JP2002058834A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine giving no disadvantage to a player for value payoff even when a power stoppage state occurs and preventing a problem for control caused by a momentary interruption of a power supply or the like. SOLUTION: A delivery control substrate stores the number of unpaid-off rental balls on a backup RAM(random access memory) so that the payoff control of game mediums can be resumed based on the number of the unpaid-off rental balls when the power feed is resumed. A reset management circuit feeding a reset signal and a recovery signal to electric component control substrates is mounted on a power substrate. When a standby state is continued for a prescribed period after a power feed stop process, the reset management circuit outputs the recovery signal for the recovery from the standby state to the payoff control substrate. No disadvantage is given to the player for the value payoff, and a problem for control caused by a momentary interruption of the power supply can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a game machine such as a pachinko game machine, a coin game machine, a slot machine, etc., in which a game is played in accordance with a player's operation. A gaming machine in which a game is played in accordance with a game machine.

[0002]

2. Description of the Related Art As a gaming machine, a game medium such as a game ball is launched into a game area by a launching device, and when a game medium wins a winning area such as a winning opening provided in the game area, a predetermined number of prize balls are obtained. Some values are paid out to players. The payout of the game medium is performed by a payout mechanism.

The payout mechanism is generally controlled by prize ball control means mounted on a payout control board. Since the progress of the game is controlled by the game control means mounted on the main board, the number of winning balls based on the winning is determined by the game control means and transmitted to the payout control board.

[0004] Further, a player borrows a game medium and plays a game using the borrowed game medium and the game medium paid out according to a prize. At that time, a request for lending a game medium from a player is once received by a lending request processing device such as a card unit, and the lending control means of the gaming machine receives a lending request from the player by communicating with the lending request processing device. A gaming machine lends a game medium in response to a lending request from a player. In many cases, the prize ball control means and the lending control means are constituted by an integrated payout control means. Generally, the payout control means includes a payout control microcomputer.

[0005]

When a power failure occurs due to a power failure or the like in a gaming machine, the power supply is restored from the power failure or the like in the initial state (for example, when the power to the gaming machine is first turned on at the beginning of the day at a game store). State), the player may be disadvantaged. For example, if the power-off state occurs due to a power failure or the like before the payout control means has completed the lending processing of all the game media corresponding to the lending request via the lending request processing device, when the power is restored, When the state of the gaming machine returns to the initial state, unpaid rental game media occurs, which is disadvantageous to the player. Also, if the power-off state due to a power failure or the like occurs before the prize ball payout according to the winning is completed, when the power is restored, the state of the gaming machine returns to the initial state, and the game medium as the prize ball is returned. Unpaid, resulting in disadvantage for the player.

In order to prevent such a problem from occurring, the game control is interrupted in response to a predetermined signal generated as the power supply voltage value decreases, and the game state at that time is changed with respect to the game machine. Even when the power supply is stopped, the power may be stored in the storage unit that is backed up (backup storage unit), and control may be performed so as to wait until the power supply is completely stopped.

However, when the power supply voltage drops for an extremely short period due to a momentary interruption of the power supply, the power supply voltage is immediately restored. In such a case, it is conceivable that the control of the microcomputer cannot completely escape from the state of waiting for the power supply to completely stop. In other words, despite the fact that the power supply to the gaming machine is in a normal state,
It is conceivable that the gaming machine control does not return to the normal state.

Therefore, the present invention can prevent the player from being disadvantaged in paying out the value of the game media and the like even if the power supply is cut off due to a power failure or the like in the game machine, and can be performed in a very short time. It is an object of the present invention to provide a gaming machine that does not hinder control even when a power supply to be restored is momentarily interrupted.

[0009]

A gaming machine according to the present invention comprises:
A gaming machine that allows a player to play a predetermined game, and includes a payout control unit and a payout unit (for example, a ball payout device 97 that pays out a game medium in response to a lending request. The paying-out means to be paid out and the paying-out means to pay out according to a prize may be formed integrally or separately from each other. The paying-out means may be stored in the same case or may be stored in another case.) And a fluctuation data storage means for storing fluctuation data generated when performing control (for example, , RAM) and the final storage contents of the fluctuation data storage means immediately before the stop of the power supply (the contents of the final control state immediately before the stop of the power supply, stored when the game is interrupted due to the stop of the power supply) Can be held) Storage means and a power supply monitoring means for monitoring the state of a predetermined power supply, and the fluctuation data can specify the number of unpaid payouts for which payout has not been completed among the payout numbers of game media based on the loan request. The payout control means can restart the payout control of the game medium based on the data which can specify the unpaid number held by the storage content holding means when the power supply is restarted. A configuration in which, when it is detected by the power supply monitoring unit that the state of the predetermined power supply has reached a predetermined state, a standby state is performed after performing a power supply stop time process related to storage of the control state. A return signal for returning from the standby state when the power supply is not stopped after a predetermined period has elapsed after the power supply monitoring unit detects that the predetermined state has been reached. It is characterized in that it comprises an output capable of returning the signal output means towards the control means.

A game medium detecting means (for example, a prize ball count switch 301A, a ball lending count switch 301B) for detecting a game medium is provided. When it is detected that the state has been reached, the input processing of the detection signal from the game medium detecting means is executed for a predetermined period, and then the power supply stop related to the saving of the control state including the data capable of specifying the number of unpaid items is performed. It is preferable to perform time treatment.

When the power supply monitoring means detects that the state of the power supply has reached a predetermined state, the payout control means stops the driving of the payout means and then detects the game medium from the game medium detection means. It is preferable to execute a signal input process.

After the power supply monitoring means detects that the state of the power supply has reached a predetermined state, the payout control means and the game It is preferable to include an auxiliary drive power supply unit that can supply a power supply that can drive the medium detection unit.

The payout control means can control the payout of the game medium in accordance with the progress of the game.
It may include data that can specify the number of unpaid payouts for which payout has not been completed among the number of payouts of game media according to the progress of the game.

It is preferable that a prize game medium detecting means and a lending game medium detecting means are separately provided as game medium detecting means.

A return signal for returning from the standby state may be input to a reset signal input section of the electric component control means.

[0016] A plurality of electric component control means may be provided, and the return signal output means may include a start order control means for controlling a start order by making the output order of the return signal to each electric component control means different.

