the process directly shifts to the step S106 in FIG.

<Description of error display processing>
Next, in the course of executing the game progress main process shown in FIG. 19, any of the recoverable errors (medal jam error, empty error, payout error, insertion sensor passing error, medal insertion error, medal retention error, The details of the error display processing executed when a throw-in sensor error, a medal passing error, or a medal full error is detected will be described with reference to the flowchart shown in FIG. When the main control means 100 detects a recoverable error during the execution of the game progress main process, the main control means 100 sets an error number (see FIG. 14) corresponding to the detected recoverable error in the A register, and then sets the error shown in FIG. Execute display processing.

  First, the main control means 100 stores the error number set in the A register in the RWM address F014 (step S200). Then, in order to save the states of the blocker signal and the hopper motor drive signal before the occurrence of the error, the value of F0H is set in the H register and 1CH is set in the L register. Then, the data stored in the RWM address (F01C) of the value set in the HL register is set in the C register (step S202). That is, the blocker signal and the hopper motor drive signal data stored in the RWM are saved (stored) in the C register. Next, the main control means 100 sets the value of the D7 bit (hopper motor drive signal) of the data stored in the RWM address (F01C) of the value set in the HL register to 0, and sets the hopper motor drive signal to 0. Turn off (step S204). Then, of the data stored in the RWM address (F01C), the value of the D6 bit (blocker signal) is set to 0, and the blocker of the selector 80 is turned off (step S206).

  Note that the processing of step S204 and step S206 can be performed in the same processing by clearing all data stored in F01C, for example. Further, in order to turn off the blocker signal and the hopper motor drive signal, information on these two signals is stored at the same address, thereby turning off the two information without changing the address information stored in the HL register. Can be updated.

  Next, the main control means 100 sets the value of the D0 bit (game start display LED) of the LED display data stored in the RWM address F015 to 0 (step S208). In other words, by setting the bit to 0, the game start display LED is turned off by the port output process of the timer interrupt process described later (step S516 in FIG. 22). Then, an output request for an error display start command corresponding to the detected error is made to the sub control means 200 (step S210). Specifically, 90H is set in the D register, and the value of the second control command (see FIG. 12) corresponding to the detected error is set in the E register. As a result, the main control means 100 generates an error display start command based on the values set in the D register and the E register and stores the command in the ring buffer area of the RWM (step S212).

  Next, the main control means 100 determines whether or not the value of the D1 bit setting / reset switch signal rising data among the various data stored in the FWM of the RWM address is 1 (step S214). If the value of the D1 bit is 0, the determination result is NO, and the process of step S214 is executed again. If the value of the D1 bit is 1, the determination result is YES, and the setting / reset switch signal stored in F00D is stored. The value of the rising data is set to 0 (step S216). Then, the main control means 100 sets the RWM address of the fullness detection signal inspection data and the input port 0 level data in the DE register (step S218). Specifically, 01000000B (the digit of "1" corresponds to the D6 bit of the RWM address F00A) is set in the D register as the fullness detection signal inspection data, and the lower 1 byte of the RWM address of the input port 0 level data is set. (0AH) is set in the E register.

  Next, the main control means 100 determines whether or not the recoverable error that has occurred is a medal full error (step S220). Specifically, the error number stored in the RWM address F014 is set in the A register, and the value of the A register is compared with a predetermined value 17H (23 in decimal; the error number of the medal full error) (subtraction processing). ). The value of the A register (the error number stored in the RWM address F014) is not updated by this comparison operation. Then, if the subtraction result becomes 0 (the zero flag is 1), the judgment result is YES as a medal full error has occurred. On the other hand, if the result of the subtraction is that the zero flag is 0, it is determined that a recoverable error other than the medal full error has occurred and the determination result is NO.

  If the decision result in the step S220 is NO, the main control means 100 sets the payout sensor inspection data and the RWM address of the input port 2 level data in the DE register (step S222). Specifically, 00011000B (the digit of “1” corresponds to the D4 and D3 bits of the RWM address F00C) is set in the D register as the payout sensor inspection data, and the lower 1 bit of the RWM address of the input port 2 level data is set. The byte value (0CH) is set in the E register. Next, the main control means 100 determines whether or not the generated recoverable error is an error related to payout of medals (error generated in the medal payout device 83) (step S224). Specifically, a comparison operation process (subtraction process) between the error number set in the A register and a predetermined value 0DH (decimal 13) is executed. As a result, if a carry occurs (the carry flag is set). 1), the judgment result is NO since an error relating to the insertion of medals (an error having an error number of "12" or less) has occurred. If the carry flag is 0 as a result of the subtraction, the determination result is YES.

  As described above, the type of error can be roughly classified based on the error number stored in the RWM address F014, and the offset value for displaying the error number on the acquired number display 28 is calculated. It becomes possible. Therefore, since the amount of data stored in the RWM is not increased, the storage area of the RWM can be reduced, and the process of storing data dedicated to each RWM can be omitted. Can be reduced.

  If the decision result in the step S224 is NO, the main control means 100 sets the insertion and the medal passage sensor inspection data in the D register (step S226). Specifically, a predetermined value of 110000B (the digit of "1" corresponds to the D7 to D5 bits of the RWM address F00C) is set in the D register as the insertion and medal path sensor inspection data.

  Next, the main control unit 100 checks the input state of each error based on various inspection data (step S228). Specifically, first, data is obtained from the RWM address where the value (F0H) of the Q register set in step S10 in FIG. 17 is an upper byte and the value set in the E register is a lower byte, and the A register Set to. Here, when a medal full error is detected, 0AH is set in the E register by the processing in step S218, so that the input port 0 level data is set in the A register. When an error other than the medal full error is detected, the value of 0CH is set in the E register by the processing in step S222, and therefore the input port 2 level data is set in the A register.

  Then, the main control means 100 determines whether or not the cause of the error has been removed (step S230). More specifically, an AND operation is performed on the value set in the A register and the value in the D register in step S228, and if the result is not 0 (the value of the zero flag is 0), the error factor is removed. No, the determination result is NO. When the AND operation result becomes 0 (the value of the zero flag is 1), the judgment result is YES because the error factor has been removed. Then, when the determination result is NO, the process returns to the determination process of step S214.

  Here, when a medal full error is detected, since the data in which the D6 bit is 1 is set in the D register by the processing of step S218, whether the value of the full detection signal is 0 is determined. Is determined. When an error relating to the medal payout device 83 is detected, since the data in which the D4 and D3 bits are 1 are set in the D register by the process of step S222, the payout sensor 1 signal and the payout sensor 2 are set. It is determined whether both signal values are 0. Further, when an error based on the insertion sensor and the medal passage sensor is detected, since the data in which the D7 to D5 bits are 1 are set in the D register by the process of step S226, the insertion sensor 1 signal, It is determined whether the values of the insertion sensor 2 signal and the medal path sensor are all 0.

  If the result of the determination in step S230 is YES, the main control means 100 stores 00H in the RWM address F014 and clears the error number (step S232). Then, as an output request of the error recovery command (8100) to the sub-control means 200, the value of 10H is set in the D register and the value of 00H is set in the E register (step S234). Then, an error recovery command is generated based on the values set in the D register and the E register, and stored in the ring buffer area of the RWM (step S236).

  Next, the main control means 100 returns the information indicating the state of the blocker signal and the hopper motor drive signal before the error detection (step S238). Specifically, first, the data (blocker signal and hopper motor drive signal data) stored in the RWM address F01C set (saved or stored) in the C register by the process of step S202 is set in the A register. Then, the same A register value is added to the A register value.

For example, if the hopper motor drive signal was on before the error was detected, the value of 10000000B has been set in the C register by the processing of step S202. Therefore, first, the result of the addition processing in the A register is
10000000B + 10000000B → 00000000B (carry flag = 1)
Becomes

On the other hand, if the blocker signal was on before the error was detected, the value of 01000000B has been set in the C register by the processing of step S202. Therefore, first, the result of the addition processing in the A register is
0100000B + 0100000B → 10000000B (carry flag = 0)
Becomes

  Next, the main control means 100 restores the hopper motor drive signal data stored in the RWM address F01C (step S240). Specifically, the following rotation processing is performed on the data (1 byte data composed of D0 to D7 bits) stored in the RWM address F01C. That is, the values of the D7 bit (most significant bit) to D1 bit of the data stored in the RWM address F01C are shifted by one digit lower bit, the carry flag value is shifted to the D7 bit, and the D0 bit ( The value of the least significant bit is shifted to the carry flag. Note that the value of the A register does not change due to this rotation processing.

As a result, if the hopper motor drive signal was on before the error was detected, the value of the carry flag has been set to 1 by the processing in step S238, and the data stored in the RWM address F01C is:
00000000B → 10000000B (carry flag = 0)
Becomes

On the other hand, if the blocker signal was turned on before the error was detected, the value of the carry flag has been set to 0 by the processing in step S238, so the data stored in the RWM address F01C is:
00000000B → 00000000B (carry flag = 0)
Becomes

  After performing the above processing, the main control means 100 determines whether or not the blocker signal before error detection was ON (step S242). This determination is made by adding the same value of the A register to the value of the A register. As a result, if the value of the carry flag becomes 1, the result is YES, and if the value of the carry flag becomes 0, the result of the determination is NO. Becomes

Here, if the hopper motor drive signal was on before the error was detected, since the value of the A register has become 00000000B by the processing of step S238,
00000000B + 00000000B → 00000000B (carry flag = 0)
, And the result of the determination in step S242 is NO.

On the other hand, when the blocker signal before the error detection is ON, since the value of the A register becomes 10000000B by the process of step S238,
10000000B + 10000000B → 00000000B (carry flag = 1)
, And the result of the determination in step S242 is YES.

  When the result of the determination in step S242 is YES, the main control means 100 sets the value of the D6 bit of the data stored in the RWM address F01C to 1 (step S244), and ends the error display processing of FIG. . If the result of the determination in step S242 is NO, the error display processing of FIG. 21 ends without performing step S244.

  In the conventional slot machine, if a recoverable error occurs, an error is issued if a predetermined error clearing operation (such as operating the setting / reset switch 82c or turning the keypad inserted into the door key 31 to the left) is performed. Cancellation had been performed. However, if an error is canceled by an illegal action and the error is immediately canceled, it may be difficult for staff members of the game arcade to discover the illegal action. Therefore, when a recoverable error occurs, it is desirable that the error is not immediately cleared even if the error clearing operation is performed.

  For example, the medal clogging error, the payout error, the insertion sensor passing error, the medal insertion error, the medal retention error, the insertion sensor error, and the medal passing error are more likely to occur due to wrongdoing than the empty error and the medal full error. Therefore, even if an error is reported when these errors occur, there is a possibility that an illegal action for canceling the error is performed and the error reporting is stopped. In addition, by preventing the error from being immediately released, for example, the person who committed the wrongdoing can be impatient that "the error cannot be released!", So that the wrongful act can be suppressed. For this reason, an operation for canceling the error is not enabled immediately after the error occurs.

  Specifically, when an error such as a medal clogging error, a payout error, an insertion sensor passing error, a medal insertion error, a medal retention error, an insertion sensor error, a medal passing error, or the like occurs, a predetermined time (for example, 5 seconds) elapses. Until the error, the error cannot be released even if the setting / reset switch 82c is operated. On the other hand, empty errors and medal full errors can be canceled without waiting for a predetermined time due to the fact that the loss due to wrongdoing is insignificant and the frequency of occurrence is high. Desirable for As described above, by changing the time until the error can be cleared depending on the content of the recoverable error, the convenience can be improved without impairing the countermeasures against fraud.

  Note that the types of errors that invalidate the error canceling operation for a predetermined time include all types of errors such as a medal clogging error, a payout error, an insertion sensor passing error, a medal insertion error, a medal retention error, an insertion sensor error, and a medal passing error. Good, some errors, and not limited to these. Furthermore, if the set / reset switch 82c is operated on the condition that a predetermined time has elapsed and the front door 14 is open, the error may be released, or the opening of the front door 14 may be performed. May not be included in the condition, and the error may be released when the setting / reset switch 82c is operated on the condition that a predetermined time has elapsed.

<Explanation of timer interrupt processing>
Next, with reference to FIG. 22, the contents of the timer interrupt processing executed at predetermined intervals in main control means 100 will be described. This timer interrupt processing is repeatedly executed at a period of about 2.235 milliseconds, and detects operation of each switch of the operation means 300 shown in FIG. 8, transmission of a control command to the sub-control means 200, external central terminal board 86, processing for generating and outputting control signals for controlling the driving of the stepping motors 42L, 42C, 42R, and updating the values of random numbers and various counter values used as timers.

  When an interrupt request signal (generation cycle: about 2.235 milliseconds) is output from the timer counting means (timer circuit) provided in the chip, the main control means 100 executes the timer interrupt processing shown in FIG. To start. Here, when the timer interrupt processing is executed, the return address of the processing executed in the main processing of the main control means 100 (general term for the setting change device processing in FIG. 18, the game progress main processing in FIG. 19, etc.) Is stored in the stack area. As a result, after the timer interrupt processing ends, the processing can be started from the continuation of the processing executed in the main processing based on the return address stored in the stack area. First, the main control unit 100 performs an initial process of a timer interrupt process to be executed (step S500). For example, data set in each register of the CPU is stored in the stack area of the RWM, and during a timer interrupt process to be performed, an interrupt disable flag is turned on so that a new timer interrupt process is not started. .

  Next, the main control means 100 determines whether or not a power-off (power-supply voltage falls below a predetermined value) is detected based on the power-off detection signal input to the input port 0 (step S502). . This power-off detection signal is output from a power-supply monitoring circuit (not shown) provided on the main control board. If the main control unit 100 detects that the power has been turned off, the determination result in step 502 becomes YES, and the power-off processing performed at the time of power-off is performed (step S504). In this power-off processing, the SP register is stored in a predetermined address of the RWM (for example, the above-mentioned temporary storage area of the stack pointer), the value of the power-off processing completion flag indicating that the power-off processing has been performed is set to 55H, and the RWM is set. The checksum of the predetermined address range (F000 to F3FF) is calculated, and a value (two's complement) based on the result is stored in a predetermined storage area of the RWM. Also, access to the RWM is prohibited, and the system enters a standby state for a reset signal input from the outside.

  On the other hand, if the power cut-off is not detected in the determination processing of step S502, the determination result is NO, and the LED for controlling the display of the credit number display 27, the acquired number display 28, and the set value display 87 is provided. A display control process is performed (step S506). Next, a timer measurement process for updating the count value of a timer that is generally used to measure a predetermined time is performed (step S508). In this timer measurement process, for example, the minimum game time (4.1 seconds) stored in the predetermined storage area of the RWM or the time detected by various sensors is subtracted. Here, as the detection time of the various sensors, a timer value for measuring the medal passing time for determining whether or not the medal inserted from the medal insertion slot 32 has stayed in the selector (medal clogging) or a medal is used. There is a medal passing time for determining whether or not the stadium stays in the hopper.

  Next, the main control means 100 performs input port 0 to 2 read processing for reading various signals from the outside input to the input ports 0 to 2 and storing them at predetermined addresses of the RWM (step S510). In order to control the rotation of the stepping motors 40C and 40R, a reel drive management process is performed for each of the stepping motors 42L, 42C and 42R (step S512). Then, when the reel drive management process is performed for all the stepping motors (step S514, YES), the main control unit 100 displays the display data of the various display devices and the respective stepping motors based on the data and the like stored in the RWM. Port output processing is performed to output control signals, blocker drive signals, hopper motor drive signals, and the like for the 42L, 42C, and 42R from the output ports (step S516).

  Next, the main control means 100 transmits the control command stored first in the control commands stored in the ring buffer area set in the RWM to the sub control means 200 (step S518). Then, after performing external signal output processing for outputting various signals to be output to the outside via the external centralized terminal board 86 (step S520), the signal is stored in a predetermined address (stack area) of the RWM by the initial processing of step S500. A return process for restoring the values and the like of the various registers to the original state is performed (step S522), and the timer interrupt process of FIG. 22 ends.

<Description of LED display control processing>
Next, the details of the LED display control process executed in step S508 of the timer interrupt process shown in FIG. 22 will be described with reference to the flowchart shown in FIG.

  First, the main control means 100 designates a 7-segment display (one of the upper digit and lower digit of the credit number display 27, the upper digit and lower digit of the acquired number display 27, and the set value display 87) for display. Then, the output port for outputting the data for performing the operation and the data for instructing the light-on / light-off for each of the specified segments a to g of the 7-segment display is turned off (step S540). Next, the main control means 100 updates the value of the LED display counter (step S542). Specifically, the value of the RWM address (F012) in which the value of the LED display counter is stored in the HL register is set, and the 8-bit value stored in the RWM address F012 is shifted to the lower digit side. . By this processing, if the value stored in the RWM is 10H, it is updated to 08H, if it is 08H, it is updated to 04H, if it is 04H, it is updated to 02H, and if it is 02H, it is updated to 01H. If it is 01H, it is updated to 00H. Here, when updated to 00H, the value of the zero flag becomes 1.

  Next, the main control means 100 determines whether or not the value of the LED display counter has become 0 (step S544). Here, as a result of the processing in step S542, the determination result is YES when the value of the zero flag becomes 1, and the determination result becomes NO when the value of the zero flag does not become 1. If the decision result in the step S544 is YES, the value of the LED display counter stored in the RWM address F012 is initialized (that is, updated to 10H) (step S546). Thus, the value of the LED display counter changes cyclically in the order of 10H → 08H → 04H → 02H → 01H → 10H →... Every time the timer interrupt processing is performed.