The electric component control means includes game control means for controlling the progress of the game, and other electric component control means for controlling the electric components in response to a control signal from the game control means. Alternatively, the game control means may be activated last.

It is preferable that the payout control means execute a process of prohibiting access to the variable data storage means in the process at the time of power supply stop.

A power supply board for generating a voltage used in each electric component control board may be provided separately from the electric component control means on which the electric component control means is mounted, and the return signal output means may be mounted on the power supply board. .

[0020]

An embodiment of the present invention will be described below with reference to the drawings. First, the overall configuration of a pachinko gaming machine, which is an example of a gaming machine, will be described. FIG. 1 is a front view of the pachinko gaming machine 1 as viewed from the front. Here, a pachinko gaming machine is shown as an example of a gaming machine, but the present invention is not limited to a pachinko gaming machine, and may be, for example, a coin gaming machine or a slot machine.

As shown in FIG. 1, the pachinko gaming machine 1
It has a glass door frame 2 formed in a frame shape. On the lower surface of the glass door frame 2, there is a hit ball supply tray 3. Below the hitting ball supply tray 3, a surplus ball receiving tray 4 for storing game balls overflowing from the hitting ball supply tray 3 and a hitting operation handle (operation knob) 5 for firing a hitting ball are provided. Behind the glass door frame 2,
The game board 6 is detachably attached. A game area 7 is provided on the front of the game board 6.

In the vicinity of the center of the game area 7, a variable display section (special symbol display device) 9 for variably displaying a plurality of types of symbols and an ordinary symbol display (ordinary symbol display device) 10 using 7-segment LEDs are provided. A variable display device 8 is provided. In the variable display section 9, for example, "left", "middle",
There are three symbol display areas of "right". Variable display device 8
Is provided with a passage gate 11 for guiding a hit ball. The hit ball that has passed through the passing gate 11 is guided to the starting winning opening 14 via the ball exit 13. In a passage between the passage gate 11 and the ball outlet 13, there is a gate switch 12 for detecting a hit ball that has passed through the passage gate 11. The winning ball that has entered the starting winning port 14 is guided to the back of the game board 6 and detected by the starting port switch 17. In addition, a variable winning ball device 15 that performs opening and closing operations is provided below the starting winning port 14. The variable winning ball device 15 is opened by the solenoid 16.

An opening / closing plate 20 which is opened by a solenoid 21 in a specific game state (big hit state) is provided below the variable winning ball apparatus 15. In this embodiment, the opening and closing plate 20 serves as a means for opening and closing the special winning opening. A winning ball that has entered one (V zone) of the winning balls guided from the opening / closing plate 20 to the back of the game board 6 is detected by the V winning switch 22. The winning ball from the opening / closing plate 20 is detected by the count switch 23. At the bottom of the variable display device 8, the number of winning balls entering the starting winning opening 14 is displayed.
A start winning storage display 18 having a plurality of display units is provided. In this example, the start winning prize storage display 18 increases the number of lit display units by one each time there is a starting prize, with the upper limit being four. Then, each time the variable display of the variable display unit 9 is started, the number of the lit display units is reduced by one.

The gaming board 6 is provided with a plurality of winning ports 19 and 24, and the winning of the game balls into the respective winning ports 19 and 24 is determined by setting the corresponding winning port switches 19a and 19a.
19b, 24a and 24b. At the left and right sides of the game area 7, there are provided decorative lamps 25 which are displayed blinking during the game, and at the lower part there is an out port 26 for absorbing hit balls which have not won. In addition, two speakers 27 that emit sound effects are provided at upper left and right sides outside the game area 7. A gaming effect LED 2 is provided on the outer periphery of the gaming area 7.
8a and gaming effect lamps 28b and 28c are provided.

In this example, one of the speakers 27
Prize ball lamp 5 that lights up when there are remaining prize balls near
1 is provided, and near the other speaker 27, a ball-out lamp 52 is provided, which lights up when the supply ball is out. Further, FIG. 1 also shows a card unit 50 that is installed adjacent to the pachinko gaming machine 1 and that allows a ball to be lent by inserting a prepaid card.

The card unit 50 has a usable indicator lamp 151 for indicating whether or not the card can be used. If there is a fraction (less than 100 yen) in the balance information recorded in the card, the fraction is displayed. Fraction display switch 1 for displaying on a frequency display LED provided near hit ball supply tray 3
52, a connecting stand direction indicator 15 indicating which side of the pachinko gaming machine 1 the card unit 50 corresponds to
3. Card insertion indicator 154 indicating that a card has been inserted into card unit 50, card insertion slot 155 into which a card as a recording medium is inserted, and a card reader provided on the back of card insertion slot 155 A card unit lock 156 is provided to release the card unit 50 when checking the mechanism of the writer.

The hit ball fired from the hitting ball launching device enters the game area 7 through the hitting rail, and thereafter, the game area 7
Come down. When a hit ball is detected by the gate switch 12 through the passage gate 11, the number displayed on the symbol display 10 normally changes. When a hit ball enters the starting winning opening 14 and is detected by the starting opening switch 17,
If the change of the symbol can be started, the symbol in the variable display section 9 starts rotating. If it is not possible to start changing the symbol, the start winning memory is increased by one.

The rotation of the image in the variable display section 9 stops when a certain time has elapsed. If the combination of images at the time of stop is a combination of big hit symbols, the game shifts to a big hit game state. That is, the opening / closing plate 20 is opened until a predetermined time elapses or until a predetermined number (for example, 10) of hit balls is won. When the hit ball wins in the specific winning area while the opening and closing plate 20 is being opened and is detected by the V winning switch 22, a continuation right is generated and the opening and closing plate 20 is opened again. The continuation right is generated a predetermined number of times (for example, 15 rounds)
Permissible.

If the combination of images in the variable display section 9 at the time of stoppage is a combination of big hit symbols with probability fluctuation, the probability of the next big hit becomes high. That is, a high probability state, which is more advantageous for the player, is obtained. When the stop symbol on the ordinary symbol display 10 is a predetermined symbol (hit symbol = small hit symbol), the variable winning ball device 15 is opened for a predetermined time. Further, in the high probability state, the probability that the stop symbol on the ordinary symbol display 10 hits the symbol is increased, and the opening time and the number of times the variable winning ball device 15 is opened are increased.