  Next, the main control means 100 acquires the value of the LED display counter and the value of the LED display request flag (step S548). Specifically, the data stored in the RWM address F013 is set in the A register, and the data stored in the RWM address F012 is set in the E register. Further, the value (F014) of the RWM address in which the error number is stored in the HL register is set. Then, the confirmation result of the segment display request of the 7-segment display (digit) to be displayed this time is set in the D register (step S550). Specifically, an AND operation is performed on the value of the A register and the value of the E register, and the operation result is set in the D register. As a result, the value of the A register is in a displayable state, and the value of the bit corresponding to the 7-segment display specified by the value of the LED display counter becomes 1.

  Next, the main control means 100 determines whether or not there is a display request for the 7-segment display (step S552). Specifically, as a result of the processing in step S550, if the value of the A register is 0 (zero flag = 1), the determination result is NO, and if the value of the A register is other than 0 (zero flag = 0). Is YES. If the decision result in the step S552 is YES, an error number is read from the RWM address of the value (F014) set in the HL register in step S548, and the error number is set in the A register (step S554). Is set in the B register (step S556). Here, the data set in the B register is used as error display data.

  Next, the main control means 100 sets the head address (1216H) of the second table (see FIG. 16B) of the LED segment table stored in the ROM in the HL register (step S558). Then, the setting value data stored in the RWM address F000 is read out and set in the A register (step S560), and 1 is added to the value of the A register to generate the setting value display data (step S562). Here, the set value display data generated by the process of step S562 is used as an offset value for the second table of the LED segment table. The process of step S562 is a process for displaying “1” to “6” on the set value display 87 while the set value data stored in the RWM address F000 is 0 to 5. . Therefore, when the setting value data stored in the RWM address F000 is stored as 1 to 6, this processing is unnecessary.

  Next, the main control means 100 determines whether or not there is a display request for the set value display 87 (step S564). Specifically, among the values set in the D register in step S550, the value of the D4 bit is 1 (there is a request to display the setting value display 87, and the value is designated as a 7-segment display for displaying. ), The decision result is YES, and if the D4 bit value of the D register is 0, the decision result is NO. If the decision result in the step S564 is NO, the stored number data stored in the RWM address F010 is set in the A register (step S566).

  Then, based on the value set in the A register, the offset value for acquiring the segment data to be displayed in the upper digit of the credit amount indicator 27 is acquired (step S568). More specifically, the value set in the A register in step S566 is divided by 0AH (10 in decimal), the quotient value is set in the A register, and the remainder value is set in the C register. Here, as described above, the value of the quotient set in the A register is an offset value for acquiring the segment data displayed in the upper digit, and the remaining value acquires the segment data displayed in the lower digit. Offset value.

  Next, the main control means 100 determines whether or not there is a display request for the upper digit of the credit amount display 27 (step S570). Specifically, among the values set in the D register in step S550, the value of the D0 bit is 1 (there is a request to display the upper digit of the credit number display 27, and the value is designated as the 7-segment display for displaying. Is determined), the determination result is YES, and if the value of the D0 bit of the D register is 0, the determination result is NO. If the decision result in the step S570 is NO, it is next decided whether or not there is a display request for the lower digit of the credit amount display 27 (step S572). Specifically, among the values set in the D register in step S550, the value of the D1 bit is 1 (the lower digit of the credit number display 27 is requested to be displayed, and the 7-segment display for displaying is designated. If the value of the D1 bit of the D register is 0, the determination result is NO.

  If the decision result in the step S572 is NO, the acquired number data stored in the RWM address F011 is set in the A register (step S574), and it is determined whether or not an error display should be performed (step S574). Step S576). More specifically, it is determined whether or not the value of the error number set in the B register is 0 in step S556. If the error number is 0, the determination result in step S576 is NO. The result of the determination in step S576 is YES. When the determination result is YES, the start address (1211H) of the first table (see FIG. 16A) of the LED segment table stored in the ROM is set in the HL register, and the value of the B register is set to A. It is set in a register (step S578).

  If the decision result in the step S576 is NO, or if the process in the step S578 is performed, the main control means 100 next displays the upper digit of the acquired number display 28 based on the value set in the A register. An offset value for obtaining segment data to be obtained is obtained (step S580). Here, the value of the acquired number data is set in the A register by the processing of step S574 when the error display is not performed, and the value of the error number is set by the processing of step S578 when the error display is performed. Then, the value set in the A register is divided by 0AH (decimal 10), the quotient value is set in the A register, and the remaining value is set in the C register. Here, as described above, the value of the quotient set in the A register is an offset value for acquiring the segment data displayed in the upper digit, and the remaining value acquires the segment data displayed in the lower digit. Offset value.

  Next, the main control means 100 determines whether or not there is a display request for the upper digit of the acquired number display 28 (step S582). Specifically, of the values set in the D register in step S550, the value of the D2 bit is 1 (the upper digit of the acquired number display 28 is requested to be displayed, and the display is designated as the 7-segment display for displaying. Is determined), the determination result is YES, and if the value of the D2 bit of the D register is 0, the determination result is NO. If the decision result in the step S582 is NO, or if the decision result in the step S572 is NO, the segment data to be displayed in the lower digit of the credit number display 27 or the acquired number display 28 is obtained. An offset value is obtained (Step S584). Specifically, the value set in the C register is set in the A register.

  As a result, if the process of step S584 is performed when the determination result of step S572 is NO, the remainder value obtained by dividing the value of the stored number data by "10" is set in the A register. If the result of the determination in step S582 is NO, the process in step S584 is performed, and the remaining value obtained by dividing the stored number data or the value of the error number by "10" is set in the A register. .

  Next, the main control means 100 reads the segment data from the LED segment table stored at the ROM address indicated by the sum of the value of the HL register and the value of the A register, and sets the segment data in the D register (step S586). . Here, if the decision result in the step S576 is YES, the start address value of the first table of the LED segment table is set in the HL register, otherwise, the start address value of the second table is set to HL in step S558. Set in a register. The value set in the A register immediately before step S586 is added to the value of the HL register, and the segment data is obtained from the ROM address specified by the added value.

  Next, the main control means 100 outputs the segment data set in the D register to the 7-segment display specified by the value of the LED display counter set in the E register in step S548, The designated 7-segment display is displayed (step S588). Then, the LED display processing in FIG. 23 ends, and the flow shifts to step S508 in FIG.

<Description of input port 0-2 read processing>
Next, the contents of the input port 0 to 2 read processing executed in step S510 of the timer interrupt processing shown in FIG. 22 will be described in detail with reference to the flowchart shown in FIG.

  First, the main control means 100 performs input processing of data input to the input port 0 (step S600). Specifically, the data of F00AH is set in the HL register, the value of the input port 0 level data is read from the RWM address indicated by the value of the HL register, and set in the B register. Here, the value of the input port 0 level data read from the RWM is the input port 0 level data saved by the previous timer interrupt processing. Further, it accesses the input port 0, reads the data input to the input port 0 at that time, and sets it in the A register.

  Next, the main control means 100 converts a signal input to the input port 0 with negative logic into positive logic (step S602). Here, since the signal input to the input port 0 with negative logic is the 0th bit (least significant bit), the 5th bit, and the 6th bit (see FIG. 11A), the signal is set in the A register. An XOR operation of the obtained value and a predetermined value 01100001B is performed, and the operation result is set in the A register. Then, in order to invalidate the value of the bit not used in the input port 0, an AND operation is performed on the value of the A register and the predetermined value 01100111B, and the operation result is set in the A register (step S604).

  Next, the main control means 100 stores the value of the A register as input port 0 level data in the RWM address of the value (F00A) of the HL register set in step S600 (step S606). Then, it is determined whether or not the value of the D2 bit (door switch signal) among the values of the A register is 1 (the front door 14 is open) (step S608). If the value of the D2 bit is 0 (the front door 14 is closed), the determination result is NO, and the previous input port 0 level data set in the B register in step S600 is set in the A register ( Step S610).

  Next, the main control unit 100 generates change bit data of the setting key switch signal and the setting / reset button signal (step S612). More specifically, data indicating whether the on / off state of the setting key switch signal and the setting / reset button signal input to input port 0 has changed from the on / off state in the previous timer interrupt processing is generated. . Specifically, an XOR operation is performed on the value set in the A register and the value set in the B register, and an AND operation is performed on the operation result and a predetermined value 00000011B to obtain the values of the D0 and D1 bits. Is extracted and set in the A register. Further, the value set in the A register is also set in the D register.

  With this, if the value of the D0 bit or the D1 bit is 1 in the data set in the A register and the D register, the value of the signal (setting key switch signal or setting / reset button signal) corresponding to that bit is set to the previous value. Indicates that the timer interrupt processing has changed. On the other hand, when it is 0, it indicates that the value of the signal corresponding to that bit has not changed from the previous timer interrupt processing.

  If the front door 14 is open (step S608, YES), the level data of the input port 0 in the previous timer interrupt processing is set in the B register in step S600. Therefore, the value of the A register indicates whether or not the value of the setting key switch signal and the value of the setting / reset button signal have changed from the values in the previous timer interrupt process by the process of step S610.

  On the other hand, if the front door 14 is closed (step S608, NO), the same value as the A register is set in the B register by the process of step S610, so that the process of step S610 is performed. The value of the A register always becomes 0, forcing that the values of the setting key switch signal and the setting / reset button signal have not changed from the values in the previous timer interrupt processing.

  After performing the processing in step S612, the main control unit 100 generates rising data of the setting key switch signal and the setting / reset button signal (step S614). Specifically, an AND operation is performed on the data set in the A register and the data stored in the RWM address F00A specified by the value set in the HL register in step S600. Here, the data stored in the RWM address F00A has been updated to the level data of the input port 0 acquired in the current timer interrupt processing by the processing in step S606. Therefore, the fact that the value of the signal acquired in the current timer interrupt processing is 1 and the value of the change bit data is 1 means that the value of the signal has changed from 0 to 1 (rising). I do. Thus, the rising data of the setting key switch signal and the setting / reset button signal can be obtained by the AND operation in step S614. However, when the determination result in step S608 is NO, the rising bit data does not become 1 because the change bit data always becomes 0 in step S612.

  Further, the main control means 100 shifts the value of each bit set in the A register by one digit to the upper digit side, shifts the rising data of the setting key switch signal in the D1 bit to D2 bits, and shifts the setting data in the D0 bit. / The rising data of the reset button signal is shifted to D1 bit. Then, the result is set in the E register.

  Next, the main control means 100 generates setting key falling data (step S616). Specifically, the data set in the B register in step S600 (input port 0 level data at the time of the previous timer interrupt processing) is set in the A register, and the change bit data set in the D register in step S612. And an AND operation, and the result is set in the A register. That is, the fact that the value of the signal obtained in the previous timer interrupt process is 1 and the value of the change bit data is 1 means that the value of the signal has changed from 1 to 0 (falling). means. Thus, by performing an AND operation in step S614, falling data of the setting key switch signal and the setting / reset button signal can be obtained. However, if the result of the determination in step S608 is NO, the changing bit data always becomes 0 in step S612, so that the falling data does not become 1.

  Further, the main control means 100 shifts the value of each bit set in the A register by one digit toward the lower digit, and shifts the falling data of the set key switch signal in the D1 bit to the D0 bit.

  Next, the main control means 100 stores the setting key and the setting / reset button edge data in the RWM (step S618). Specifically, a logical sum (OR) operation of the value of the falling data of the setting key switch signal in the A register and the value set in the E register in step S614 is performed. As a result, in the value of the A register, the D2 bit is the rising data of the setting key switch signal, the D1 bit is the rising data of the setting / reset button signal, and the D0 bit is the falling data of the setting key switch signal. Then, in step S600, the value of the A register is stored in the RWM address (F00D) specified by adding 3 to the value (F00A) set in the HL register. Here, the value (F00A) set in the HL register is only referred to, and the value is maintained.

  Next, the main control unit 100 reads the data input to the input port 1 at that time and sets the data in the A register (step S620). Then, the input port 1 negative logic bit data is set in the D register, and all the input port 1 bit data is set in the E register (step S622). Here, the input port 1 negative logic bit data represents a bit of a signal input to the input port 1 in negative logic by 1, and its value is 01110000B (see FIG. 11B). . In addition, the input port 1 all-bit data represents a bit to which a signal is input as 1, and its value is 01111111B.

  Next, the main control means 100 performs an input port data set process of storing the level data of each signal input to the input port 1 or 2 and the rising data thereof in the RWM (step S624). This input port data set processing will be described later in detail with reference to FIG.

  Next, the data input to the input port 2 at that time is read and set in the A register (step S626). Then, the input port 2 negative logic bit data is set in the D register, and all the input port 2 bit data is set in the E register (step S628). Here, the input port 2 negative logic bit data represents a bit of a signal which is input to the input port 2 in negative logic by 1, and its value becomes 1110000B (see FIG. 11C). . In addition, the input port 1 all-bit data represents a bit to which a signal is input as 1, and its value is 11111111B.

  When the processing of step S628 is completed, the input port 0 to 2 read processing of FIG. 24 is completed, and the process proceeds to the input port data set processing shown in FIG.

<Description of input port data set processing>
Next, with reference to the flowchart shown in FIG. 25, the details of step S624 of the input port 0 to 2 read processing shown in FIG. 24 and the input port data set processing performed after the input port 0 to 2 read processing will be described in detail.

  First, the main control means 100 sets the value of the RWM address where the level data of the input port 1 or the input port 2 is stored in the HL register (step S650). Specifically, 1 is added to the value of the HL register. As a result, when the input port data set process of FIG. 25 is executed in step S624 of FIG. 24, the value of the HL register is set to F00A by the process of step S600 of FIG. The value of the HL register is F00B, and the RWM address of the input port 1 level data is specified. When the input port data set process of FIG. 25 is executed after the input port 0 to 2 read process of FIG. 24 is completed, 1 is added because the value of the HL register is F00B by the above process. Then, the value of the HL register becomes F00C, and the RWM address of the input port 2 level data is specified.

  Next, the main control means 100 reads out the level data stored in the RWM address of the value set in the HL register in step S650 and converts it into positive logic data (step S652). Specifically, the level data (the level data stored in the previous timer interrupt processing) stored in the RWM address of the value set in the HL register is read and set in the B register, and the value of the B register is read. , And an AND operation with the value (negative logic bit data) set in the D register, and the operation result is set in the A register.

  Here, when executing the input port data setting process of FIG. 25 in step S624 of FIG. 24, the input port 1 negative logic bit data is set in the D register by the process of step S622 of FIG. When the input port data set processing of FIG. 25 is executed after the input port 0-2 read processing of FIG. Is set.

  Next, the main control means 100 invalidates unused bits in the level data converted into positive logic set in the A register (step S654). Specifically, an AND operation is performed on the value of the A register and the value (all bit data) set in the E register, and the operation result is set in the A register.

  Here, when the input port data set processing of FIG. 25 is executed in step S624 of FIG. 24, the input port 1 input port 1 all bit data is set in the E register by the processing of step S622 of FIG. When the input port data set processing of FIG. 25 is executed after the input port 0-2 read processing of FIG. 24 is completed, all the bit data of the input port 2 is set in the D register by the processing of step S628 of FIG. Have been.

  Next, the main control means 100 stores the level data set in the A register in the RWM address indicated by the value of the HL register (step S656). By performing this processing, the level data of the input port 1 or the input port 2 stored in the RWM is updated. Here, as described above, when the input port data set processing of FIG. 25 is executed in step S624 of FIG. 24, the value of the HL register is F00B, and the input port 0 to 2 read processing of FIG. When executing the input port data set processing of FIG. 25 after the end, the value of the HL register is F00C.

  Next, the main control means 100 generates changed bit data indicating bits whose values have changed based on the level data stored in the previous timer interrupt processing and the level data stored in the current timer interrupt processing. (Step S658). Specifically, an XOR operation is performed on the value of the B register (the level data stored in the previous timer interrupt processing) and the value of the A register (the level data stored in the current timer interrupt processing), The result of the operation is set in the A register.

  Next, the main control means 100 generates rising data of each signal acquired from the input port (step S660). Specifically, an AND operation is performed on the change bit data set in the A register and the updated level data stored in the RWM address of the value set in the HL address, and the result of the AND operation is expressed as A Set in a register. By this process, the signal corresponding to the bit whose value is 1 has changed from 0 to 1 (rising). Then, the value of the A register is stored in the RWM address specified by the value obtained by adding 3 to the value set in the HL register in step S650. Here, the value set in the HL register in step S650 is only referred to, and the value is maintained.

When the processing of step S650 is completed, the main control means 100 returns to the processing executed before performing the input port data setting processing of FIG. That is, when the input port data set processing of FIG. 25 has been executed in step S624 of FIG. 24, the processing shifts to the processing of step S626 of FIG. When the input port data set process of FIG. 25 is to be executed after the input port 0 to 2 read process of FIG. 24 has been completed, the process proceeds to the reel drive management process of step S512 in the timer interrupt process of FIG.

  As described above, in the first embodiment, the rising data of the key switch 82b and the setting / reset switch 82c and the falling data of the key switch 82b are generated in the timer interrupt processing (steps S614 and S614 in FIG. 24). See S616). If the front door 14 is closed, the change bit data of the signals corresponding to these switches is forcibly set to 0 (no change) (steps S608 → S610 → S612 in FIG. 24). Thus, even when the key switch 82b and the setting / reset switch 82c are operated, when the front door 14 is closed, the rising data and the falling data are not generated. Therefore, when the front door 14 is closed, the set values are changed after the power is turned on (steps S72 and S74 in FIG. 18), the setting change mode ends (step S86 in FIG. 18), and the set values are confirmed during the game (step S86 in FIG. 18). 20 (NO in step S140 in FIG. 20), and canceling during error occurrence (step S214 in FIG. 21) cannot be performed.

<< Description of control processing in sub-control means >>
Next, the contents of various processes executed by the sub-control unit 200 will be described. First, when the power of the slot machine 10 is turned on, the sub-control means 200 executes a sub-power-on process shown in FIG.