Next, each board disposed on the back of the pachinko gaming machine 1 will be described. As shown in FIG. 2, on the back surface of the pachinko gaming machine 1, a ball storage tank 38 is provided above the mechanism plate in the frame 2A, and above the pachinko gaming machine 1 installed on the gaming machine installation island. The game ball is supplied to the ball storage tank 38 from. The game balls in the ball storage tank 38 pass through a guiding gutter 39 to reach a ball dispensing device covered with a prize ball case 40A.

On the back side of the gaming machine, a variable display control unit 29 for controlling the variable display section 9 and a game control board (main board) 31 on which a game control microcomputer and the like are mounted are installed. A payout control board 37 on which a payout control microcomputer or the like for performing ball payout control is mounted;
And a hit ball launching device that launches a hit ball into the game area 7 using the rotational force of a motor. Furthermore, the decoration lamp 25, the game effect LED 28a, the game effect lamp 28
b, 28c, a lamp control board 35 for sending signals to the prize ball lamp 51 and the ball out lamp 52, a voice control board 70 for controlling the generation of voice from the speaker 27, and a launch control for controlling the hit ball launching device. A substrate 91 is also provided.

Further, DC30V, DC21V, DC1
A power supply board 910 on which a power supply circuit for generating 2V and 5V DC is mounted is provided, and a terminal board 1 provided with terminals for outputting various information to the outside of the gaming machine is provided above.
60 are installed. The terminal board 160 has at least an out-of-ball terminal for introducing and outputting the output of the out-of-ball detection switch, an award ball terminal for externally outputting the award ball number signal, and an externally outputting ball lending number signal. A ball lending terminal is provided. In the vicinity of the center, an information terminal board 34 having terminals for outputting various information from the main board 31 to the outside of the gaming machine is provided. In FIG. 2, signals from the lamp control board 35 and the sound control board 70 are supplied to the game effect LEDs 28a, game effect lamps 28b and 28c, the prize ball lamp 51, and the ball cut lamp 52 provided on the frame side. Although the electric relay board A77 for performing the above is shown, other relay boards are provided as necessary for signal relay.

FIG. 3 is a rear view of the mechanical plate of the pachinko gaming machine 1 as viewed from the rear. The balls stored in the ball storage tank 38 pass through the guide gutter 39, pass through the ball cut detectors (ball cut switches) 187a and 187b, and are dispensed through the ball supply gutters 186a and 186b, as shown in FIG. The device 97 is reached. The ball out switches 187a and 187b are switches for detecting the presence or absence of a game ball in the game ball passage.
67 is also provided. Hereafter, the ball out switch 187
a, 187b may be expressed as a ball-out switch 187.

The game balls paid out from the ball payout device 97 are supplied to the hitting plate 3 provided on the front face of the pachinko gaming machine 1 through the communication port 45. On the side of the communication port 45, an excess ball passage 46 communicating with the excess ball tray 4 provided on the front of the pachinko gaming machine 1 is formed.

A number of prize balls are paid out based on the prize, and the hitting ball supply plate 3 becomes full.
When the game balls are further paid out after reaching 5, the game balls are guided to the surplus ball tray 4 via the surplus ball passage 46. When the game balls are further paid out, the sensing lever 47 presses the full tank switch 48 and the full tank switch 48 is turned on. In this state, the rotation of the stepping motor in the ball discharging device 97 stops, the operation of the ball discharging device 97 stops, and the driving of the hitting ball firing device also stops.

Next, the structure of the intermediate base unit installed on the mechanism plate 36 will be described. The intermediate base unit includes the ball supply gutters 186a and 186b and the ball discharging device 9
7 is installed. As shown in FIG. 4, connecting concave protrusions 182 are formed on the upper and lower sides of the intermediate base unit. The connection concave projection 182 connects and fixes the intermediate base unit and the upper base unit and the lower base unit of the mechanism plate 36.

A passage 18 is provided above the intermediate base unit.
4 is fixed. The ball dispensing device 97 is fixed to a lower portion of the passage body 184. The passage body 184 is a payout ball passage 186 that allows two rows of game balls whose flow direction has been changed left and right by the curve gutter 174 (see FIG. 3) to flow down.
a, 186b. Dispensing ball passages 186a, 186b
On the upstream side of the ball, ball breaking switches 187a and 187b are provided. The ball out switches 187a and 187b
It detects the presence or absence of a game ball in the payout ball passages 186a and 186b, and detects a ball out switch 187a or 187b.
Stops detecting the game ball, the rotation of the payout motor (not shown in FIG. 4) in the ball payout device 97 is stopped, and the ball payout is immobilized.

It should be noted that the ball out switches 187a, 187b
Is locked by a locking piece 188 at a position where it can be detected that about 27 to 28 game balls exist in the payout ball paths 186a and 186b. That is, the out-of-ball switches 187a and 187b are the maximum payout amount of one unit of the prize ball (15 in this embodiment) and the maximum payout amount of one unit of the ball lending (100 yen: 25 in this embodiment).
It is installed in a position where it can be confirmed that the above is secured.

The central portion of the passage body 184 is formed in a shape curved right and left so as to reduce the ball pressure of the game ball flowing down inside. And the payout ball passages 186a, 186b
A stop hole 189 is formed therebetween. The mounting boss provided on the intermediate base unit is fitted into the back surface of the stop hole 189. The set screw is screwed in that state,
The passage body 184 is fixed to the intermediate base unit. Before being screwed, the positioning of the passage body 184 can be performed by a locking projection 185 provided on the intermediate base unit.

Below the passage body 184, a ball payout device 97 is provided.
To supply the game balls to the ball, and in the event of failure, the ball payout device 9
A ball stopping device 190 for stopping the supply of game balls to the game ball 7 is provided. The ball dispensing device 97 installed below the ball stopping device 190 is housed inside a rectangular parallelepiped case 198. Protrusions are provided at four places on the left and right of the case 198. The lower end of the case 198 is fitted into an elastic engagement piece provided at a lower portion of the intermediate base unit with each projection being related to a positioning projection provided on the intermediate base unit.

FIG. 5 is an exploded perspective view of the ball payout device 97. The configuration and operation of the ball payout device 97 will be described with reference to FIG. Ball payout device 97 in this embodiment
, A stepping motor (payout motor) 289 rotates a screw 288 to pay out pachinko balls one by one. The ball payout device 97 pays out not only premium balls based on winnings but also game balls to be lent.

As shown in FIG. 5, the ball dispensing device 97
There are two cases 198a and 198b. The ball dispensing device 9 is provided at two places on the left and right of each case 198a, 198b.
7 is provided with an engagement projection 280 that is in contact with a positioning projection provided at the upper part of the installation position. In each case 198a, 198b, a ball supply path 281a,
81b are formed. Ball supply path 281a, 281b
Has curved surfaces 282a and 282b, and has curved surfaces 282a and 282b.
Below the end of 282b, there is a ball feed horizontal path 284a, 2
84b are formed. In addition, ball feed horizontal path 284
Ball discharge passages 283a and 283b are formed at the ends of a and 284b.

The ball supply paths 281a and 281b, the ball feed horizontal paths 284a and 284b, and the ball discharge paths 283a and 283b.
Are formed in front of partition walls 295a and 295b that partition the cases 198a and 198b forward and backward, respectively.
Further, in front of the partition walls 295a and 295b, a ball pressure buffering member 285 is sandwiched between the cases 198a and 198b. The ball pressure buffering member 285 distributes the ball supplied to the ball payout device 97 to the left and right sides and the ball supply paths 281a, 281.
81b.

Further, a payout motor position sensor including a light emitting element (LED) 286 and a light receiving element (not shown) is provided below the ball pressure buffering member 285. Light emitting element 2
86 and the light receiving element are provided at a predetermined interval. The distal end of the screw 288 is inserted into the space. The ball pressure buffering member 28
When the cases 198a and 198b are attached to each other, the case 5 is completely stored and fixed therein.

The ball feed horizontal paths 284a and 284b have a screw 28 rotated by a payout motor 289.
8 are arranged. The payout motor 289 is fixed to the motor fixing plate 290, and the motor fixing plate 290 is
Fixing grooves 291a, 2 formed behind 5a, 295b
Fits into 91b. In this state, the motor shaft of the dispensing motor 289 projects forward of the partition walls 295a, 295b, so that the screw 288 is fixed forward of the projection. On the outer periphery of the screw 288, a spiral protrusion 288a for moving the game ball placed on the ball feed horizontal path 284a, 284b forward by the rotation of the payout motor 289.
Is provided.

A recess is formed at the tip of the screw 288 so as to house the light emitting element 286, and two notches 292 are formed 180 degrees apart from each other on the outer periphery of the recess. Therefore, while the screw 288 makes one rotation, the light from the light emitting element 286 is
Is detected twice by the light receiving element via the.

That is, the dispensing motor position sensor including the light emitting element 286 and the light receiving element is for stopping the screw 288 at the fixed position and detecting that the dispensing operation has been performed. The wires from the light emitting element 286, the light receiving element, and the payout motor 289 are collectively pulled out to the outside through drawout holes formed below the rear portions of the cases 198a, 198b, and connected to the connector.

When the game ball is a ball-feeding horizontal path 284a, 284b
When the payout motor 289 rotates in a state where the screw 288 is placed on the
The game ball moves forward on the ball feeding horizontal paths 284a and 284b. And finally, ball feed horizontal path 28
4a, 284b from the end of the ball discharge path 283a, 283b
To fall. At this time, the left and right ball feed horizontal paths 284a,
The drop from 284b is performed alternately. That is, every time the screw 288 makes a half turn, one game ball falls from one side. Therefore, every time one game ball falls, light from the light emitting element 286 is detected by the light receiving element.

As shown in FIG. 4, below the ball payout device 97, a ball distribution member 311 is provided. The ball distribution member 311 is driven by the distribution solenoid 310.
For example, when the solenoid 310 is on, the ball sorting member 3
11 falls to the right, and when off, falls to the left. Below the distribution solenoid 310, a prize ball count switch 301A and a ball lending count switch 3 by a proximity switch are provided.
01B is provided. At the time of prize ball based on winning,
The ball distribution member 311 falls to the right side, and the ball discharge paths 283a, 283
The balls from 83b are both prize ball count switches 301A
Pass through. Also, at the time of lending a ball, the ball distribution member 311 falls to the left, and the balls from the ball discharge paths 283a and 283b both pass through the ball lending count switch 301B. Accordingly, the ball payout device 97 can switch the payout flow path between the time of winning a ball and the time of lending a ball, and can pay out a predetermined number of game media.

By providing the ball sorting member 311 in this manner, the balls falling down the two ball passages can receive the prize ball count switch 301A and the ball lending count switch 30.
1B. Therefore,
The number of prize balls or the number of ball lending can be immediately grasped from the detection output of the prize ball counting switch 301A and the ball lending count switch 301B without determining whether the ball is a prize ball or a ball lending.

In this embodiment, a ball payout device 97 that pays out game balls by the rotation of a stepping motor is used as a ball payout device that pays out game balls by driving an electric drive source. A ball payout device having a structure in which a game ball is sent out by a driving source of the above may be used, or a ball payout device having a structure in which a stopper is removed by driving an electric drive source to pay out the game ball by its own weight may be used. In this embodiment, the ball payout device 97 pays out both a prize ball based on a prize ball and a loaned ball based on a loan request, but a payout device may be provided for each.

FIG. 6 is a block diagram showing an example of the circuit configuration of the main board 31. FIG. 6 also shows a payout control board 37, a lamp control board 35, a voice control board 70, a firing control board 91, and a symbol control board 80. On the main board 31, a basic circuit 53 for controlling the pachinko gaming machine 1 according to a program, a gate switch 12,
Starting port switch 17, V winning switch 22, count switch 23, winning port switches 19a, 19b, 24a,
24b, the full tank switch 48, the ball out switch 187, and the switch circuit 58 that supplies signals from the prize ball count switch 301A to the basic circuit 53, and the variable prize ball device 1
A solenoid 16 for opening / closing the opening 5, a solenoid 21 for opening / closing the opening / closing plate 20, and a solenoid circuit 59 for driving a solenoid 21 A for switching a path in the special winning opening in accordance with a command from the basic circuit 53 are mounted.

Although not shown in FIG. 6, the count switch short-circuit signal is also transmitted to the basic circuit 53 via the switch circuit 58.