<Description of sub-power-on process>
First, during execution of the sub-power-on process, the sub-control unit 200 performs a process of prohibiting execution of the timer interrupt process by the sub-control unit 200 (step Ss10), and then calculates a checksum of the RWM. A comparison is made with the calculation result of the RWM checksum calculated at the time of power-off and stored in the non-volatile memory, and it is determined whether or not both match (step Ss12). If the two checksum values do not match, the determination result is NO, and the sub-control unit 200 clears the stored contents of the RWM incorporated in the sub-control unit 200 (step Ss14).

  If the two checksum values match in the determination process of step Ss12, the determination result is YES, and the sub-control unit 200 determines whether or not the previous power-off occurred during one-command processing described later. Is determined (step Ss16). Here, if the power supply is interrupted during the execution of the one-command processing described later, the sub-control unit 200 restarts the processing performed at the time of the power supply interruption when the power is turned on again. A process of saving various information (data indicating the states of the registers and various flags of the CPU) in the non-volatile memory at that time is performed (power cutoff process).

  When the power is turned off, the sub-control unit 200 stores a power-off processing flag indicating whether or not the above-described power-off processing has been performed in the nonvolatile memory. Here, when the power interruption processing flag is on, it indicates that the above-described power interruption processing has been performed (that is, power interruption has occurred during the processing of one command), and when the power interruption processing flag is off, , Indicates that the power-off processing was not performed (that is, no power-off occurred during the processing of one command). The determination process shown in step Ss16 is performed based on the on / off state of the power interruption processing flag stored in the nonvolatile memory. If the power supply has been interrupted during the processing of one command, the determination result is YES, and the execution of the timer interrupt processing in the sub control means 200 is permitted in step Ss10 (step Ss18), and the processing is executed when the power is cut off. The processing shifts to

  If the stored contents of the RWM in the sub-control means 200 are cleared by the processing of the above-described step Ss14, or if the determination result of the step Ss16 is NO (the previous power-off did not occur during the processing of one command) After clearing the value of the watchdog timer (step Ss20), the operation of the watchdog timer is started (step Ss22). This watchdog timer is for notifying that an abnormality has occurred when the time required for processing in steps Ss24 to S28 described later exceeds 100 milliseconds. When the watchdog timer determines that an abnormality has occurred, the sub-control unit 200 may execute an initialization process.

  Next, the sub-control unit 200 permits the execution of the timer interrupt process prohibited in step Ss10 (step Ss24), reads the control command received from the main control unit 100 from the command buffer, and executes the process (1) based on the control command. Command processing) (step Ss26). Then, it is determined whether or not 16 milliseconds have elapsed between the processing of steps Ss20 to Ss28 (step Ss28). If it is determined that 16 milliseconds have not elapsed (NO), the process returns to step Ss26 to read out the control commands stored in the command buffer, and perform one-command processing based on the control commands. Then, the one command process of step Ss26 is repeated until 16 milliseconds elapse, and when 16 milliseconds elapse, the determination result of step Ss28 becomes YES and the process returns to step Ss20.

  In this manner, the sub-control unit 200 performs the effect control process based on the control command transmitted from the main control unit 100 by repeatedly executing the above-described sub-main routine process.

<Description of one command processing>
Next, the content of one command process in step Ss26 of FIG. 26 will be described with reference to the flowchart shown in FIG. The one-command processing shown in FIG. 27 indicates a setting change device operation start command (8038) and a setting change device operation end command (80 ##: ## indicates setting value data (0 to 5)) from the main control unit 100. ), When a set value designation command (82 ##: ## indicates set value data (0 to 5)), a set value display start command (8F5A), and a set value display end command (8F00) are received. It shows a process to be executed.

  When one-command processing is started in step Ss26 of FIG. 26, the sub-control unit 200 determines the type of the control command received from the main control unit 100 in the flowchart shown in FIG. 27 (step Ss100). If the received control command is a setting change device operation start command, the result of the determination in step Ss100 is YES, and a screen indicating that the setting value is being changed is displayed on the image display device 70 (step Ss102). ). After shifting to the effect setting mode described later (step Ss114), the one-command processing of FIG. 27 ends.

  When the sub control means 200 determines that the setting change device operation start command has not been received in the determination process of step Ss100, the determination result is NO, and it is determined whether the next setting change device operation end command has been received. A determination is made (step Ss104). When the setting change device operation end command is received, the determination result of step Ss104 is YES, and the game standby display is started (step Ss106). Then, the effect setting mode shifted in the process of step Ss114 ends (step Ss118), and the one command process of FIG. 27 ends. The game standby display is a display of a so-called “demo screen”, and displays a manufacturer name of the slot machine 10, a moving image in which a character used for producing a game appears, and the like.

  When the sub-control means 200 receives the setting change device operation end command, a normal effect image (normal display image) displayed during the game is displayed instead of the game standby display (so-called “demo screen”). You may. This normal display image is different from a so-called cut-in image or an image that suggests a winning combination or inspires a player's expectation, which is caused by the operation of the start switch 36 and the stop switches 37L, 37C, and 37R. , An effect image displayed in a default state, such as an image of a scene in which a character is simply walking. In this case, when the setting change device operation end command is received, the display of the normal display image is started, and when the operation related to the game by the player has not been performed for a predetermined time (for example, one minute), the game standby display is started. Become.

  When the sub control means 200 determines in the determination processing of step Ss104 that the setting change device operation end command has not been received, the determination result is NO, and it is determined whether the next setting value designation command has been received. (Step Ss108). When the setting value designation command is received, the determination result is YES, and the value of the second control command of the received setting value designation command (that is, the setting value data) is stored in a predetermined storage area of the RWM (step Ss110). , The one-command processing of FIG. 27 ends.

  When the sub-control unit 200 determines that the set value designation command has not been received in the determination processing of step Ss108, the determination result is NO, and it is determined whether the set value display start command has been received next ( Step Ss112). When the set value display start command is received, the process proceeds to step Ss114 to shift to the effect setting mode described later, and then the one command process in FIG. 27 ends. Also, in the determination process of step Ss112, when the sub-control unit 200 determines that the set value display start command has not been received, the determination result is NO, and it is determined whether the next set value display end command has been received. A determination is made (step Ss116). When the set value display end command is received, the process proceeds to step Ss118, the above-described game standby display is performed on the image display device 70, and after the effect setting mode shifted in the process of step Ss114 is ended, one command of FIG. The process ends.

  Here, when the set value display end command is received, the above-described normal display image may be displayed instead of the game standby display (so-called “demo screen”). In this case, when the set value display end command is received, the display of the normal display image is started, and when the operation related to the game by the player has not been performed for a predetermined time (for example, one minute), the game standby display is started. . Also, when the set value display end command is received, the effect that was executed when the set value display start command was received or the effect related to the effect that was executed when the set value display start command was received. You may return.

  When the sub-control unit 200 determines that the set value designation command has not been received in the determination processing of step Ss116, the determination result is NO, and it is determined whether another control command has been received next (step Ss116). Ss120). When any control command is received from the main control unit 100, processing based on the received control command is performed (step Ss122), and the one-command processing of FIG. 27 ends. If the control command has not been received from the main control unit 100 in the determination process of step Ss120, the determination result is NO, and the one-command process of FIG. 27 ends.

  In the above-described one-command processing, the mode shifts to the effect setting mode when the setting change device operation start command and the setting value display start command are received, but only when the setting change device operation start command is received. It may shift to. Further, since the setting change mode can be shifted immediately after the power of the slot machine 10 is turned on, it is necessary to perform an initialization process in the sub-control means 200. It may be possible not to shift to the effect setting mode but to shift to the effect setting mode only when the set value display start command is received. In this case, when the sub-control means 200 receives the setting change device operation start command, a start message indicating that the device is being started is displayed on the image display device 70 and the initialization process is started. May be deleted and the image display device 70 may be set to a non-display state.

  Also, for example, in an image data storage unit (for example, a VRAM) for temporarily storing image data of a moving image to be displayed on the image display device 70, a first storage area for storing image data for effects to be displayed during a game; A second storage area for storing image data to be displayed during the effect setting mode is provided, and during the game, the image data held in the first storage area is output to the image display device 70, and during the effect setting mode May output the image data held in the second storage area to the image display device 70. Also, during the effect setting mode, the data of the normal display image described above is stored in the first storage area, and the normal display image is not displayed on the image display device 70, but the image data for that is displayed at any time as in the case of display. Update it. When receiving the set value display end command, the image data output to the image display device 70 is switched from the second storage area to the image data stored in the first storage area, and immediately switched to the normal display image. You may do so.

<Explanation of production setting mode>
Next, with reference to FIG. 28 to FIG. 36, the contents of the effect setting mode to be shifted by the process of step Ss114 in FIG. 27 will be described. In the effect setting mode, the user of the slot machine 10 (for example, an administrator of the slot machine) can set various parameters relating to the effect performed by the sub-control unit 200 and display a history of games and errors that have occurred. Mode. Note that the content set in the effect setting mode is returned to an initial value (for example, a factory default setting value) even when the setting value is changed (when a setting change device operation start command is received) ( Will not be cleared).

(System menu screen)
When the process shifts to the effect setting mode by the process of step Ss114 in FIG. 27, the sub-control unit 200 displays the system menu screen shown in FIG. Items that can be executed in the effect setting mode are listed on the system menu screen. Specifically, seven items of "volume adjustment", "game standby lamp color", "side lamp test", "game data display", "user volume adjustment", "error etc. history", and "power saving setting" are included. is there.

  Here, “volume adjustment” is an item for adjusting the volume of the effect sound generated during the effect. The “game standby lamp color” is an item for selecting the emission color of the decorative lamps 74L and 74R that emit light during the game standby display. The “side lamp test” is an item for performing a test of a predetermined blinking pattern of the side lamps 52L and 52R. "Game data display" is an item for selecting whether or not to display data relating to a game to a player. "User volume adjustment" is an item for selecting whether or not to allow the player to adjust the volume of the effect sound. The “error history” is an item for displaying a history of errors detected by the main control unit 100 on the image display device 70. “Power saving setting” is an item for selecting whether or not to perform an effect with reduced power consumption.

  By operating the selection switch 38 among the seven item names displayed on the system menu screen, a desired item name can be selected. That is, in the initial state of the system menu screen, the item name of “volume adjustment” is displayed in white characters, and by operating the selection switch 38, the item displayed in white characters is displayed. Can be moved. For example, on the system menu screen shown in FIG. 28, "volume adjustment" is in a selected state, and when the upper switch of the selection switch 38 is operated in this state, the item name of "game data display" is outlined in white. Will be displayed. When the lower switch of the selection switch 38 is operated in a state where “volume adjustment” is selected, the item name of “game standby lamp color” is displayed in white characters, and the right switch or the left switch of the selection switch 38 is displayed. Is operated, the item name of "user volume adjustment" is displayed in white characters.

  As described above, when the determination switch 39 is operated in a state where the desired item name is displayed in white characters, the system menu screen displayed on the image display device 70 is changed to the item name displayed in white characters. The screen changes to the screen corresponding to. Hereinafter, the contents of the screen which is switched when each of the seven items displayed on the system menu screen is selected will be described.

(Volume adjustment screen)
When the determination switch 39 is operated while the item name of "volume adjustment" is displayed in white characters on the system menu screen, the display of the image display device 72 switches to the volume adjustment screen shown in FIG. The volume adjustment screen is a screen for adjusting the volume of the effect sound generated during the game. In the volume adjustment screen shown in FIG. 29, a level meter LV is displayed at the center of the screen, and a desired volume is set by operating a right switch or a left switch of the selection switch 38. In the level meter LV of FIG. 29, eight levels of volume can be set, and FIG. 29 shows a state where the fifth level of the level meter LV is set (see a hatched portion).

  When adjusting the volume, the area of hatching increases to the right (the area painted black decreases) each time the right switch of the selection switch 38 is operated, and the volume increases. Each time the left switch of the selection switch 38 is operated, the hatched area decreases to the left (the area painted black increases), and the volume decreases. When the right switch of the selection switch 38 is kept pressed, the hatched area of the level meter LV gradually increases, and when the left switch of the selection switch 38 is kept pressed, the hatched area gradually decreases. May be configured. In FIG. 29, an inverted triangular power saving volume mark EM with the character “eco” and a triangular standard volume mark SM with the character “standard” are displayed for reference to a person who adjusts the volume. Mark. The standard volume mark SM is displayed at the fifth stage of the level meter LV, and when this volume is set, the produced sound is the standard volume recommended by the manufacturer. Further, the power saving volume mark EM is displayed at the third stage of the level meter LV. When the volume is set to this volume, the volume of the produced sound is lower than the standard volume, Power can be reduced.

  When the determination switch 39 is operated while the volume adjustment screen of FIG. 29 is displayed, the volume of the effect sound is determined to the volume set at that time, and the sub control unit 200 The display on the display device 70 is switched to the system menu screen shown in FIG.

(Game standby lamp color screen)
When the enter switch 39 is operated while the item name of “game standby lamp color” is displayed in outlined characters on the system menu screen, the display of the image display device 72 changes to the game standby lamp color shown in FIG. Switch to the screen. On the game standby lamp color screen, eight pattern selection displays PB of “pattern 1” to “pattern 8” for specifying the emission colors of the decorative lamps 74L and 74R are displayed. Then, the user operates the selection switch 38 to select one of the pattern selection displays PB. Here, the selected pattern selection display PB is displayed in white characters, and indicates that the pattern selection display PB of “pattern 1” is selected on the game standby lamp color screen of FIG. 30, for example. .

  Then, when the determination switch 39 is operated while the desired pattern selection display PB is selected, the emission colors of the decorative lamps 74L and 74R when performing the game standby display are determined, and the sub control means 200 displays the image. The display on the display device 70 is switched to the system menu screen shown in FIG.

Providing such setting items has the following advantages, for example.
(1) A gaming machine may be manufactured and sold with the same performance (so-called specifications) and performance as a gaming machine, but with different panels (for example, lower panel). The decorative lamp can be made to match the color of the panel. . For example, there are a first gaming machine and a second gaming machine having the same specifications and effects. The first gaming machine mainly adopts a red panel design, and the second gaming machine has a blue panel design. Let's say that they are proactively adopting In this case, the color of the decorative lamp of the first gaming machine is set to, for example, red, and the color of the decorative lamp of the second gaming machine is set to, for example, blue. Looks better. Therefore, in order to make the decorative lamp emit light in a color corresponding to the color of the panel, rather than creating a different program for each gaming machine, the decorative lamp can be made to emit light in a plurality of colors. Developing a program in which colors can be selected can reduce the burden of development costs.

(2) When installed side by side in a game arcade, a colorful mode can be achieved. For example, in a case where six identical gaming machines are installed in a line in a gaming arcade, when the gaming arcade is opened, a game standby display is performed on all six gaming machines. In such a case, a bright atmosphere can be given to the player by alternately setting the decorative lamps of the gaming machine to different emission colors (for example, red and blue).

(Side lamp test screen)
When the enter switch 39 is operated while the item name of “side lamp test” is displayed in outline characters on the system menu screen, the display of the image display device 72 is displayed on the side lamp test screen shown in FIG. Switch. On the side lamp test screen, a pattern selection display PB of “pattern 1” to “pattern 8” corresponding to blinking patterns (test patterns) of different side lamps 52L and 52R is displayed. Then, the user operates the selection switch 38 to select one of the pattern selection displays PB. Here, the selected pattern selection display PB is displayed in white characters, and for example, on the side lamp test screen of FIG. 31, it indicates that the pattern selection display PB of “Pattern 1” is selected.

  Then, when the pattern selection display PB is selected by operating the selection switch 38, the side lamps 52L and 52R blink each time with a test pattern corresponding to the selected pattern selection display PB, and thereafter, a standby state is set. . When the decision switch 39 is operated in the standby state, the sub-control unit 200 switches the display of the image display device 70 to the system menu screen shown in FIG. In addition, other lamps such as decorative lamps 74L and 74R in addition to the side lamps 52L and 52R may be tested at the same time.

(User volume adjustment screen)
On the system menu screen, when the enter switch 39 is operated while the item name of “user volume adjustment” is displayed in outline characters, the display of the image display device 72 is displayed on the user volume adjustment screen shown in FIG. Switch. On the user volume adjustment screen, a selection display SB of “adjustment permission” for allowing the player to adjust the effect sound and a selection display SB of “adjustment impossible” for not allowing the player to adjust the effect sound are provided. Is displayed. Then, by operating the upper switch or the lower switch of the selection switch 38, one of the selection displays SB of "adjustment permitted" and "adjustment disabled" is selected. The selected selection display SB is displayed in white characters, and FIG. 32 shows that the selection display SB of “adjustment permission” is selected.

  Then, when the determination switch 39 is operated while the desired selection display SB is selected, it is determined whether or not to allow the player to adjust the volume, and the sub-control unit 200 displays the image on the image display device 70. Is switched to the system menu screen shown in FIG. It should be noted that a menu screen for a player displayed on the image display device 70 when a game is not being played, and a display on the image display device 70 during the game standby display, depending on whether or not volume adjustment by the player is permitted. The demo screen is different.

  Here, FIG. 37 shows an example of the menu screen for the player. On the menu screen for the player, after the unit game (one game) is completed (more specifically, two seconds after the completion of the unit game), the effect switch (more specifically, the decision switch 39) is operated. By doing so, it can be displayed. When the menu screen for the player is displayed, various settings and selections can be made based on the operation of the effect switch by the player. FIG. 37A is a menu screen for a player displayed when “adjustment permission” is selected on the user volume adjustment screen in FIG. 32. FIG. 37B is a menu screen for a player displayed when “adjustment impossible” is selected on the user volume adjustment screen in FIG. 32. In the menu screen for players shown in FIG. 37, a cursor C is displayed at the center of the screen on the initial screen. Then, by operating the upper switch or the lower switch of the selection switch 38 with the cursor C displayed at this position, “heroine selection”, “story introduction”, “payout table”, “password input”, The six items of “end-time code display” and “custom clear” scroll vertically and cyclically.