According to the data supplied from the basic circuit 53, jackpot information indicating occurrence of a jackpot, effective start information indicating the number of start winning balls used to start image display on the variable display section 9, and probability fluctuation have occurred. An information output circuit 64 for outputting an information output signal such as probability change information indicating the fact to an external device such as a hall computer is mounted.

The basic circuit 53 includes a ROM 54 for storing a game control program and the like, a RAM 55 as an example of a storage means used as a work memory, a CPU 56 for performing a control operation according to the program, and an I / O port unit 5.
7 inclusive. In this embodiment, the ROM 54 and the RAM 5
5 is built in the CPU 56. That is, the CPU 5
Reference numeral 6 denotes a one-chip microcomputer. In addition, 1
The chip microcomputer has at least the RAM 55
And the ROM 54 and the I / O port unit 57 may be external or internal.

A hit ball launching device that hits and launches a game ball is driven by a drive motor 94 controlled by a circuit on a launch control board 91. Then, the driving force of the driving motor 94 is adjusted according to the operation amount of the operation knob 5. That is, the circuit on the firing control board 91 is controlled so that the hit ball is fired at a speed corresponding to the operation amount of the operation knob 5.

In this embodiment, a reset signal whose low level indicates a reset state, a low-active return signal, and a low-active power-off signal are also input from the power supply substrate 910 to the main substrate 31. The reset signal and the return signal are input to the AND circuit 161 and the AND circuit 1
The output of 61 is input to the reset terminal of the CPU 56.
In addition, the power-off signal is output from the non-maskable interrupt (N
MI) terminal. Further, although not explicitly shown in FIG. 6, a RAM (a RAM with a built-in CPU may be used)
At least a part of 55 is backed up by a backup power supply created in the power supply board 910. That is, even if the power supply to the gaming machine is stopped,
During a predetermined period, at least a part of the contents of the RAM 55 is stored.

In this embodiment, the lamp control means mounted on the lamp control board 35 is used to display the start storage display 18, the gate passage storage display 41 and the decoration lamp 25 provided on the game board. Controls the game and the game effect lamp / LED 28 provided on the frame side.
a, 28b, and 28c, display control of the award ball lamp 51, and the ball out lamp 52 are performed. The display control of the variable display unit 9 for variably displaying special symbols and the ordinary symbol display 10 for variably displaying ordinary symbols is performed by display control means mounted on the symbol control board 80.

FIG. 7 is a block diagram showing components related to payout, such as components of the payout control board 37 and the ball payout device 97. As shown in FIG. 7, the detection signal from the full tank switch 48 is transmitted to the main board 3 via the relay board 71.
1 is input to the I / O port unit 57. The full tank switch 48 is a switch that detects whether the excess ball tray 4 is full. In addition, the ball out switch 187 (187a, 187)
The detection signal from b) is also used for the relay board 72 and the relay board 7.
1 is input to the I / O port unit 57 of the main board 31.

The CPU 56 of the main board 31 checks whether the detection signal from the ball out switch 187 indicates that the ball is out.
Alternatively, when the detection signal from the full tank switch 48 indicates the full tank state, a payout control command to instruct payout prohibition is transmitted. When receiving the payout control command instructing the payout prohibition, the payout control CPU 37 of the payout control board 37
1 stops the ball payout process.

Further, the detection signal from the prize ball count switch 301A is input to the relay board 72 and the I / O port section 57 of the main board 31 via the relay board 71, and the payout control is performed via the relay board 72. It is input to the input port 372b of the substrate 37. Prize ball count switch 30
1A is provided in the payout mechanism portion of the ball payout device 97, and detects a prize ball payout ball actually paid out.

When there is a prize, the payout control board 37 has output ports (ports 0, 1) 570, 571 of the main board 31.
, A payout control command indicating the number of winning balls is input. The output port (output port 1) 571 outputs 8-bit data, and the output port 570 outputs a 1-bit strobe signal (INT signal). The payout control command indicating the number of winning balls is input to the I / O port 372a via the input buffer circuit 373A. The INT signal is input to the interrupt terminal of the payout control CPU 371 via the input buffer circuit 373B. The payout control CPU 371
A payout control command is input via the / O port 372a, and the ball payout device 97 is driven in accordance with the payout control command to perform award ball payout. In this embodiment, the payout control CPU 371 is a one-chip microcomputer and has at least a RAM.

In the main board 31, the output port 5
Buffer circuits 620 and 68A are provided outside 70 and 571. As the buffer circuits 620 and 68A, for example, 74HC250 and 7HC which are general-purpose CMOS-ICs
4HC14 is used. According to such a configuration, since a signal inputted from the outside to the inside of the main board 31 is blocked, a signal line to which a signal may be given from the payout control board 37 to the main board 31 is further reliably eliminated. be able to. Note that a noise filter may be provided on the output side of the buffer circuits 620 and 68A.

The payout control CPU 371 is connected to the output port 3
A ball lending number signal indicating the number of lending balls is output to the terminal board 160 via 72c. Further, the output port 37
An error signal is output to the error display LED 374 via 2d.

Further, the input port 3 of the payout control board 37
The detection signal from the ball lending count switch 301B is input to 72b via the relay board 72. The ball lending count switch 301B is provided in the payout mechanism portion of the ball payout device 97, and detects the actually paid lending balls.
The drive signal from the payout control board 37 to the payout motor 289 is supplied to the payout motor 28 in the payout mechanism of the ball payout device 97 via the output port 372c and the relay board 72.
9 and the drive signal to the distribution solenoid 310 is
The distribution solenoid 310 in the dispensing mechanism of the ball dispensing device 97 via the output port 372e and the relay board 72.
Conveyed to.

The card unit 50 is provided with a microcomputer for controlling the card unit. Also,
The card unit 50 is provided with a fraction display switch 152, a connection board direction indicator 153, a card insertion indicator lamp 154, and a card insertion slot 155 (see FIG. 1). The balance display board 74 is connected to a frequency display LED, a ball lending switch, and a return switch provided near the hit ball supply tray 3.

From the balance display board 74 to the card unit 50
In response to the operation of the player, a ball lending switch signal and a return switch signal are given via the payout control board 37. In addition, the balance display board 74 is provided from the card unit 50.
, A card balance display signal indicating the balance of the prepaid card and a ball lending possible display signal are given via the payout control board 37. Between the card unit 50 and the payout control board 37, a connection signal (VL signal) and a unit operation signal (B
RDY signal), ball lending request signal (BRQ signal), ball lending completion signal (EXS signal) and pachinko machine operation signal (P
RDY signal) is input port 372b and output port 3
It is exchanged via 72e.

When the power of the pachinko gaming machine 1 is turned on,
The payout control CPU 371 of the payout control board 37 outputs a PRDY signal to the card unit 50. The card unit control microcomputer outputs a VL signal. The payout control CPU 371 determines the connection state / non-connection state based on the input state of the VL signal. When the card is accepted in the card unit 50 and the ball lending switch is operated to input a ball lending switch signal, the microcomputer for controlling the card unit outputs a BRDY signal to the payout control board 37. When a predetermined delay time has elapsed from this point, the microcomputer for controlling the card unit outputs a BRQ signal to the payout control board 37.

The payout control board 37 of the payout control board 37
When the PU 371 raises the EXS signal to the card unit 50 and detects the fall of the BRQ signal from the card unit 50, it drives the payout motor 289 and pays out a predetermined number of loaned balls to the player. At this time, the distribution solenoid 310 is in a driving state. That is, the ball distribution member 311 is directed to the ball lending side. When the payout is completed, the payout control CPU 371 sets the card unit 5
The EXS signal for 0 falls. Thereafter, if the BRDY signal from the card unit 50 is not in the ON state,
The winning ball payout control is executed.

As described above, all signals from the card unit 50 are input to the payout control board 37. Therefore, regarding the ball lending control, the card unit 5
No signal is input from 0 to the main board 31, and there is no room for a signal to be incorrectly input from the card unit 50 side to the basic circuit 53 of the main board 31. The power supply voltage AC24V used in the card unit 50 is supplied from the payout control board 37.

In this embodiment, a reset signal, a return signal, and a power-off signal are also input from power supply board 910 to payout control board 37. The reset signal and the return signal are input to the AND circuit 385, and the output of the AND circuit 385 is input to the reset terminal of the payout control CPU 371. The power-off signal is input to a non-maskable interrupt (NMI) terminal of the payout control CPU 371. further,
RAM (RAM with built-in CPU) existing on the payout control board 37
It may be. At least a part of the power supply board 91
0 is backed up by a backup power supply created at 0. That is, even if the power supply to the gaming machine is stopped, at least a part of the contents of the RAM is stored for a predetermined period.

In this embodiment, the case where the card unit 50 is installed separately from the gaming machine and adjacent to the gaming machine is described as an example, but the card unit 50 is integrated with the gaming machine. You may. Also, the present invention can be applied to a case where a game ball corresponding to the amount of money is lent out according to insertion of a coin.

FIG. 8 shows the circuit configuration in the symbol control board 80 by changing the output port (port 0, port 0, 2) It is a block diagram shown together with 570, 572 and output buffer circuits 620, 62A. Output port (output port 2) 572 outputs 8-bit data, and output port 570 outputs a 1-bit strobe signal (INT signal).

As shown in FIG. 8, the display control CPU 10
1 is supplied with a reset signal from the power supply board 910. When the reset signal is low level, the display control C
The PU 101 is in a reset state, and when the reset signal goes high, the display control CPU 101 is in an operable state.

The display control CPU 101 controls the control data R
It operates according to the program stored in the OM 102, and receives an INT signal from the main board 31 via the noise filter 107 and the input buffer circuit 105B, and receives a display control command via the input buffer circuit 105A. As the input buffer circuits 105A and 105B, for example, 74HC540 and 74HC14, which are general-purpose ICs, can be used. When the display control CPU 101 does not include an I / O port, an I / O port is provided between the input buffer circuits 105A and 105B and the display control CPU 101.

Then, the display control CPU 101 controls the display of the screen displayed on the LCD 82 according to the received display control command. Specifically, a command corresponding to the display control command is given to the VDP 103. VDP103
Reads necessary data from the character ROM 86. The VDP 103 controls the LCD 8 according to the input data.
2 to generate image data to be displayed on the LCD 2, and output R, G, B signals and a synchronization signal to the LCD 82.

FIG. 8 also shows a reset circuit 83 for resetting the VDP 103, an oscillation circuit 85 for supplying an operation clock to the VDP 103, and a character ROM 86 for storing frequently used image data. The frequently used image data stored in the character ROM 86 is, for example, a person, an animal, or an image composed of characters, figures, or symbols displayed on the LCD 82.

The input buffer circuits 105A and 105B
Signals can be passed only in the direction from the main board 31 to the symbol control board 80. Therefore, the symbol control board 8
There is no room for a signal to be transmitted from the 0 side to the main board 31 side. That is, the input buffer circuits 105A and 105B together with the input ports constitute irreversible information input means. Even if the circuit in the symbol control board 80 is tampered with, the signal output by the tampering is not transmitted to the main board 31 side.

The outputs of the output ports 570 and 572 may be directly output to the symbol control board 80, but the output buffer circuits 620 and 62A capable of transmitting signals only in one direction.
, The main board 31 to the symbol control board 8
One-way signal transmission to 0 can be more reliably performed. That is, the output buffer circuits 620 and 62A constitute irreversible information output means together with the output port.

Further, for example, a three-terminal capacitor or a ferrite bead is used as the noise filter 107 for cutting off the high-frequency signal. The effect is eliminated. Note that a noise filter may be provided on the output side of the buffer circuits 620 and 62A of the main board 31.

FIG. 9 is a block diagram showing a signal transmitting / receiving portion in the main board 31 and the lamp control board 35.
In this embodiment, a game effect LED 28a and game effect lamps 28b, 28 provided outside the game area 7 are provided.
c and lighting / extinguishing of the decorative lamp 25 provided on the game board, and lighting / extinguishing of the prize ball lamp 51 and the ball out lamp 52.
A lamp control command indicating turning off is output from the main board 31 to the lamp control board 35. Also, the start memory display 1
8 and the lamp control command indicating the number of lighting of the gate passage memory display 41 are also transmitted from the main board 31 to the lamp control board 35.
Is output to

The lamp control CPU 351 is supplied with a reset signal from the power supply board 910. When the reset signal is at a low level, the lamp control CPU 351 is in a reset state, and when the reset signal is at a high level, the lamp control CPU 351 is in an operable state.