  The “heroine selection” among the above-mentioned items allows the player to select which character is to be used as the effect to be performed in accordance with the progress of the game. The "story introduction" is a display that introduces the original work that is the motif of the gaming machine. Things. The “payout table” displays a symbol combination of a bonus combination, a small combination, and a replay combination (for the small combination, the number of paid out medals). In the item of the "payout table", so-called "chance eyes", "reach eyes", and the like may be displayed. As a result, even a beginner player can easily compare the symbol combination stopped and displayed with the "chance eyes" and "reach eyes" displayed on the "payout table".

  "Custom clear" enables the effect contents (effect contents selected on the mobile terminal) included in the input password to be returned (updated) to the initial effect (also referred to as the standard effect). is there. The “member registration” displays a two-dimensional code including the URL of a predetermined server on the net (however, information such as game history is not included) when a new password is requested. "Volume adjustment" displays an image for enabling the player to adjust the volume of the effect sound output from the gaming machine.

  “Password input” is for displaying a screen for inputting a password. The input password is issued from a predetermined server accessible via the mobile terminal, and is displayed on the mobile terminal. The password includes the total number of games played by the player, the effect contents selected on the portable terminal (for example, the sound of the push-navigation), and the like. The “display at end code” is a display of a two-dimensional code including information of a game history relating to a game performed after a password is input and a game is played.

  It should be noted that the game standby display may be started when a predetermined time has elapsed since the display of the two-dimensional code. At this time, the time from the display of the two-dimensional code to the start of the game standby display may be longer than the time from the stop of the game to the start of the game standby display. With such a configuration, for example, while sufficiently securing the time until a two-dimensional code is acquired by a mobile terminal or the like, if the player has left with the two-dimensional code displayed, the next It becomes easier for the player to start the game.

  In addition, if the game standby display is started after displaying the two-dimensional code, it is impossible to select “End code display” again from the menu screen, or the two-dimensional code is displayed even if “End code display” is selected. May not be displayed. With this configuration, the following effects can be obtained. For example, it is assumed that the displayed two-dimensional code includes unique information (for example, a mobile number) of the mobile terminal. Here, the unique information of the mobile terminal included in the two-dimensional code is based on the two-dimensional code displayed on the image display device 70 when the “member registration” item described above is selected. This was included in the password issued by. Then, when the player starts the game after inputting the password, the two-dimensional code displayed when the item of “display the code at the end” is selected includes the unique information of the mobile terminal included in the password. Will be included. For this reason, when the game standby display is started after displaying the two-dimensional code, if “display at end code” can be selected again from the menu screen, the next player can select “display at end code” from the menu screen. Is selected and the displayed two-dimensional code is acquired by the user's own portable terminal, the unique information of the portable terminal included in the acquired two-dimensional code is different from the unique information of the portable terminal that acquired the two-dimensional code. Therefore, even if a predetermined server is accessed based on the acquired two-dimensional code, an appropriate password is not issued, which may cause confusion. Therefore, when the game standby display is started after the two-dimensional code is displayed, it is not possible to select “end-time code display” again from the menu screen, thereby eliminating the possibility of causing such confusion.

  For example, when the upper switch of the selection switch 38 is operated in the state shown in FIG. 37A, the display of the six items described above scrolls upward, and the item “password input” is moved to the position of the cursor C. Moving. When the lower switch of the selection switch 38 is operated in the state shown in FIG. 37A, the display of the six items described above scrolls downward, and the item “Introduction to Story” is moved to the position of the cursor C. Moving. As described above, the upper switch or the lower switch of the selection switch 38 is operated until the desired item is moved to the position of the cursor C. Then, when the decision switch 39 is operated when the desired item is displayed at the position of the cursor C, a screen corresponding to the desired item is displayed on the image display device 70.

  When the right switch of the selection switch 38 is operated in the state shown in FIG. 37A, the display of the cursor C moves rightward, and the cursor C is displayed at the position of the item of “end”. If the decision switch 39 is operated at this time, the display content of the image display device 70 returns to the state before the menu screen for the player is displayed. When the left switch of the selection switch 38 is operated in the state shown in FIG. 37A, the display of the cursor C moves to the left, and the cursor C is displayed at the position of the item of “member registration”. . If the decision switch 39 is operated at this time, the display of the image display device 70 is switched to a screen for performing member registration.

  Here, when “adjustment permission” is selected on the user volume adjustment screen of FIG. 32, an item of “volume adjustment” is displayed below an item of “member registration” on the menu screen for the player (FIG. 32). 37 (a)). When the lower switch of the selection switch 38 is operated while the cursor C is moving to the position of “member registration”, the cursor C moves to the position of “volume adjustment”. When the decision switch 39 is operated in this state, a screen similar to the volume adjustment screen shown in FIG. 29 (the cursor EC need not be displayed) is displayed on the image display device 70, and By instructing the direction, the volume of the effect sound can be adjusted.

  On the other hand, if “adjustment impossible” is selected on the user volume adjustment screen of FIG. 32, the item of “volume adjustment” is not displayed on the player menu screen (see FIG. 37 (b)). Cannot adjust the volume of the production sound.

  In addition, although the item of "volume adjustment" is displayed, the item of "volume adjustment" cannot be selected, the item of "volume adjustment" is displayed, and the item of "volume adjustment" can also be selected. However, even if the screen of "volume adjustment" is displayed, the volume of the effect sound cannot be adjusted by operating the selection button. As described above, in the present embodiment, the hall can set whether or not to set so that the player can perform “volume adjustment”.

  Although the volume adjustment mode in FIG. 29 is displayed on the system menu screen, it may be displayed on a player menu screen (see FIG. 37) that can be selected by the player. In this case, if the player does not want to adjust the volume of the production sound, the staff of the game hall adjusts the desired volume in "volume adjustment" of the menu screen, and then shifts to the production setting mode, and the system menu screen is displayed. It is preferable to set so that the player cannot adjust the volume by the “user volume adjustment”.

Providing such setting items has the following advantages, for example.
(1) The sound volume can be set to an appropriate level according to the circumstances of the game arcade. For example, some gaming centers place importance on announcements by staff and BGM flowing to the gaming hall, and there is also a demand for reducing the production sound output by the slot machine. Therefore, by setting an appropriate volume in the volume adjustment mode and disabling the user's volume adjustment, it is possible to output an effect sound at a volume desired by the game hall.

(2) It is possible to cope with a case where the amplifier for amplifying the effect sound breaks down after the gaming machine is installed in the game arcade. If the volume is too high, the amplifier will be overloaded and the amplifier may break down. Although the manufacturer has designed a volume that does not cause the amplifier to fail as a MAX value that can be selected in the volume adjustment mode, a behavior exceeding the manufacturer's design value does not always occur. For example, when it is determined that the cause of the failure of the amplifier of the gaming machine installed in the game arcade A is related to the output volume, the same event may occur in other game machines in the game arcade A. . In that case, in order to appropriately adjust the volume, the manufacturer uses the volume adjustment mode to notify the appropriate volume to each game hall, and after the staff of the game hall set the volume, the user volume cannot be adjusted. This makes it harder for other gaming machines to fail.

  Next, FIG. 38 shows an example of the game standby display. Here, FIG. 38A shows an example of a game standby display when “adjustment permission” is selected on the user volume adjustment screen of FIG. 32, and FIG. It is an example of a game standby display when "adjustment impossible" is selected. As shown in FIG. 32, when “adjustment permission” is selected on the user volume adjustment screen of FIG. 32, during the game standby display, “Push button to menu screen / right button of cross key to volume setting screen” Is displayed. At this time, when the enter switch 39 is operated during the game standby display, the image display device 70 displays the menu screen for the player shown in FIG. When the right switch of the selection switch 38 is operated, a screen similar to the volume adjustment screen shown in FIG. 29 (however, the cursor EC is not displayed) is displayed on the image display device 70, and the left switch of the selection switch 38 or By operating the right switch, the volume of the effect sound can be adjusted. In this case, a screen for volume adjustment is displayed on the image display device 70 only by operating the selection switch 38 without operating the determination switch 39 to shift to a menu screen for a player and selecting “volume adjustment”. Since the volume can be adjusted, the player can perform the volume adjustment with a simple operation.

  On the other hand, when “impossible to adjust” is selected on the user volume adjustment screen of FIG. 32, the message M is not displayed during the game standby display, and even if the right switch of the selection switch 38 is operated, the display of FIG. A screen similar to the volume adjustment screen shown is not displayed on the image display device 70. However, the menu screen for the player shown in FIG. 37B may be displayed by operating the determination switch 39 at this time. In this case, a message “Push button to menu screen” may be displayed on the image display device during the game standby display.

  Before the game standby display is displayed (for example, two seconds after the end of the game), control is performed so that a message M (see FIG. 38A) notifying that the volume can be adjusted is displayed. May be. Furthermore, the display of “Menu screen with push button” as the content of the message may be displayed even when “Adjustment impossible” is selected on the user volume adjustment screen. In this case, as the content of the message displayed before the game standby display is displayed (for example, two seconds after the end of the game), the text “Press the right button of the cross key to go to the volume setting screen” is not displayed and “PUSH” is displayed. Only a menu screen with a button "may be displayed. In addition, the volume set by the player is maintained until the game is switched to the game standby display, and after the game is switched to the game standby display, when the game is resumed, the volume is returned to the volume set on the volume adjustment mode screen in FIG. You may. Further, the volume set by the player shifts to the game standby display and is held until a predetermined time elapses. After the predetermined time elapses after the game shifts to the game standby display, the game is resumed. The sound volume may be returned to the sound volume set on the sound volume adjustment mode screen 29. At this time, if the game is restarted before the predetermined time has elapsed since the transition to the game standby display, the effect is executed at the volume set by the player.

  When the player adjusts the volume, the effect is performed at that volume, but when the slot machine 10 is turned off and then turned on again, the effect is again performed at the volume set on the volume adjustment screen in FIG. An effect may be performed. When there is no “volume adjustment” item on the system menu screen of FIG. 28 (that is, the volume of the effect sound cannot be adjusted in the effect setting mode), the power of the slot machine 10 is turned off and then turned on again. Alternatively, the volume adjusted by the player may be returned to a predetermined initial value. Furthermore, when the power saving mode and the normal mode can be selected on the system menu screen, the volume of the initial value is set to be smaller when the power saving mode is set than when the normal mode is set. May be configured. In this case, since the setting value is changed when the power of the slot machine 10 is turned on, the volume of the effect sound is inevitably the volume set on the game hall side, or the predetermined initial value. It will return to the volume. For this reason, it is not possible to distinguish whether the power has just been turned off or the setting value has been changed, so even if the volume of the production sound returns to the initial state, the setting value change will not be made. It cannot be determined whether or not it has been performed.

(Game data display setting screen)
When the enter switch 39 is operated while the item name of “game data display” is displayed in outline characters on the system menu screen, the display of the image display device 72 changes to the game data display setting screen shown in FIG. Switch to On the game data display setting screen, a selection display SB of "game data display" for enabling display of game data to the player and a selection display of "game data non-display" for not displaying game data for the player SB is displayed. By operating the upper switch or the lower switch of the selection switch 38, one of the selection displays SB of "game data display" and "game data non-display" is selected. The selected selection display SB is displayed in white characters, and FIG. 33 shows that the selection display SB of “game data display” is selected.

  Then, when the decision switch 39 is operated while the desired selection display SB is being selected, it is determined whether or not the game data can be displayed for the player, and the sub control means 200 displays the image. The display of the device 70 is switched to the system menu screen shown in FIG. Note that the content of the menu screen for the player displayed on the image display device 70 when the game is not performed differs depending on whether or not the game data can be displayed to the player.

  Specifically, when the game data can be displayed to the player, the item “display game data” is displayed at the position of the item “volume adjustment” on the menu screen for the player shown in FIG. Is displayed. On the other hand, when the game data is not displayed to the player, the menu screen for the player has the content shown in FIG. When both the volume adjustment by the player and the display of the game data are enabled, in the menu screen for the player shown in FIG. An item “data display” may be added.

  In the case where the game data can be displayed to the player, when the item “display game data” is selected by the cursor C on the menu screen for the player, the sub-control unit 200 displays the image display device 70 in FIG. The game data display screen shown is displayed. On this game data display screen, game data relating to “the total number of games”, “the number of normal games”, “the number of AT games”, “the number of specific small role prize”, “the number of BB role prize” and “the number of AT start” are displayed. Have been. The “number of AT games” indicates the number of games played during the AT game out of the total number of games. The “number of normal games” indicates the number of times that a game other than the AT game is played out of the total number of games (the number of games obtained by subtracting the number of AT games from the total number of games).

  The “number of small role winnings” is the number of times a small role with a different winning probability according to the set value wins among the small roles targeted for the role lottery, and the winning probability (specific small role winning times) / Number of normal games). Further, the “number of BB winning combinations” indicates the number of winnings of the BB combination and the winning probability (the number of winning BB combinations / the number of normal games), and the “number of AT starts” indicates the number of times the AT game was started. , Start probability (number of starts / number of normal games).

  Here, the number and the number of times of various games indicate values counted after the password is input by the player. When this password is displayed on the menu screen of FIG. 37, when “End code display” is selected, a two-dimensional barcode including the URL of the predetermined server is displayed on the image display device 70, and the two-dimensional barcode is displayed on the portable terminal. The data is transmitted from the above-mentioned predetermined server by being taken in and accessing the Internet. Thereby, the game data displayed on the game data display screen becomes game data unique to the player who has input the password. The number and the number of various games may be counted after the power is turned on, or may be counted after the set value is changed.

  When the decision switch 39 is operated while the game data display screen shown in FIG. 39 is displayed, a menu screen for a player similar to FIG. Game data display item is included).

(Error display screen)
When the enter switch 39 is operated while the item name of “error etc. history” is displayed in outline characters on the system menu screen, the image display device 72 displays the error etc. history display screen shown in FIG. Switch to In the error etc. history display screen, "setting change / confirmation history", "insertion sensor error information history", "medal passing error information history", "payout error information history", "effect setting mode transition history", "occurrence error A selection display SB corresponding to the six items of “time-series history” and “return” is displayed.

  Then, the user operates the selection switch 38 to select one of the selection displays SB. Here, the selected selection display SB is displayed in white characters, and indicates, for example, that the selection display SB of “setting change / confirmation history” is selected on the error etc. history display screen of FIG. I have. Thereby, any one of the selection display SB among “setting change / confirmation history”, “insertion sensor error information history”, “medal passing error information history”, “payout error information history”, and “effect setting mode transition history” When the determination switch 39 is operated in a state where is selected, the selected history screen is displayed on the image display device 70.

  For example, when the selection display SB of “setting change / confirmation history” is selected, the time at which the setting value was changed (that is, the reception time of the setting change device operation start command (8038)) and the setting value are confirmed. The set times (that is, the reception times of the set value display start command (8F5A)) are listed in chronological order. When the selection display SB of the “input sensor error information history” is selected, the occurrence time of the input sensor error (error code: C0) (that is, the reception time of the input sensor error display start command (8106)) is time-series. A list is displayed. When the selection display SB of “medal passing error information history” is selected, the time of occurrence of the medal passing error (error code: C1) (that is, the reception time of the insertion sensor error display start command (8107)) is time-series. A list is displayed. When the selection display SB of “payout error information history” is selected, the time of occurrence of a payout error (error code: H0) (that is, the reception time of the payout error display start command (8103)) is displayed in a chronological list. You. Further, when the selection display SB of “transition to effect setting mode” is selected, the time at which the transition to the effect setting mode is listed in chronological order.

  Here, in the present embodiment, when the main control means 100 shifts to the setting change mode and the setting confirmation mode, the mode shifts to the effect setting mode (see FIG. 27). The history displayed when the “setting change / confirmation history” is selected has the same content. Therefore, either one of the “effect setting mode transition history” or the “setting change / confirmation history” may be deleted. In addition to the case where the main control means 100 shifts to the setting change mode and the setting confirmation mode, for example, when the upper switch of the selection switch 38 is continuously operated for a predetermined time or more with the front door 14 opened, The transition to the effect setting mode may be performed, and a history of the transition to the effect setting mode by each method may be displayed in the “effect setting mode transition history”. In this case, it goes without saying that the contents of the “effect setting mode transition history” and the contents of the “setting change / confirmation history” are different. Note that even in such a configuration, the item of “setting change / confirmation history” may be omitted.

  As described above, when the mode is shifted to the effect setting mode when the upper switch of the selection switch 38 is continuously operated for a predetermined time or more with the front door 14 opened, the setting key of the key switch 82b is provided. Even if there is no staff (there is no authority to change the setting value), if the staff of the game hall has the keypad of the door key 31, the staff can shift to the effect setting mode and check the history of errors that have occurred. . As a result, for example, the staff of the game arcade can grasp on the spot how much error has occurred in the player who is currently playing the game.

  A system menu screen that is displayed on the image display device 70 when the mode is switched to the effect setting mode by shifting to the setting change mode or the setting confirmation mode, and when the mode is shifted to the effect setting mode using only the keypad. May be set differently. For example, when the mode is shifted to the effect setting mode using only the keypad, only the items of “error etc. history” and “side lamp test” may be displayed on the system menu screen of FIG. Further, when the mode is shifted to the effect setting mode using only the keypad, the error history selection mode screen of FIG. 34 may be displayed on the image display device 70 so that various histories can be selectively displayed. In this way, the staff of the game hall having only the keypad cannot operate the setting of the power saving mode or the like, so that the staff of the game hall having the setting key is differentiated. The staff at the game hall without the setting key is not limited to the contents described above. For example, operating a predetermined switch provided inside the slot machine when the front door 14 is open, When the selection switch 38 is operated in a specific procedure, such as operating the upper switch twice with the selection switch 38 twice and then operating the lower switch twice in a state where 14 is opened, the mode can be shifted to the setting change mode. It may be.