As shown in FIG. 9, the lamp control command related to the lamp control is output from the output ports (output ports 0, 3) 570, 5 of the I / O port unit 57 in the basic circuit 53.
73. Output port (output port 3) 57
3 outputs 8-bit data, and output port 570 is 1
It outputs a bit INT signal. In the lamp control board 35, a control command from the main board 31 is transmitted to the CPU for lamp control via input buffer circuits 355A and 355B.
351. When the lamp control CPU 351 does not include an I / O port, an I / O port is provided between the input buffer circuits 355A and 355B and the lamp control CPU 351.

In the lamp control board 35, the CPU 351 for lamp control includes a game effect LED 28a, a game effect lamp 28b, and a game effect lamp 28b defined in accordance with each control command.
8c, according to the lighting / extinguishing pattern of the decorative lamp 25,
Game effect LED 28a, game effect lamps 28b, 28
c, output a light-on / light-off signal to the decorative lamp 25; The ON / OFF signal is output to the game effect LED 28a, the game effect lamps 28b and 28c, and the decoration lamp 25. It should be noted that the lighting / extinguishing pattern is determined by the lamp control CPU.
351 is stored in an internal ROM or an external ROM.

On the main board 31, the CPU 56
When there is an unpaid prize ball remaining number in the memory contents of M55, the control command for instructing lighting of the prize ball lamp 51 is output, and the control command is provided upstream of the payout ball passages 186a, 186b on the back of the game board. Ball switch 187a, 187b
When the game ball is no longer detected (see FIG. 3), a control command for instructing lighting of the ball out lamp 52 is output. In the lamp control board 35, each control command is transmitted to the lamp control CPU via input buffer circuits 355A and 355B.
351. The lamp control CPU 351 turns on / off the prize ball lamp 51 and the ball out lamp 52 according to the control commands. The light-on / light-off pattern is stored in a built-in ROM or an external ROM of the lamp control CPU 351.

Further, the lamp control CPU 351 outputs a light-on / light-off signal to the start storage display 18 and the gate passage storage display 41 according to the control command.

As the input buffer circuits 355A and 355B, for example, 74HC54 which is a general-purpose CMOS-IC
0,74HC14 is used. Input buffer circuit 35
5A and 355B are connected to the lamp control board 35 from the main board 31.
The signal can be passed only in the direction toward. Therefore, there is no room for a signal to be transmitted from the lamp control board 35 side to the main board 31 side. For example, even if a circuit in the lamp control board 35 is tampered with, a signal output by the tampering is not transmitted to the main board 31 side. Note that a noise filter may be provided on the input side of the input buffer circuits 355A and 355B.

In the main board 31, the output port 5
Buffer circuits 620 and 63A are provided outside 70 and 573. As the buffer circuits 620 and 63A, for example, 74HC250 and 7HC which are general-purpose CMOS-ICs
4HC14 is used. According to such a configuration, since a signal input from the outside to the inside of the main board 31 is blocked, a signal line to which a signal may be supplied from the lamp control board 70 to the main board 31 is more reliably eliminated. be able to. Note that a noise filter may be provided on the output side of the buffer circuits 620 and 63A.

FIG. 10 is a block diagram showing an example of the configuration of the voice control command signal transmitting portion of the main board 31 and the voice control board 70. In this embodiment, a voice control command for instructing a voice output of the speaker 27 provided outside the game area 7 is output from the main board 31 to the voice control board 70 in accordance with the progress of the game.

The sound control CPU 701 includes a power supply board 9
10, a reset signal is supplied. When the reset signal is at a low level, the audio control CPU 701 is in a reset state, and when the reset signal is at a high level, the audio control CPU 701 is in an operable state.

As shown in FIG. 10, the voice control command is output from output ports (output ports 0, 4) 570, 574 of the I / O port unit 57 in the basic circuit 53. An output port (output port 4) 574 outputs 8-bit data, and an output port 570 outputs a 1-bit INT signal. In the audio control board 70, each signal from the main board 31 is input to the input buffer circuit 70.
The data is input to the voice control CPU 701 via 5A and 705B. If the audio control CPU 701 does not have an I / O port, the input buffer circuit 705A,
An I / O port is provided between the audio control CPU 701 and the audio control CPU 701.

The voice synthesizing circuit 702 using, for example, a digital signal processor is
The sound and the sound effect corresponding to the instruction 01 are generated and output to the volume switching circuit 703. The volume switching circuit 703 sets the output level of the voice control CPU 701 to a level corresponding to the set volume and outputs the output level to the volume amplification circuit 704. The volume amplification circuit 704 outputs the amplified audio signal to the speaker 27.

As the input buffer circuits 705A and 705B, for example, 74HC54 which is a general-purpose CMOS-IC
0,74HC14 is used. Input buffer circuit 70
5A and 705B can pass signals only in the direction from the main board 31 to the voice control board 70. Therefore, there is no room for a signal to be transmitted from the voice control board 70 side to the main board 31 side. Therefore, even if a circuit in the voice control board 70 is tampered with, a signal output by the tampering is not transmitted to the main board 31 side. Note that a noise filter may be provided on the input side of the input buffer circuits 705A and 705B.

In the main board 31, the output port 5
Buffer circuits 620 and 67A are provided outside 70 and 574. As the buffer circuits 620 and 67A, for example, 74HC250 and 7HC which are general-purpose CMOS-ICs
4HC14 is used. According to such a configuration, since a signal input from the outside to the inside of the main board 31 is blocked, a signal line to which a signal may be supplied from the voice control board 70 to the main board 31 is more reliably eliminated. be able to. Note that a noise filter may be provided on the output side of the buffer circuits 620 and 67A.

FIG. 11 shows a payout control board 37 and a firing control board 9 on which a control means for controlling hit ball firing is mounted.
FIG. As shown in FIG. 11, the firing control signal is output from the output port 37 on the payout control board 37.
2d is output to the launch control board 91. In the firing control board 91, the firing control signal from the payout control board 37 is transmitted to the motor drive circuit 813 via the buffer circuit 815.
To enter.