  Next, when the selection display SB of “occurrence error time series history” is selected, the sub-control unit 200 displays the occurrence error time series history screen shown in FIG. The occurrence error time-series history screen displays the order in which the errors occurred (No), the type (contents) of the error that occurred, and the time of occurrence (date and time of occurrence) in a chronological order in a table format. Here, the types of errors to be displayed are, in addition to the above-described insertion sensor error, medal passing error, and payout error, an empty error, a medal jam error, a medal full error, a medal insertion error, a medal passing error, a medal staying error, A history regarding the input sensor passage error may be displayed.

  Here, the occurrence time displayed on each history screen may be a time elapsed after the power of the slot machine 10 is turned on, or a date acquired from, for example, an RTC (real-time clock: an integrated circuit that measures time). And time. If the history cannot be displayed on one screen, the history is scrolled by operating the upper switch or the lower switch of the selection switch 38, and the page switching display is performed by operating the left or right switch. Or you may.

  If the enter switch 39 is operated while the various history screens described above are displayed, the screen returns to the error history etc. display screen of FIG. Then, when the decision switch 39 is operated on the error history etc. display screen of FIG. 34 while the selection display SB of “RETURN” is selected, the screen returns to the system menu screen of FIG.

  Note that the histories relating to a plurality of errors are individually selected as the error history selection mode. However, when the error history selection mode is selected, the histories relating to the plurality of errors are collectively displayed in one history. Alternatively, some of the plurality of errors may be displayed collectively in one history, and the remaining errors may be displayed individually. In addition, the history to be displayed may include an event other than the error (for example, the power on / off date and time, the opening / closing time of the front door 14 and the like).

(Power saving setting screen)
When the enter switch 39 is operated while the item name of “power saving setting” is displayed in outline characters on the system menu screen, the display of the image display device 72 is displayed on the power saving setting screen shown in FIG. Switch. On the power saving setting screen, selection displays SB respectively corresponding to “normal mode” and “power saving mode” are displayed. By operating the upper switch or the lower switch of the selection switch 38, the selection display SB of either the "normal mode" or the "power saving mode" can be selected. The selected selection display SB is displayed in white characters, and FIG. 36 shows that the “normal mode” selection display SB is selected. When the determination switch 39 is operated while the selection display SB of “normal mode” is selected, the normal mode is set. When the selection display SB of “power saving mode” is selected, the determination switch 39 is operated. Then, the power saving mode is set.

  Here, the difference between the “normal mode” and the “power saving mode” will be described. These modes are modes for selecting whether or not to suppress the power consumption during the game standby display. When the “power saving mode” is selected, the power consumption during the game standby display can be suppressed. . Specifically, in the game standby display when the “power saving mode” is selected, the illumination provided in the lower panel 50 is made darker than in the game standby display in the “normal mode”. For example, an effect with reduced power consumption, such as decreasing the brightness of the demonstration screen displayed on the screen, lowering the volume of the BGM, or stopping the BGM, is performed.

  When the power saving mode is set, the volume of the effect sound during the normal game is automatically set to the first value (for example, “5” when the volume can be adjusted in 15 steps). When the “normal mode” is set, the volume of the effect sound during the normal game is automatically set to the second value (for example, “8” when the volume can be adjusted in 15 steps). You may do so. In this way, by associating the “normal mode” and the “power saving mode” with their respective unique volumes, the trouble of setting the volume on the volume adjustment screen of FIG. 29 can be omitted.

  In the case described above, when the display is shifted to the volume adjustment screen of FIG. 29 after setting to the “normal mode”, the cursor SC is displayed at the position of “8”, and the volume is adjusted after setting to the “power saving mode”. When shifting to the screen, the cursor EC may be displayed at the position of “5”.

  Further, for example, in the game standby display when the "normal mode" is selected, the "power saving mode" is selected by blinking the side lamps 52L, 52R and the backlight of the reel in a predetermined pattern. When the game is on standby, when the side lamps 52L and 52R blink in a predetermined pattern, the number of lamps (or LEDs) to be turned on at one time is reduced while the backlight of the reel is turned off, or the side lamps 52L are turned off. , 52R and the backlight of the reel may be turned off.

  In the game standby display when the “normal mode” is selected, the side lamps 52L and 52R blink in a predetermined pattern, but the backlight of the reel is turned off or the backlight of the reel is displayed in a predetermined pattern. Although the side lamps 52L and 52R are turned off, the side lamps 52L and 52R and the reel backlight may be turned off in the game standby display when the "power saving mode" is selected. Conceivable.

In the effect setting mode described above, a function having the following functions may be provided.
(1) The date and time of the RTC (real-time clock) provided in the slot machine 10 may be set on the system menu screen of FIG. Thus, the date and time set in the RTC are referred to when the various histories described above are recorded.

(2) Various items displayed on the system menu screen can be selected regardless of the open / closed state of the front door 14. This is because the weight of the front door 14 is generally heavy (about 10 kg), and when a structure (also referred to as “movable for production”) that is moved by a motor or the like as a production device is provided on the front door 14, the weight is further increased. Increase. For this reason, if the staff at the amusement arcade selects each item of the effect setting mode with the front door 14 kept open, a load is applied to the hinge connecting the front door 14 and the main body 12 during that time. It may cause a failure. For this reason, after shifting to the effect setting mode, the load on the hinge can be reduced by enabling various settings even when the front door 14 is closed. In addition, if it is assumed that various settings can be made on condition that the front door 14 is opened, various settings can be performed with only one hand while holding the front door 14 with one hand so as not to close. Therefore, there is a possibility that the setting operation becomes difficult.

(3) As a method of shifting to the effect setting mode, in each of the setting change mode and the setting confirmation mode, or in any one of the modes, a specific switch is operated to shift to the effect setting mode. Is also good. Here, the specific switch may be the selection switch 38 or the determination switch 39, or a dedicated switch for shifting to the effect setting mode may be provided.

(4) For example, when there is an effect movable object driven by a drive source such as a motor, the effect movable object test mode for testing whether or not the effect movable object operates normally is provided. Is also good. For example, when a movable left shutter and a right shutter that cover the screen of the image display device are provided as a movable object for production, if the movable object test mode for production is selected, the right shutter is activated after the left shutter is activated. Control. Thereby, it can be grasped whether or not the effect movable object operates correctly.

(5) Although seven types of setting items are provided on the system menu screen shown in FIG. 28, the number of setting items is not limited thereto. Further, since the setting items such as the user volume adjustment, the power saving setting, the game standby lamp color, and the game data display are adjustment functions related to the execution of the game, all of these setting items or a part of the setting items are put together. May be combined into one setting item “adjustment setting”. In this case, when a setting item “adjustment setting” is selected, a screen on which a plurality of setting items can be individually adjusted is displayed on one screen. For example, when the user volume adjustment and the power saving setting are combined into one setting item, the level meter LV shown in FIG. 29 and the selection display SB of “normal mode” and “power saving mode” shown in FIG. 36 are displayed. Are displayed on one screen. By operating the upper switch or the lower switch of the selection switch 38, the item to be selected is designated. For example, when the level meter LV is selected, the left or right switch of the selection switch 38 is operated to produce the effect sound. Make the volume adjustable. Further, for all the setting items shown on the system menu screen, an adjustment screen combined into one screen can be displayed in the display contents of FIGS. 29 to 34, and the adjustment screen is displayed when the mode shifts to the effect setting mode. You may. In this case, when displaying the error history, only the type and time of occurrence of the most recent error may be displayed. Alternatively, when the most recent error is selected and the decision switch 39 is operated, the power The screen may be switched to a screen that displays a history of all errors that have occurred after the input.

(6) The setting change display and the warning sound output when the mode is changed to the setting change mode may be maintained for a predetermined time after the setting change mode ends. Alternatively, timing may be started when the mode shifts to the setting change mode, and the display indicating that the setting is being changed and the warning sound may be maintained until a predetermined time has elapsed. In this case, even if the setting change mode is ended before the predetermined time elapses after the transition to the setting change mode, the display indicating that the setting is being changed and the warning sound are maintained until the predetermined time elapses. Further, the above-mentioned predetermined time may be adjustable in the effect setting mode. For example, the desired predetermined time may be selectable from 5 seconds, 10 seconds, and 15 seconds.

(7) It is desirable that the contents set in the effect setting mode be maintained even when the setting / reset switch 82c is operated and reset after an error that can be returned is generated, for example. Also, when the set value is changed by shifting to the setting change mode, the content set in the effect setting mode is maintained. For example, the volume adjusted by the player is erased (ie, May return to the set volume). Further, for example, when the watchdog timer activated in step Ss22 in FIG. 26 has timed out (such as when the CPU of the sub-control unit 200 has run out of heat), the contents set in the effect setting mode are cleared, and for example, Alternatively, the settings may be returned to the factory settings.

(8) As an item that can be set in the effect setting mode, an item that can set whether or not to accept input of a password may be provided. In this case, if the setting is made not to accept the input of the password, the item of “password input” is excluded (not displayed) from the menu screen for the player shown in FIG. By providing such setting items, the following effects can be obtained.
(A) If there is an item "Enter Password" in the menu screen for the player, the player who saw the item for the first time knows the advantages and disadvantages of entering the password and not entering the password. The player may be puzzled. In addition, depending on the amusement arcade, it is considered that a complicated function may be intentionally disabled in order to allow a player who is not used to playing the game to be able to play the game without being confused. I can do it.
(B) When manufacturing and selling gaming machines that are not equipped with a password input function, it is inefficient to change the specification of the effect setting mode between gaming machines that can enter passwords and gaming machines that cannot enter passwords. is there. Therefore, with respect to a gaming machine that does not allow a password to be input, by setting a mode in which a password cannot be input at the game arcade, it is possible to reduce the cost of the game machine during product development.

[Second embodiment]
Next, a second embodiment of the present invention will be described. In the first embodiment, the rising data and the falling data of the signal input to the input port 0 are generated by the timer interrupt processing (more specifically, the input port 0 to 2 reading processing). When the front door 14 is open (that is, the door switch signal is on), the rising data and the falling data are generated. When the front door 14 is closed (that is, the door switch signal is off), the rising data and the falling data are generated. No falling data is generated (see steps S608 to S618 in FIG. 24).

  Then, in the game medal insertion standby display process (see FIG. 20) of the first embodiment, the set value can be confirmed when the rising data of the set key switch signal is 1 (step S140, YES → S142). -S148) As described above, in order for the rising data of the setting key switch signal to be 1, not only the setting key switch signal has changed from off to on, but also the door switch signal must be on. Therefore, in order to confirm the set value, it is necessary to turn the key switch 82c from off to on while the front door 14 is open.

  If the falling data of the setting key switch signal becomes 1 while the setting value is being checked, the setting value check is terminated (step S150, YES → S152). In order for the falling data of the signal to be 1, not only the setting key switch signal has changed from on to off, but also the door switch signal must be on. Therefore, in order to complete the confirmation of the set value, it is necessary to turn the key switch 82c from on to off while the front door 14 is open.

  On the other hand, in the present embodiment, the open / close determination of the front door 14 is not performed in the timer interrupt process as in the first embodiment, but is performed in the game medal insertion standby display process. . Therefore, in the input port 0 to 2 read processing of the present embodiment, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. In the first embodiment, the falling data (D0 bit) of the setting key switch signal and the rising data (D1, D2 bits) of the setting / reset button signal and the setting key switch signal are stored in the RWM address F00D. However, in the present embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021, and the processing in step S618 is performed in the following manner. It shall be omitted. The contents of the D1 to D7 bits of the data stored in the RWM addresses F020 and F021 are the same as the D1 to D7 bits of the RWM address F00A.

  FIG. 40 shows a flowchart of the game medal insertion standby display process in this embodiment. In this figure, steps that perform the same processing as the game medal insertion standby display processing shown in FIG. 20 are assigned the same step numbers, and detailed descriptions thereof are omitted.

  When the determination result of step S102 of the game progress main process shown in FIG. 19 is YES, the main control unit 100 of the present embodiment executes the game medal insertion standby display process of FIG. First, it is determined whether the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sa10). If the value of the D2 bit is 0 (the front door 14 is closed), the result of the determination in step Sa100 is NO, and the flow shifts to the determination processing in step S160.

  On the other hand, if the value of the D2 bit is 1 (the front door 14 is open), the determination result in the step a10 is YES, the process proceeds to a step S140, and the rising data of the input port 0 stored in the RWM address F020 is obtained. It is determined whether or not the value of the D1 bit (rising data of the setting key switch signal) is 1. Then, if the value of the D1 bit of the input port 0 rising data is 1 (step S140, YES), the blocker of the selector 80 is turned off, and a set value display start command is transmitted to the sub control means 200. The current set value is displayed on the display 87 (steps S142 to S148). In this state, it is determined again whether the value of the door switch signal (D2 bit) stored in the RWM address F00D is 1 (step Sa12). When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Sa12 is performed again. The determination process of step Sa12 is repeated until the determination result becomes YES.

  On the other hand, when the value of the D2 bit becomes 1, the determination result in step Sa12 becomes YES, and the process proceeds to step S150, where the D1 bit of the input port 0 falling data stored in the RWM address F021 (the setting key switch signal It is determined whether the value of the falling data is 1 or not. When the value of the falling data of the setting key switch signal is 0, the determination result of step S150 is NO, and the determination process of step Sa12 is performed again. As a result, when the front door 14 is open, the determination processing of steps Sa12 and S150 is repeated until the key switch 82c is turned off from on.

  When the value of the door switch signal is 1 and the value of the falling data of the setting key switch signal is 1 (step S150, YES), the main control means 100 turns off the setting value display 87, A set value display end command is transmitted to the control means 200, and the blocker of the selector 80 is turned on (steps S152 to S158). Next, when the game standby display is started, the acquired number data stored in the RWM is cleared (step S160, YES → S162), and the process proceeds to the game medal management process of step S106 in FIG. On the other hand, when the game standby display is not started, the process directly proceeds to the game medal management process of step S106 in FIG.

(Modification of Second Embodiment)
In the game medal insertion standby display process of FIG. 40, the determination of the rising of the setting key switch signal in step S140 and the determination of the falling of the setting key switch signal in step S150 are determined by the setting key switch stored in the RWM address F00D. This is performed based on the values of the rising data (D2 bit) and the falling data (D0 bit) of the signal. These data are generated by the processing of steps S612 to S616 of the input port 0 to 2 read processing (FIG. 24) executed in the timer interrupt processing (FIG. 22).

  However, the rising / falling data of the signal input to each input port may be generated when needed in the game progress main processing. Therefore, with reference to the flowcharts of FIGS. 41 to 43, a description will be given of a case where the rising and falling data of the setting key switch signal is generated in the game signal main processing (more specifically, in the game medal insertion standby display processing). I do.

  In the game medal insertion standby display process shown in FIG. 41, the same steps as those of the game medal insertion standby display process shown in FIG. 40 are denoted by the same step numbers, and detailed description thereof will be omitted. In this modification, the input port 0 level data acquired during the game medal insertion standby display process of FIG. 41 is stored in the RWM address F00A.

  In this modification, when the determination result of step S102 of the game progress main process shown in FIG. 19 is YES, the main control unit 100 starts the game medal insertion standby display process of FIG. First, the value of F00AH is set in the HL register, the signal currently input to the input port 0 is read, and set in the A register (step Sb10). At this time, a signal input in negative logic may be converted to positive logic. Of course, if there is no problem in the subsequent processing with the negative logic, it is not necessary to convert to the positive logic. Next, the process proceeds to step Sa10, and it is determined whether or not the value of the D2 bit (door switch signal) of the A register is 1. When the value of the D2 bit is 1 (the front door 14 is open), the determination result is YES, and then the main control means 100 sets the value of 00000010B in the C register as the detection data of the setting key switch. (Step Sb12). At this time, the value of F00A (the address for storing the input port 0 level data) is set in the HL register by the process of step Sb10.

  Here, the detection data of the setting key switch is data for validating only the setting key switch signal (D1 bit) of the input port 0 level data. Then, a rising check process for generating rising data of the setting key switch signal is performed (step Sb14), and the process proceeds to step S140, where the setting key switch signal rises (the key switch 82c is turned on from off). It is determined whether or not. Here, whether or not the setting key switch signal has risen is determined based on the value of the zero flag. If the value of the zero flag is 1, the determination result of step S140 is NO, and if the value of 0 is 0, the determination result is YES. (Details will be described later). If the set key switch signal has risen (step S140, YES), the blocker of the selector 80 is turned off, a set value display start command is transmitted to the sub control means 200, and the set value display 87 is displayed. Is displayed (steps S142 to S148).

  Next, the main control means 100 sets the value of F00AH in the HL register, reads the signal currently input to the input port 0, and sets the signal in the A register (step Sb16). If the value of the HL register (F00AH) set in step Sb10 is not changed through the processing of steps S140 to S148, Sb16, and Sa12 in FIG. 41, the value of F00AH is set in the HL register in step Sb18. Can be omitted. Then, the process proceeds to a step Sa12, where it is determined whether or not the value of the D2 bit (door switch signal) of the A register is 1; if the value of the D2 bit is 0, the determination result is NO and the process returns to the step Sa12. The determination processing of Sb16 is performed, and the determination processing of steps Sb16 and Sa12 is repeated until the determination result becomes YES. On the other hand, when the value of the D2 bit becomes 1, the determination result in step Sa12 becomes YES, and the detection data (00000010B) of the setting key switch described above is set in the C register (step Sb18). At this time, the value of F00A (the address for storing the input port 0 level data) is set in the HL register by the process of step Sb16.

  Next, the main control means 100 performs a rising check process for generating falling data of the setting key switch signal (step Sb20). Next, the main control means 100 proceeds to step S150, and determines whether or not the setting key switch signal has fallen. Here, whether or not the setting key switch signal has fallen is determined based on the value of the zero flag. If the value of the zero flag is 1, the determination result of step S150 is NO, and if the value of 0 is 0, the determination of step S150 is made. The result is YES (details will be described later).

  If the decision result in the step S150 is YES, the set value display 87 is turned off, a set value display end command is transmitted to the sub control means 200, and the blocker of the selector 80 is turned on (step S152). To S158). Then, when the game standby display is started, the acquired number data stored in the RWM is cleared (step S160, YES → S162), and the process proceeds to the game medal management process of step S106 in FIG. On the other hand, when the game standby display is not started, the process directly proceeds to the game medal management process of step S106 in FIG.

  Next, the rise check processing in step Sb14 in FIG. 41 will be described in detail with reference to the flowchart in FIG. First, the main control means 100 reads the level data of the input port 0 from the RWM address specified by the value (F00A) set in the HL register, and sets it in the B register (step Sb100). Then, the value of the A register is stored in the RWM address specified by the value (F00A) set in the HL register, and the previously acquired input port 0 level data is acquired this time (acquired in step Sb10 in FIG. 41). ) Update to input port 0 level data (step Sb102). As described above, since the data of the input port 0 is updated to the latest data every time the rise check processing is performed, the rise is continued (in other words, continuously) when the rise check processing of step Sb14 is next performed. Will not be determined.

  Next, the main control means 100 calculates change bit data by performing an XOR operation on the value set in the A register and the value set in the B register, and setting the operation result in the A register (step S1). Sb104). Accordingly, when the value of the setting key switch signal obtained in step Sb10 of FIG. 41 and the value of the setting key switch signal obtained in step Sb100 change, the value of the D1 bit becomes 1.

  Then, the rising data of the setting key switch signal is generated (step Sb106). Specifically, the change bit data set in the A register and the data stored in the RWM address specified by the value (F00A) set in the HL register (input port 0 updated in step Sb102) Level data) and an AND operation, and the operation result is set in the A register. As a result, as the value of the A register, rising data of a signal input to the input port 0 with positive logic is generated. Next, by performing an AND operation on the value of the A register and the value (00000010B) set in the C register, only the D1 bit (rising data of the setting key switch signal) becomes valid data.

  Here, if the result of the AND operation between the value of the A register and the value of the C register becomes 0 (that is, zero flag = 1), it means that the setting key switch signal has not risen, and AND When the result of the calculation becomes 1 (that is, the zero flag = 0), it means that the setting key switch signal has risen. Therefore, in step S140, it can be determined whether or not the set key switch signal has risen based on the value of the zero flag. When the processing in step Sb106 is completed, the main control unit 100 proceeds to the continuation of the processing (step S140 in FIG. 41) performed before the start-up check processing in FIG. 42 is started.

  Next, the falling edge check process in step Sb20 in FIG. 41 will be described in detail with reference to the flowchart in FIG. First, the main control means 100 reads the level data of the input port 0 from the RWM address specified by the value (F00A) set in the HL register, and sets it in the B register (step Sb110). Then, the value of the A register is stored in the RWM address specified by the value (F00A) set in the HL register, and the previously obtained input port 0 level data is updated (step Sb112).

  Next, the main control means 100 calculates change bit data by performing an XOR operation on the value set in the A register and the value set in the B register, and setting the operation result in the A register (step S1). Sb114). Thereby, when the value of the setting key switch signal obtained in step Sb16 of FIG. 41 and the value of the setting key switch signal obtained in step Sb100 change, the value of the D1 bit becomes 1.

  Then, the falling data of the setting key switch signal is generated (step Sb116). Specifically, the change bit data set in the A register and the data set in the B register (the previously obtained input port 0 level data) are AND-operated, and the operation result is stored in the A register. set. As a result, the falling data of the signal input to the input port 0 with the positive logic is generated as the value of the A register. Next, by performing an AND operation on the value of the A register and the value (00000010B) set in the C register, only the D1 bit (rising data of the setting key switch signal) becomes valid data.

  Here, when the result of the AND operation between the value of the A register and the value of the C register becomes 0 (that is, the zero flag = 1), it means that the setting key switch signal has not fallen, When the result of the AND operation becomes 1 (that is, the zero flag = 0), it means that the setting key switch signal has fallen. Therefore, in step S150, it is possible to determine whether the setting key switch signal has fallen based on the value of the zero flag. When the processing in step Sb116 ends, the main control unit 100 proceeds to the continuation of the processing (step S150 in FIG. 41) performed before the start of the fall check processing in FIG.

  In the rise check processing shown in FIG. 42, the rise data of the set / reset button signal, the set key switch signal, and the door switch signal is generated. (Each stop switch sensor signal, three-sheet insertion sensor signal, clearing switch signal, start switch sensor signal, and the like) may be used to generate rising data. Specifically, before executing the rising check processing, the value of the address where the level data of the input port to which the signal from the target switch is input is stored in the HL register, and the switch signal is assigned. This can be achieved by setting data in which a bit is set to “1” and other bits to “0” in a C register, and then executing a rising check process. In other words, since the subroutine (module) of the rise check processing is a versatile program executed when determining the presence or absence of rise data, it can be diverted in various situations, so that the program capacity Can be reduced.

[Third embodiment]
Next, a third embodiment of the present invention will be described. As described at the beginning of the second embodiment, in the first embodiment, when the rising data and the falling data of the signal input to the input port 0 are generated in the timer interrupt processing, the opening and closing of the front door 14 is performed. The condition was included in the condition. Therefore, in the setting change device processing of the first embodiment shown in FIG. 18, when the setting value data is updated in steps S72 and S74 (that is, the rising data of the setting / reset button signal is 1). , The front door 14 is open.

  In the setting change device processing of FIG. 18, when the falling data of the setting key switch signal becomes 1, the setting change device processing ends (step S86, YES → S88-S94). In order for the falling data of the signal to be 1, not only the setting key switch signal has changed from on to off, but also the door switch signal must be on. Therefore, in order to end the setting change device process, it is necessary to turn the key switch 82c from on to off while the front door 14 is open.

  On the other hand, in the present embodiment, the open / close determination of the front door 14 is not performed in the timer interrupt process as in the first embodiment, but is performed in the setting change device process. Therefore, in the input port 0 to 2 read processing of the present embodiment, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. Also, as in the second embodiment, in this embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021. The processing in step S618 is omitted.

  FIG. 44 shows a flowchart of the setting change device processing in the present embodiment. In this figure, steps for performing the same processing as the setting change apparatus processing shown in FIG. 18 are denoted by the same step numbers, and detailed description thereof will be omitted.

  When the determination result of step S32 of the program start process shown in FIG. 17 is YES, the main control unit 100 of the present embodiment executes the setting change device process of FIG. First, the main control means 100 sets the RWM address (F200H) of the stack area in the SP register, and then initializes the RWM address (steps S50 to S56). After activating the timer interrupt processing and transmitting a setting change operation start command to the sub-control means 200, and waiting for a predetermined time, "88" is displayed on the acquired number display 28 and the set value is displayed. The current set value is displayed on the display 87, and the address value (F000) of the set value data is set in the HL register (steps S58 to S70).

  Next, the main control means 100 determines whether or not the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sc10). If the value of the D2 bit is 0 (the front door 14 is closed), the determination result is NO, and the process shifts to step S80. On the other hand, if the value of the D2 bit is 1 (the front door 14 is open), the determination result is YES, and the main control unit 100 reads the input port 0 rising data stored in the RWM address F020, and It is set in the A register (step Sc12). Then, an AND operation is performed on the value of the A register and the predetermined value 00000001B, and the operation result is set in the A register, thereby generating data for pressing the set / reset button signal (step Sc14).

  Next, the main control means 100 updates the set value data by reading the set value data from the RWM address F000 by the processing of step S70 and adding the read value to the A register (step S74). If the updated set value is within the normal numerical range (0 to 5), the value set in the A register is stored in the RWM address F000 as updated set value data (step S80), and the timer interrupt processing is performed. Then, it is determined whether or not the start switch sensor signal has risen (steps S82 and S84). If the start switch sensor signal has not risen, the determination result is NO, and the process returns to step Sc10. On the other hand, when the start switch sensor signal rises, the determination result is YES, and the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 again. It is determined whether or not (Step Sc16).

  When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Sc16 is performed again. The determination process of step Sc16 is repeated until the determination result becomes YES. On the other hand, when the value of the D2 bit becomes 1, the determination result in step Sc16 becomes YES, and the process proceeds to step S86, where the value of the D1 bit (setting key switch signal falling data) of the data stored in the RWM address F021 is set. Is determined to be 1 (step S86). When the value of the falling data of the setting key switch signal is 0, the determination result of step S86 is NO, and the determination process of step Sc16 is performed again. As a result, the value of the level data of the door switch signal is 1 (the front door 14 is open) and the value of the falling data of the set key switch signal is 1 (the key switch 82c is turned on from off). , And the determination processing of steps Sc16 and S86 is repeated.

  When the result of the determination in step S86 is YES, the main control means 100 clears the display data indicating that the set value is being changed, and then turns on the credit number display 27 and the acquired number display 28, After the set value changing device operation end command is transmitted to the sub control means 200, the game progress main process is started (steps S88 to S94).

[Fourth embodiment]
Next, a fourth embodiment of the present invention will be described. In this embodiment, as in the third embodiment, in the setting change device processing, the setting value data is updated and the value of the door switch signal is determined when the setting change device processing is completed. Is different from the third embodiment. Hereinafter, the setting change device processing of the present embodiment will be described with reference to the flowchart in FIG.

  Also in the present embodiment, in the input port 0 to 2 read processing in the timer interrupt processing, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. . Further, similarly to the third embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021, and the process of step S618 is performed. It shall be omitted. In the flowchart of FIG. 45, steps that perform the same processing as the processing of the setting change device shown in FIG. 18 are denoted by the same step numbers, and detailed description thereof will be omitted.

  When the determination result of step S32 of the program start processing shown in FIG. 17 is YES, the main control unit 100 of the present embodiment executes the setting change device processing of FIG. First, the main control means 100 sets the RWM address (F200H) of the stack area in the SP register, and then initializes the RWM address (steps S50 to S56). After activating the timer interrupt processing and transmitting a setting change operation start command to the sub-control means 200, and waiting for a predetermined time, "88" is displayed on the acquired number display 28 and the set value is displayed. The current set value is displayed on the display 87, and the address value (F000) of the set value data is set in the HL register (steps S58 to S70).

  Next, the main control means 100 determines whether or not the set value data stored in the RWM address (F000) specified by the value of the HL address is within a normal numerical range (step Sd10). Specifically, a comparison operation process (subtraction process) between the value stored in the RWM address F000 and 6 is executed. If the carry flag becomes 1, the judgment result of step Sd10 becomes YES (within a normal numerical range), and if the carry flag becomes 0, the judgment result of step Sd10 becomes NO (out of a normal numerical range). If the decision result in the step Sd10 is NO, 00H is stored in the RWM address (F000) specified by the value of the HL register (or the data of the RWM address F000 is cleared) (step Sd12).

  When the result of the determination in step Sd10 is YES, or when the processing in step Sd12 is performed, the main control unit 100 reads the set value data from the RWM address (F000) specified by the value of the HL address, and It is set in the A register (step Sd14). Then, it is determined whether or not the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sd16). If the value of the door switch signal is 1, the result of the determination in step Sd16 is YES, and the main control means 100 sets the D0 bit (setting / reset button) in the input port 0 rising data stored in the RWM address F020. It is determined whether or not the value of the signal rising data is 1 (step Sd18). Here, if the value of the D0 bit is 1, the judgment result is YES, and if the value of the D0 bit is 0, the judgment result is NO.

  If the decision result in the step Sd18 is YES, the main control means 100 updates the set value data (step Sd20). Here, 1 is added to the value of the A register, and the numerical value range of the addition result does not exceed 0 to a designated maximum value (here, 5 is designated). Is performed). That is, 1 is added to the set value data set in the A register in step Sd14, and if the added result is 5 or less, the value of the added result is used as it is in the A register. Is exceeded, the value of the A register is set to 0.

  Then, the value set in the A register is stored in the RWM address F000 as updated set value data (step S80). If the result of the determination in step Sd16 or Sd18 is NO, and the process proceeds to step S80, the set value data read from the RWM in step Sd14 is stored as it is. Next, the main control means 100 waits for the execution of the timer interrupt processing, and then determines whether or not the start switch sensor signal has risen (steps S82 and S84). If the start switch sensor signal has not risen, the determination result is NO, and the process returns to step Sd14. On the other hand, when the start switch sensor signal rises, the determination result is YES, and the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 again. It is determined whether or not (Step Sd22). When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Sd22 is performed again. The determination process of step Sd22 is repeated until the determination result becomes YES.

  On the other hand, when the value of the D2 bit becomes 1, the determination result in step Sd22 becomes YES, and the process proceeds to step S86, where the value of the D1 bit (setting key switch signal falling data) of the data stored in the RWM address F021 is set. Is determined to be 1 (step S86). When the value of the falling data of the setting key switch signal is 0, the determination result of step S86 is NO, and the determination process of step Sd22 is performed again. As a result, the value of the level data of the door switch signal is 1 (the front door 14 is open) and the value of the falling data of the set key switch signal is 1 (the key switch 82c is turned on from off). , The determination processing of steps Sd22 and S86 is repeated.

  When the result of the determination in step S86 is YES, the main control means 100 clears the display data indicating that the set value is being changed, and then turns on the credit number display 27 and the acquired number display 28, After the set value changing device operation end command is transmitted to the sub control means 200, the game progress main process is started (steps S88 to S94).

[Fifth Embodiment]
Next, a fifth embodiment of the present invention will be described. In this embodiment, as in the third and fourth embodiments, in the setting change device processing, the value of the door switch signal is determined when the setting value data is updated and the setting change device processing ends. The processing related to the update of the set value data is different from the third and fourth embodiments. Hereinafter, the setting change device processing of the present embodiment will be described with reference to the flowchart in FIG.

  Also in the present embodiment, in the input port 0 to 2 read processing in the timer interrupt processing, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. . Further, similarly to the third embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021, and the process of step S618 is performed. It shall be omitted. In the flowchart of FIG. 46, the same steps as those of the setting change device processing shown in FIG. 18 are denoted by the same step numbers, and detailed description thereof will be omitted.

  When the determination result of step S32 of the program start processing shown in FIG. 17 is YES, the main control unit 100 of the present embodiment executes the setting change device processing of FIG. First, the main control means 100 sets the RWM address (F200H) of the stack area in the SP register, and then initializes the RWM address (steps S50 to S56). After activating the timer interrupt processing and transmitting a setting change operation start command to the sub-control means 200, and waiting for a predetermined time, "88" is displayed on the acquired number display 28 and the set value is displayed. The current set value is displayed on the display 87, and the address value (F000) of the set value data is set in the HL register (steps S58 to S70).

  Next, the main control means 100 determines whether or not the set value data stored in the RWM address (F000) specified by the value of the HL address is within a normal numerical range (step Se10). Specifically, a comparison operation process (subtraction process) between the value stored in the RWM address F000 specified by the value of the HL register and 6 is executed. If the carry flag becomes 1, the judgment result of step Se10 becomes YES (within a normal numerical range), and if the carry flag becomes 0, the judgment result of step Se10 becomes NO (out of a normal numerical range). If the judgment result in the step Se10 is NO, 00H is stored in the RWM address (F000) specified by the value of the HL register (or the data of the RWM address F000 is cleared) (step Se12).

  If the result of the determination in step Se10 is YES, or if the processing in step Se12 is performed, then the main control unit 100 sets the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A. It is determined whether or not the value of is 1 (step Se14). If the value of the door switch signal is 1, the result of the determination in step Se14 is YES, and the main control means 100 sets the D0 bit (setting / reset button) in the input port 0 rising data stored in the RWM address F020. It is determined whether or not the value of the signal rising data is 1 (step Se16). Here, if the value of the D0 bit is 1, the judgment result is YES, and if the value of the D0 bit is 0, the judgment result is NO.

  If the decision result in the step Se16 is YES, the main control means 100 sets F000 to the value of the HL register and updates the set value data (step Se18). Here, 1 is added to the value stored in the RWM address specified by the value of the HL register, and the numerical value range of the addition result is from 0 to the specified maximum value (here, 5 is specified). Addition processing is performed so as not to exceed (if it exceeds, the addition result is set to 0). That is, 1 is added to the set value data stored in the RWM address F000, and if the addition result is 5 or less, the value of the addition result is stored in the RWM address F000 as it is. On the other hand, if the result of the addition exceeds 5, 0 is stored in the RWM address F000. It should be noted that the value of the A register is maintained during the processing of step Se18.

  Then, after waiting for the execution of the timer interrupt processing, the main control means 100 determines whether or not the start switch sensor signal has risen (steps S82 and S84). If the start switch sensor signal has not risen, the determination result is NO, and the process returns to step Se14. On the other hand, when the start switch sensor signal rises, the determination result is YES, and the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 again. It is determined whether or not (Step Se20). When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Se20 is performed again. The determination process of step Se20 is repeated until the determination result becomes YES.

  On the other hand, when the value of the D2 bit becomes 1, the determination result in step Se20 becomes YES, and the process proceeds to step S86, where the value of the D1 bit (setting key switch signal falling data) of the data stored in the RWM address F021 is set. Is determined to be 1 (step S86). When the value of the falling data of the setting key switch signal is 0, the determination result of step S86 is NO, and the determination process of step Se20 is performed again. As a result, the value of the level data of the door switch signal is 1 (the front door 14 is open) and the value of the falling data of the set key switch signal is 1 (the key switch 82c is turned on from off). , The determination processing of steps Se20 and S86 is repeated.

  When the result of the determination in step S86 is YES, the main control means 100 clears the display data indicating that the set value is being changed, and then turns on the credit number display 27 and the acquired number display 28, After the set value changing device operation end command is transmitted to the sub control means 200, the game progress main process is started (steps S88 to S94).

[Sixth embodiment]
Next, a sixth embodiment of the present invention will be described. In the present embodiment, as in the third to fifth embodiments, the value of the door switch signal is determined when the setting value data is updated and the setting change device process ends in the setting change device process. The processing related to updating the set value data is different from the third to fifth embodiments. Hereinafter, the setting change device processing of the present embodiment will be described with reference to the flowchart of FIG.

  Also in the present embodiment, in the input port 0 to 2 read processing in the timer interrupt processing, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. . Further, similarly to the third embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021, and the process of step S618 is performed. It shall be omitted.

  Further, in the present embodiment, F022 is assigned as an address for storing set value display data (hereinafter, referred to as “set value display data”). Here, the set value display data is data referred to when the set value is displayed on the set value display 87, and like the set value data, the set value display data also corresponds to the set values (1 to 6). To a value of 0 to 5. In the third to fifth embodiments, the set value data is updated according to the rise of the set / reset button signal, but in the present embodiment, the set value display data is updated.

  Further, in the flowchart of FIG. 47, steps for performing the same processing as the setting change apparatus processing illustrated in FIG. 18 are denoted by the same step numbers, and detailed description thereof will be omitted.

  When the determination result of step S32 of the program start processing shown in FIG. 17 is YES, the main control unit 100 of the present embodiment executes the setting change device processing of FIG. First, the main control means 100 sets the RWM address (F200H) of the stack area in the SP register, and then initializes the RWM address (steps S50 to S56). Then, the timer interrupt process is started, and a setting change operation start command is transmitted to the sub-control means 200, and the process waits for a predetermined time (steps S58 to S66).

  Next, the main control means 100 reads the set value data stored in the RWM address (F000) specified by the value of the HL address, and sets the read data in the A register (step Sf10). Then, it is determined whether or not the set value data set in the A register is within a normal numerical range (step Sf12). That is, 6 is subtracted from the value set in the A register, and if the carry flag becomes 1, the determination result of step Sf12 becomes YES (within a normal numerical range), and if the carry flag becomes 0, the process proceeds to step Sf12. The judgment result is NO (out of the normal numerical range).

  If the decision result in the step Sf12 is NO, the value of the A register is set to 0 (step Sf14). Specifically, an XOR operation is performed on the value of the A register with the same value, and the operation result is set in the A register. Then, the value of F022H is set to the HL address, and the value of the A register (data read from the RWM in step Sf10 or 0) is stored in the RWM address (F022) specified by the value of the HL address (step Sf16).

  Next, the main control means 100 displays "88" on the acquired number display 28, displays the current set value on the set value display 87, and displays the value of the RWM address of the set value display data in the HL register (F022). Is set (steps S68 to S70). Then, the setting value display data is read from the RWM address (F022) specified by the value of the HL address and set in the C register (step Sf18). Next, the main control means 100 determines whether or not the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sf20). If the value of the door switch signal is 1, the result of the determination in step Sf20 is YES, and the main control means 100 outputs the D0 bit (setting / reset button) in the input port 0 rising data stored in the RWM address F020. It is determined whether or not the value of the signal rising data is 1 (step Sf22). Here, if the value of the D0 bit is 1, the judgment result is YES, and if the value of the D0 bit is 0, the judgment result is NO.

  If the decision result in the step Sf22 is YES, the main control means 100 updates the set value display data (step Sf24). Specifically, the value of the C register is set in the A register, 1 is added to the value of the A register, and the numerical value range of the addition result is from 0 to the designated maximum value (here, 5 is designated). Addition processing is performed so as not to exceed (if it exceeds, the addition result is set to 0). That is, 1 is added to the value of the set value display data set in the A register, and if the added result is 5 or less, the value of the A register is maintained as it is, but the added result exceeds 5 In this case, the value of the A register is set to 0. Then, the value of the A register is set in the C register.

  Next, the main control means 100 waits for the execution of the timer interrupt processing, and then determines whether or not the start switch sensor signal has risen (steps S82 and S84). If the start switch sensor signal has not risen, the determination result is NO, and the process returns to step Sf18. On the other hand, if the start switch sensor signal has risen, the determination result is YES, and the value set in the C register is stored in the RWM address F000 (step S28).

  Then, the main control means 100 determines again whether the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sf30). When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Sf30 is performed again. The determination process of step Sf30 is repeated until the determination result becomes YES. On the other hand, when the value of the D2 bit becomes 1, the determination result in step Sf30 becomes YES, and the process proceeds to step S86, where the value of the D1 bit (setting key switch signal falling data) of the data stored in the RWM address F021 is set. Is determined to be 1 (step S86).

When the value of the falling data of the setting key switch signal is 0, the determination result of step S86 is NO, and the determination process of step Sf30 is performed again. As a result, the value of the level data of the door switch signal is 1 (the front door 14 is open) and the value of the falling data of the set key switch signal is 1 (the key switch 82c is turned on from off). , And the determination processing of steps Sf30 and S86 is repeated. When the result of the determination in step S86 is YES, the main control means 100 clears the display data indicating that the set value is being changed, and then turns on the credit number display 27 and the acquired number display 28, After the set value changing device operation end command is transmitted to the sub control means 200, the game progress main process is started (steps S88 to S94).
[Seventh embodiment]
Next, a seventh embodiment of the present invention will be described. In the present embodiment, as in the third to sixth embodiments, the value of the door switch signal is determined when the setting value data is updated and the setting changing device processing ends in the setting changing device processing. In the present embodiment, the set value display data is updated in the same manner as in the sixth embodiment, but the processing contents are different from those in the sixth embodiment. Hereinafter, the setting change device processing of the present embodiment will be described with reference to the flowchart of FIG.

  Also in the present embodiment, in the input port 0 to 2 read processing in the timer interrupt processing, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. . Further, similarly to the third embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021, and the process of step S618 is performed. It shall be omitted. Also, as in the sixth embodiment, the setting value display data is stored at the RWM address F022.

  Further, in the flowchart of FIG. 48, steps that perform the same processing as the processing of the setting change device shown in FIG.

  When the determination result of step S32 of the program start process shown in FIG. 17 is YES, the main control unit 100 of the present embodiment executes the setting change device process of FIG. First, the main control means 100 sets the RWM address of the stack area in the SP register, and then initializes the RWM address (steps S50 to S56). Then, the timer interrupt process is started, and a setting change operation start command is transmitted to the sub-control means 200, and the process waits for a predetermined time (steps S58 to S66).

  Next, after setting the value of F022H in the HL address, the main control unit 100 reads out the set value data stored in the RWM address F000, and reads the RWM address (F022. Set value display data) designated by the value of the HL address. Is stored (step Sg10). Then, it is determined whether or not the set value display data stored at the RWM address specified by the value of the HL address is within a normal numerical range (step Sg12). Specifically, 6 is subtracted from the value stored in the RWM address F022, and if the carry flag becomes 1, the determination result of step Sg12 becomes YES (within a normal numerical range), and the carry flag becomes 0. In this case, the result of the determination in step Sg12 is NO (out of the normal numerical range). If the decision result in the step Sg12 is NO, 0 is stored in the RWM address specified by the value of the HL address (step Sg14).

  Here, the processing of steps Sg10 to g14 is performed on the value stored in the RWM, and is executed by directly specifying the address of the RWM without using a register of the CPU.

  If the decision result in the step Sg12 is NO, or if the process in the step Sg14 is performed, the main control means 100 displays “88” on the acquired number display 28 and displays the current set value on the set value display 87. It is displayed (steps S68 to S70). Then, it is determined whether or not the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sg16). If the value of the door switch signal is 1, the judgment result in the step Sg16 becomes YES, and the main control means 100 outputs the D0 bit (setting / setting) in the input port 0 rising data stored in the RWM address F020. It is determined whether the value of the reset button signal rise data) is 1 (step Sg18). Here, if the value of the D0 bit is 1, the judgment result is YES, and if the value of the D0 bit is 0, the judgment result is NO.

  If the decision result in the step Sg18 is YES, the main control means 100 updates the set value display data (step Sg20). Specifically, 1 is added to the value of the set value display data stored in the RWM address (F022) specified by the value of the HL register, and the numerical value range of the addition result is from 0 to the specified maximum value (here, In this case, it is assumed that 5 is specified.) The addition processing is performed so as not to exceed (if it exceeds, the addition result is set to 0). That is, if the added result is 5 or less, the value of the added result is stored in the RWM address F022 as it is. On the other hand, when the result of the addition exceeds 5, 0 is stored in the RWM address F022. It should be noted that the value of the A register is maintained during the processing of step Se18.

  Next, the main control means 100 waits for the execution of the timer interrupt processing, and then determines whether or not the start switch sensor signal has risen (steps S82 and S84). If the start switch sensor signal has not risen, the determination result is NO, and the process returns to step Sg16. On the other hand, if the start switch sensor signal has risen, the determination result is YES, and the main control means 100 stores the signal in the RWM address (F022) specified by the value set in the HL register. The value of the set value data is stored in the RWM address F022 (step Sg22).

  Then, the main control means 100 determines whether or not the value of the D2 bit (door switch signal) of the input port 0 level data stored in the RWM address F00A is 1 (step Sg24). When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Sg24 is performed again. The determination process of step Sg24 is repeated until the determination result becomes YES. On the other hand, when the value of the D2 bit becomes 1, the determination result of step Sg24 becomes YES, and the process proceeds to step S86, where the value of the D1 bit (setting key switch signal falling data) of the data stored in the RWM address F021 is set. Is determined to be 1 (step S86).

  When the value of the falling data of the setting key switch signal is 0, the determination result of step S86 is NO, and the determination process of step Sg24 is performed again. As a result, the value of the level data of the door switch signal is 1 (the front door 14 is open) and the value of the falling data of the set key switch signal is 1 (the key switch 82c is turned on from off). , And the determination processing of steps Sg24 and S86 is repeated. When the result of the determination in step S86 is YES, the main control means 100 clears the display data indicating that the set value is being changed, and then turns on the credit number display 27 and the acquired number display 28, After the set value changing device operation end command is transmitted to the sub control means 200, the game progress main process is started (steps S88 to S94).

  In the above-described sixth and seventh embodiments, the address for storing the set value display data is provided in the RWM. However, this address is an error executed when the power is restored (the program start process in FIG. 17). The process is executed when the condition for shifting to the setting change mode (for example, the setting change device process of FIG. 47) is satisfied (step S28, YES) under the situation where it is determined that there is no abnormality in the determination process (step S32, YES). The address (for example, F050) is the target of the RWM clear (for example, S52 to S56 in FIG. 47). On the other hand, the RWM address of the set value data is an address (F000) that is not a target of the RWM clear executed when the transition condition of the setting change mode is satisfied under the situation where it is determined that there is no abnormality when the power is restored. Has become. As described above, the setting value display data is stored in the address to be subjected to the RWM clear executed when the transition condition of the setting change mode is satisfied under the situation where it is determined that there is no abnormality when the power is restored, The following advantages are obtained by using the RWM address.

  For example, while the staff of a game arcade are updating the set value, they want to check the set value before performing the update work (hereinafter, referred to as “initial set value”) (for example, Even if the user is worried that a set value different from the set value set by the staff may have been displayed now, the original set value can be displayed. For example, when the RWM address of the setting value display data is not provided, the value stored in the address (F000) of the setting value data is updated by operating the setting / reset switch 82c. At this time, once the set value is updated, the value stored in the address of the set value data is overwritten with the updated value, so there is no way to confirm the original set value.

  On the other hand, when the RWM address of the set value display data is provided, the set value display data is updated during the work of updating the set value, and when the update work is completed (in other words, when the set value after the update is determined. If the value of the set value display data is reflected in the set value data in ()), the value of the set value data maintains the original set value while the set value is being updated. Therefore, when it is desired to confirm the original set value again during the update of the set value, the power switch 82a is turned off during the update, the key switch 82b is turned on, and the power switch 82a is turned on again. Thus, the set value before the update of the set value can be displayed on the set value display 87 again. On the other hand, if an unintended power interruption (for example, when the power is accidentally turned off) occurs while the staff of the game arcade is changing the set value (that is, while executing the setting change device processing). By turning off the key switch 82b and then turning on the power switch 82a while the power is off, when the power is cut off, processing is performed from the middle of the setting change device processing based on the return address stored in the stack area. Can be resumed.

  Note that "1" to "6" (the set value data is "0" to "5") is stored in the RWM address of the set value display data for displaying the set value on the set value display 87. You may do so. Specifically, when data is stored in the RWM address of the set value display data based on the set value data, a value obtained by adding “1” to the value of the set value data is stored as the set value display data, Based on the operation of the reset switch 82c, the value of the set value display data is processed to circulate between “1” to “6”, and the RWM address of the set value display data can be stored. Thereby, the LED display processing shown in FIG. 23 can be simplified (specifically, step S562 is omitted), and the execution time of the timer interrupt processing shown in FIG. 22 can be reduced. Further, the set value data is referred to when performing various lottery processes such as a winning lottery process (see step S112 in FIG. 19) and an error check process for determining whether or not the set value is within a normal numerical range. For the sake of convenience, it is desirable to manage in the numerical range of “0” to “5”. On the other hand, since the set value display data is not referred to in the above-described processing, even if the data is managed by “1” to “6”, the influence is not so large as compared with the set value data.

  In the above-described sixth and seventh embodiments, the timing at which the updated set value display data is reflected on the set value data is triggered by the operation of the start switch 36 (step S84, YES), but is not limited to this. Instead, for example, when the falling data of the setting key switch signal becomes 1 (step S86, YES), it may be reflected on the setting value data.

  In the setting change device processing according to the third to seventh embodiments, the level data of the input port 0 and the rising / falling data of the input port 0 are processed by the timer interrupt processing (more specifically, the input port 0 of FIG. 24). ２2 reading process), the setting change device process in each embodiment is based on the level data of the input port 0 obtained in the timer interrupt process. Rise data may be generated. Further, the level data of the input port 0 may be acquired during the setting change device processing in each embodiment, and the rising data may be generated based on the acquired level data.

[Eighth Embodiment]
Next, an eighth embodiment of the present invention will be described. In the second embodiment, the open / closed state of the door switch signal is determined when displaying the set value and when ending the display of the set value in the game medal insertion standby display process. In the third to seventh embodiments, in the setting change device processing, the open / closed state of the door switch signal is determined when changing the set value and when ending the change processing of the set value. . On the other hand, in the present embodiment, in the error display processing of FIG. 21 executed when a recoverable error occurs, when the error is canceled by operating the setting / reset switch 82c, the door switch signal is not output. The open / close state is determined.

  Here, in the input port 0 to 2 read processing of the present embodiment, the processing of steps S608 and S610 shown in FIG. 24 is omitted, and the process directly proceeds from step S606 to step S612. Also, as in the second embodiment, in this embodiment, the rising data generated in step S614 of FIG. 24 is stored in the RWM address F020, and the falling data generated in step S616 is stored in the RWM address F021. The processing in step S618 is omitted.

  FIG. 49 shows a flowchart of the error display processing in the present embodiment. In this figure, steps for performing processing similar to the error display processing shown in FIG. 21 are denoted by the same step numbers, and detailed description thereof will be omitted.

  First, the main control means 100 stores the error number in the RWM address F014, saves the state of the blocker signal and the hopper motor drive signal before the occurrence of the error, turns off the blocker of the selector 80, and sets the game start display LED Is turned off, an error display start command corresponding to the generated error is transmitted to the sub-control means 200 (steps S200 to S212).

  Next, the main control means 100 determines whether or not the value of the D2 bit door switch signal is 1 in the input port 0 level data stored in the F00A of the RWM address (Step Sh10). Here, when storing the input port 0 level data in the RWM address F00A, a signal input in negative logic may be converted into positive logic before being stored. When the value of the D2 bit is 0, the determination result is NO, and the determination process of Step Sh10 is performed again. The determination process of Step Sh10 is repeated until the determination result becomes YES. On the other hand, when the value of the D2 bit becomes 1, the result of the determination at step Sh10 becomes YES, and the main control means 100 sets the D0 bit (setting / reset button signal rising data) of the data stored in the RWM address F020. It is determined whether the value is 1 (step S214).

  When the value of the rising data of the setting / reset button signal is 0, the determination result of step S214 is NO, and the determination process of step Sh10 is performed again. Thereby, the value of the level data of the door switch signal is 1 (the front door 14 is open) and the value of the rising data of the setting / reset button signal becomes 1 (the setting / reset switch 82b is turned on). , The determination processing of steps Sh10 and S214 is repeated. When the result of the determination in step S214 is YES, the main control means 100 sets the value of the D0 bit (setting / reset button signal rising data) of the data stored in the RWM address F020 to 0 (step S216).

  Then, the main control means 100 checks the input state of the generated recoverable error (steps S218 to 228), and determines whether or not the error factor has been removed (step S230). If it is determined that the error factor has not been removed, the process returns to step Sh10. If it is determined that the error factor has been removed, the error number stored in the RWM is cleared and an error display end command is transmitted to the sub control means 200. (Steps S232 to S236). Then, the hopper motor drive signal and the blocker signal are returned to the state before the occurrence of the error (steps S238 to S244). The error display processing of FIG. 49 ends.

(Modification of the eighth embodiment)
In the error display processing of FIG. 49, the determination of the rising of the setting key switch signal in step S214 is performed based on the value of the rising data (D2 bit) of the setting key switch signal stored in the RWM address F00D. This data is generated by the processing of steps S612 to S616 of the input port 0 to 2 read processing (FIG. 24) executed in the timer interrupt processing (FIG. 22).

  However, the rising data of the signal input to the input port 0 may be generated when a recoverable error occurs. Therefore, a case where rising data of the setting key switch signal is generated in the error display processing will be described with reference to the flowchart of FIG.

  In the error display processing shown in FIG. 50, the same steps as those in the error display processing shown in FIG. 49 are denoted by the same step numbers, and detailed description thereof will be omitted. In this modification, the input port 0 level data acquired during the play error display processing of FIG. 49 is stored in the RWM address F00A. The contents of bits D0 to D7 stored in RWM address F00A are the same as the contents of bits D0 to D7 stored in RWM address F00A (see FIG. 13).

  When the error display processing shown in FIG. 50 is started, the main control means 100 stores the error number in the RWM address F014, saves the state of the blocker signal and the hopper motor drive signal before the occurrence of the error, and then starts the blocker of the selector 80. After the game start display LED is turned off and the game start display LED is turned off, an error display start command corresponding to the generated error is transmitted to the sub control means 200 (steps S200 to S212).

  Next, the main control means 100 sets the value of F00AH in the HL register, reads the signal currently input to the input port 0, sets the signal in the A register (step Si10), and sets the D2 bit of the A register (door switch). It is determined whether or not the value of the signal is 1 (step Si12). When the value of the D2 bit is 0, the determination result is NO, and the determination process of step Si10 is performed again. The determination processes of steps Si10 and Si12 are repeated until the determination result becomes YES. On the other hand, when the value of the D2 bit becomes 1, the determination result in step Si12 becomes YES, and the main control means 100 sets the value of 00000001B in the C register as the detection data of the setting / reset switch (step Si14). Here, the detection data of the setting / reset switch is data for validating only the setting / reset button signal (D0 bit) of the input port 0 level data. At this time, the value of F00A (the address for storing the input port 0 level data) is set in the HL register by the processing of step Si10.

  Next, the main control means 100 performs a rising check process of FIG. 42 to generate rising data of the setting / reset button signal (step Si16). That is, the input port 0 level data is read from the RWM address F00A and set in the B register. Then, the value of the A register (the input signal of the input port 0 read in step Si10) is stored in the RWM address F00A and the input port 0 is stored. The level data is updated (FIG. 42, steps Sb100 to Sb102).

  Next, the main control means 100 calculates change bit data by XORing the value of the A register and the value of the B register, and compares the result with the value of the input port 0 level data stored in the RWM address F00A. Is AND-operated to generate rising data of the signal input to the input port 0. The rising data and the setting / reset switch detection data (00000001B) set in the C register are AND-operated to make only the rising data of the setting / reset button signal valid. (FIG. 42, steps Sb104 to Sb106)

  After finishing the processing of step Si16, the main control means 100 determines whether or not the setting / reset button signal has risen (step S214). Specifically, it is determined whether or not the value of the zero flag is 0. If the value of the zero flag is 0, the determination result is YES, and if the value of the zero flag is 1, the determination result is NO. When the determination result of step S214 is NO, the determination process of step Si10 is performed again. On the other hand, if the decision result in the step S214 is YES, the input state of the generated recoverable error is checked (steps S218 to S228), and it is determined whether or not the error factor has been eliminated (step S218). S230). If it is determined that the error factor has not been removed, the process returns to step Si10. If it is determined that the error factor has been removed, the error number stored in the RWM is cleared and an error display end command is transmitted to the sub-control unit 200. (Steps S232 to S236). Then, the hopper motor drive signal and the blocker signal are returned to the state before the occurrence of the error (steps S238 to S244). The error display processing of FIG. 50 ends.

[Modification of input port 0 to 2 read processing]
In the read processing of the input ports 0 to 2 shown in FIG. 24, when generating the rising data and the falling data of the signal input to the input port 0, the open / close state of the front door 14 is checked and the front door 14 is closed. If so, rising data and falling data are not generated (step S608, NO → S610). However, when generating the rising data and the falling data of the signal input to the input port 0, it is not always necessary to associate the determination result of the open / close state of the front door 14.

  Thus, in this modification, in the input port 0 to 2 read processing, the determination of the open / closed state of the front door 14 and the generation of the rising data and the falling data of the signal input to the input port 0 are individually performed. Will be described. Hereinafter, with reference to the flowchart of FIG. 51, the input port 0 to 2 read processing of this modification will be described.

  In the flowchart shown in FIG. 51, steps for performing the same processing as the input port 0 to 2 read error display processing shown in FIG. 24 are denoted by the same step numbers, and detailed description thereof will be omitted. In this modification, as shown in FIG. 51, it is assumed that an RWM address F017 for storing switch valid data is determined. The switch valid data is used to determine whether the rising data or falling data to be determined is valid when judging the values of the rising data and falling data of the signal input to the input port 0. Data. Here, the switch valid data when the front door 14 is open is 11111111B, and the switch valid data when the front door 14 is closed is 11111000B.

  When the input port 0 to 2 read processing of FIG. 51 is started, first, the main control means 100 acquires each signal input to the input port 0, converts a signal of negative logic into positive logic, and then outputs unused signals. The bit value is invalidated, and the input port 0 level data stored in the RWM is updated (steps S600 to S606). Next, it is determined whether or not the value of the D2 bit (door switch signal) in the input port 0 level data is 1 (the front door 14 is open) (step S608). If the value of the D2 bit is 1, the determination result is YES, and 11111111B is stored in the RWM address F017 as switch effective data (step Sj10). If the value of the D2 bit is 0, the determination result is NO. Then, 11111000B is stored in the RWM address F017 as switch effective data (step Sj12).

  Then, after performing the processing in step Sj10 or Sj12, the main control unit 100 generates rising data and falling data of each signal input to the input port 0 and stores the generated data in the RWM address F00D (steps S612 to S618). ). Next, rising data of each signal input to the input port 1 and the input port 2 is generated and stored in the corresponding RWM address (steps S620 to S628 → input port data set processing in FIG. 25).

  When performing the above-described input port 0 to 2 read processing, for example, when performing the processing of steps Sa10 and S140 in the game medal insertion standby display processing shown in FIG. 40, first, the setting key stored in the RWM address F00D AND operation is performed on the set / reset button edge data and the switch valid data stored in the RWM address F017, and the determination in step S140 is made based on the value of the D2 bit in the operation result. That is, if the value of the D2 bit is 1, it indicates that the key switch 82b has been turned on from the off state with the front door 14 open. On the other hand, if the value of the D2 bit is 0, it indicates that the key switch 82b has not been turned on from the off state while the front door 14 is open.

  When performing the processing of steps Sa12 and S150, the setting key and the setting / reset button edge data stored in the RWM address F00D and the switch valid data stored in the RWM address F017 are AND-operated. The determination in step S150 is performed based on the value of the D0 bit in the operation result. That is, if the value of the D0 bit is 1, it indicates that the key switch 82b has been turned off from on while the front door 14 is open. On the other hand, if the value of the D0 bit is 0, it indicates that the key switch 82b has not been turned off from on while the front door 14 is open.

  Similarly, when performing the setting change device processing shown in FIGS. 44 to 48 and the error display processing shown in FIG. 49, when determining the rising or falling of the signal input to the input port 0, the rising or falling data is used. By performing an AND operation with the switch valid data, it is possible to determine the rise or fall of various signals including the open / closed state of the front door 14 as a condition.

  In the first to eighth embodiments, processing for generating rising data indicating that the signal input to the input port has changed from off to on (for example, steps S612 and S614 in FIG. 24, the rising data in FIG. 42). The check processing) corresponds to information generation means for generating state change information indicating whether or not the state has changed from the first state to the second state. Further, the processing of generating falling data indicating that the signal input to the input port has changed from on to off (for example, steps S612 and S616 in FIG. 24, the falling check processing in FIG. 43) is performed in the second state. It corresponds to information generating means for generating state change information indicating whether or not the state has changed from the first state to the first state.

[Modification]
(1) Generation of Rising Data and Falling Data In steps S612 to S616 in FIG. 24, and in the rising check processing in FIG. 42 and the falling check processing in FIG. 43, the state of the level data of various signals has changed from the previous state. Sometimes, instead of immediately generating rising data or falling data, rising data or falling data may be generated when the changed state continues a plurality of times.

  In the input port 0 to 2 read processing shown in FIG. 51, instead of storing the switch valid data corresponding to the opening and closing of the front door 14 in the RWM, when the front door 14 is closed, the data is stored in the RWM. Alternatively, the signal rising data or falling data to be determined and the level data may be cleared.

(2) About error release by keypad When a recoverable error occurs, when the keypad inserted into the door key 31 shown in FIG. 1 is turned counterclockwise, the setting / reset switch 82c shown in FIG. 2 is operated. It is assumed that the same error can be released (reset) as when the error has been reset. However, when the error is released by the keypad, even if the front door 14 is closed, the generated recoverable error can be released. Good. In this case, the types of errors that can be cleared while the front door 14 is closed may be limited to a part (for example, empty errors (HE errors) can be cleared, but medal jam errors (HP errors) and payout errors (H0). Error), insertion sensor passing error (CE error), medal insertion error (CP error), medal retention error (CH error), insertion sensor error (C0 error), medal passing error (C1 error), etc. It cannot be released without operating 82c). For example, in the case of an empty error, it is released by operating the setting / reset switch 82c, and the hopper motor 46 is driven to discharge medals from the medal discharge port 60. At this time, when a medal is put in the hopper 83a and the setting / reset switch 82c is operated in a state where the front door 14 is open, the medal jumps out because the front door 14 is open. There is a risk of falling on the floor of a game arcade. For this reason, in the case of an empty error, the setting / reset switch 82c can be operated (or the error is released by turning the key of the door key 31 to the left) while the front door 14 is closed. Is preferred.

  Further, in this case, a mechanism that can turn the keypad counterclockwise only when the front door 14 is closed may be provided. Of course, the present invention is not limited to the case where an empty error has occurred, and the keypad can be turned counterclockwise (it can function as a reset switch) when the front door 14 is closed. A mechanism may be provided so that the key cannot be turned counterclockwise when the key 14 is open. Further, even if the keypad can be turned counterclockwise even when the front door 14 is open, the keypad is turned counterclockwise in the main control means 100 when the front door 14 is open. In this case, the error may not be canceled by, for example, invalidating that the key is turned counterclockwise.

(3) Acquisition of Door Switch Signal When determining whether or not the door switch signal is on in the main game progress processing, the data of the input port 0 is directly acquired, and the D2 bit (door It may be determined whether the door switch signal is ON based on the data of the switch signal). Such processing is applicable to all embodiments. The process of determining whether or not the door switch signal is ON can be determined, for example, by determining whether or not the door is open for a predetermined time (for example, about 0.5 seconds: 250 interrupts). For example, the door opening error data is stored in a predetermined storage area (address) of the RWM on condition that the door is opened for a predetermined time. If the door opening error data is stored at the address, it is determined that the front door 14 is open, and if the door opening error data is not stored, the front door 14 is closed. It can be determined. In other words, the wording of “door switch signal on” (for example, step S608 in FIG. 24, step Sa10 in FIG. 40, etc.) described in the present specification and the drawings is changed to “door open error data exists” or “door switch signal It can be replaced with a phrase such as "ON for a predetermined time".

As described above, determining whether the front door 14 is open for a predetermined time has the following advantages.
(A) For example, even in a situation where the front door 14 is closed due to cheating, a board, a harness, or the like to which a door switch signal is input so that the gaming machine can recognize that the front door 14 is open. There is a risk that a signal indicating that the front door 14 is open may be input as a signal input to the input port via the conductive member. However, since the condition that the front door 14 is open for a predetermined time in order to determine that the front door 14 is opened is a condition, it is difficult to satisfy the condition for deeming the front door 14 to be open due to the above-described misconduct. Becomes
(A) There is a possibility that a noise signal due to radio waves, static electricity, or the like may be mixed into a signal input to the input port and recognized as a signal indicating that the door switch is open. Therefore, the condition that the front door 14 is open for a predetermined period of time to determine that the front door 14 is open is determined, and it is determined that the front door 14 is erroneously opened by the noise signal as described above. There is a low possibility of being performed.
(C) When detecting the open / closed state of the front door 14 by turning on / off the door switch 44, chattering occurs in the door switch 44 when the front door 14 is opened and closed, and the accurate open / closed state cannot be detected. There is a fear. Therefore, by setting the condition that the front door 14 is open for a predetermined period of time as a condition for determining that the front door 14 is open, the influence of chattering generated by the door switch 44 can be reduced.

(4) Processing after the end of the setting change mode and the setting confirmation mode In the setting change mode and the setting confirmation mode, when the key switch 82b is turned off and each mode is ended, the standby game display or the normal effect image is displayed on the image display device 70. When the key switch 82b is turned off, the fact that the front door 14 is open is notified, and after the front door 14 is closed, the standby game display or the normal effect image is displayed. Is also good. Specifically, a command indicating that the front door 14 was opened when the front door 14 was opened was transmitted from the main control unit 100 to the sub-control unit 200, and when the front door 14 was closed, the command was closed. Command to indicate that this is the case. When the staff at the game hall opens the front door 14 to perform a setting change operation or a setting confirmation operation, a command indicating the opening is transmitted to the sub-control unit 200, and the sub-control unit 200 checks that the front door 14 is open. Notify. Then, the mode shifts to the setting change mode or the setting confirmation mode through a predetermined procedure. When the sub-control means 200 receives the setting change device operation start command or the set value display start command, the mode shifts to the effect setting mode. When the setting change mode or the setting confirmation mode ends and the sub-control means 200 receives the setting change device operation end command or the set value display end command, the sub-control means 200 informs again that the front door 14 is open. . Then, when the front door 14 is closed and the sub-control means 200 receives a command indicating that, the standby game display or the normal effect image is displayed. Here, when the sub-control means 200 receives a command indicating that the front door 14 is closed, it may be notified that the front door 14 has been closed.

  When the above-described door opening error can be detected, the following processing may be performed. When a predetermined time elapses after the front door 14 is opened for the staff of the game hall to perform the setting change operation or the setting confirmation operation, the main control unit 100 determines that the door opening error has occurred, and sends the door to the sub control unit 200. Send the release error display command. When the sub-control means 200 receives this command, it reports that a door opening error has occurred. Then, the mode shifts to the setting change mode or the setting confirmation mode through a predetermined procedure. When the sub-control means 200 receives the setting change device operation start command or the set value display start command, the mode shifts to the effect setting mode. When the setting change mode or the setting confirmation mode ends and the sub control means 200 receives the setting change device operation end command or the set value display end command, the sub control means 200 notifies again that the door opening error has occurred. Then, when the error recovery operation is performed and the error return command (8100) is transmitted from the main control means 100, the sub control means 200 ends the notification indicating that the door opening error has occurred, and displays the standby game display or A normal effect image is displayed.

  The first embodiment to the eighth embodiment can be appropriately combined, and further, each embodiment or a combination thereof can be appropriately combined with each modified example.

DESCRIPTION OF SYMBOLS 10 Slot machine 12 Main part 14 Front door 21 Display window 26a, 26b, 26c Bet number display lamp 27 Credit number display 28 Acquired number display 33 Clearing switch 34 1-Bet switch 35 Maximum bet switch 36 Start switch 37L, 37C, 37R Stop switch 38 Selection switch 39 Decision switch 40L, 40C, 40R Reel 42L, 42C, 42R Stepping motor 43L, 43C, 43R Reversing body sensor 44 Door switch 46 Hopper motor 47a, 47b Discharge sensor 48a, 48b Input sensor 49 Medal passage sensor 52L, 52R Side lamp 64L, 64R Speaker 70 Image display device 72 Effect lamp 74L, 74R Decoration lamp 80 Selector 82 Power supply unit 82a Power supply Switch 82b key switch 82c setting / reset switch 83 medal payout device 84 medal auxiliary storage 86 external centralized terminal board 87 set value display 100 main control means 110 winning combination determination means 120 freeze control means 130 reel control means 140 state control means 142 RT state control means 144 Game state control means 150 Notification game control means 160 Winning determination means 170 Abnormality detection means 180 Control command transmission means 190 External signal transmission means 200 Sub-control means 202 Sub-control board 204 Image control board 210 Production control means 212 Effect lottery means 214 Effect state control means 220 Control command receiving means 230, 240 Sub-control command transmitting / receiving means 250 Image / sound output means

Claims (1)

Predetermined display means capable of displaying a set value,
Image display means,
First operating means;
And second operating means,
When the first operation means is operated, the mode shifts to a menu mode ,
When the mode is shifted to the menu mode by operating the first operation unit when the setting mode is not the setting check mode in which the setting value can be checked, an item for displaying an error history in the menu mode is displayed on the image display unit. It is possible to display , the item for enabling the power saving setting in the menu mode is configured not to be displayed on the image display means ,
In a case where the operation mode is shifted to the menu mode by operating the first operation means in the setting confirmation mode in which the setting value can be confirmed, an item for displaying an error history in the menu mode is displayed on the image display means. to a displayable a item for enabling power saving setting in the menu mode can be displayed on the image display unit,
If the second operation means is operated while the front door is open and the item for enabling the power saving setting is selected, it is possible to shift to a state where the power saving setting is available. Yes,
Even if the front door is closed, if the second operation means is operated while the item for enabling the power saving setting is selected, the state shifts to the state where the power saving setting is available. A gaming machine characterized by being made possible.

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