The motor drive circuit 813 controls the drive motor 9 in each period of a ball hitting operation for firing a game ball and a recovery / ball replenishment operation for preparing to fire the next game ball.
4 to generate a voltage for controlling the rotation speed. During the ball hitting operation period, a voltage that gradually increases in accordance with the rotation operation angle with respect to the operation knob 5 is generated.
A predetermined voltage is generated.

The touch sensor circuit 93 outputs a firing permission signal to the motor drive circuit 813 while the human body is in contact with the human body detection electrode attached to the operation knob 5.
The motor drive circuit 813 is supplied with a firing control signal from the payout control board 37. Motor drive circuit 813
When the firing control signal and the firing permission signal are turned on, the switching of the sequence operation during the ball hitting operation period and the recovery / ball replenishment operation period is controlled, and the driving pattern signal and the driving voltage switching signal necessary for driving the driving motor 94 are controlled. Occurs.

FIG. 12 is a block diagram showing a DC voltage and the like supplied from the power supply board 910 to each board. As shown in FIG. 12, a power supply circuit for generating various DC voltages is mounted on a power supply board 910. If necessary, AC2
4V is also supplied to each substrate.

In this embodiment, the main substrate 31 has a D
C30V, DC12V, DC5V and backup power supply voltage (VBB) are supplied. The lamp control board 35 includes DC30V, DC21V, DC12V and DC5V.
V is supplied. 24V AC,
DC30V, DC12V, DC5V and backup power supply voltage (VBB) are supplied. Then, 30 V DC, 12 V DC and 5 V DC are supplied to the launch control board 91. The voice control board 70 is supplied with DC12 and DC5V. The symbol control board 80 includes DC
12V and 5V DC are supplied. Further, a reset signal is supplied from a power supply substrate 910 to each substrate.

As shown in FIG. 12, the ground side of the voltage supplied to each substrate is shared by the power supply substrate 910. Therefore, the ground level in each substrate is common. Then, a voltage level can be used as it is as a signal transmitted from one substrate to another substrate. If there is a substrate whose ground level is not shared, when transmitting signals to such a substrate, it is necessary to use a non-contact type information transmitting means such as a photocoupler, which causes an increase in cost. However, when the ground levels of all the substrates are common as in this embodiment, it is not necessary to use a photocoupler or the like.

FIG. 13 is a block diagram showing a configuration example of a power supply board 910 of a gaming machine. The power supply board 910 is installed independently of the electric component control boards such as the main board 31, the symbol control board 80, the voice control board 70, the lamp control board 35, and the payout control board 37, and controls each of the electric component control boards in the game machine. Generates voltages used by mechanical components. In this example, AC24V, VSL (DC + 30V), DC + 21
V, + 12V DC and + 5V DC. Also,
The capacitor 916 serving as a backup power supply is DC + 5
V, that is, charged from a power supply line for driving an IC or the like on each substrate.

[0102] Transformer 911 converts an AC voltage from an AC power supply to 24V. AC 24V voltage is applied to connector 9
15 is output. Further, the rectifier circuit 912 includes an AC24
A DC voltage of +30 V is generated from V and output to the DC-DC converter 913 and the connector 915. DC-D
C converter 913 includes one or more converters I
C922 (only one is shown in FIG. 13), and generates + 21V, + 12V, and + 5V based on VSL and outputs it to the connector 915. A relatively large-capacity capacitor 923 is connected to the input side of the converter IC 922. Therefore, when the power supply to the gaming machine from the outside is stopped, the DC voltage such as +30 V, +12 V, +5 V, etc., decreases relatively slowly. As a result, the capacitor 923 plays a role of an auxiliary driving power supply described later. The connector 915 is connected to, for example, a relay board, and power of a voltage required for each electric component control board and a mechanical component is supplied from the relay board.

However, the power supply board 910 may be provided with each connector leading to each electric component control board, and the power supply board 910 may supply each voltage reaching each board without passing through the relay board. Further, FIG. 13 shows one connector 915 as a representative, but the connector is provided for each electric component control board.

+5 V from DC-DC converter 913
The line branches to form a backup + 5V line. A large-capacity capacitor 916 is connected between the backup + 5V line and the ground level. The capacitor 916 sets the storage state of the backup RAM (the RAM backed up by the power supply, that is, the storage means that can be in the storage state even when the power supply is stopped) of the electric component control board when the power supply to the gaming machine is cut off. A backup power supply that supplies power so that it can be held. + 5V line and backup + 5V
A diode 917 for preventing backflow is inserted between the line and the line.

A battery that can be charged from a + 5V power supply may be used as a backup power supply. In the case of using a battery, a rechargeable battery is used which runs out of capacity when power is not supplied from a + 5V power supply for a predetermined time.

The power supply board 910 has a power monitoring I
C902 is mounted. The power supply monitoring IC 902
The occurrence of power interruption is detected by introducing the VSL power supply voltage and monitoring the VSL power supply voltage. Specifically, when the VSL power supply voltage falls below a predetermined value (+22 V in this example),
A power-off signal is output on the assumption that power-off occurs. The power supply voltage to be monitored is preferably higher than the power supply voltage (+5 V in this example) of the circuit element mounted on each electric component control board. In this example, VSL, which is a voltage immediately after conversion from AC to DC, is used. The power supply cutoff signal from the power supply monitoring IC 902 is supplied to the main board 31, the payout control board 37, and the like.

The predetermined value for the power supply monitoring IC 902 to detect the power-off is lower than the voltage at the normal time, but is a voltage at which the CPU on each electric component control board can operate for a while. Further, the power supply monitoring IC 902 is configured to monitor a voltage higher than a voltage for driving a circuit element such as a CPU (+5 V in this example) and a voltage immediately after conversion from AC to DC. Therefore, the monitoring range can be extended for the voltage required by the CPU. Therefore,
More precise monitoring can be performed.

Further, VSL (+30 V) is used as the monitoring voltage.
Is used, since the voltage supplied to the various switches of the gaming machine is +12 V, prevention of erroneous switch-on detection upon a momentary power interruption can be expected. That is, by monitoring the voltage of the +30 V power supply, it is possible to detect a decrease in the voltage of +12 V generated after the generation of +30 V before the voltage starts to drop. Therefore, when the voltage of the + 12V power supply decreases, the switch output comes to the on state. However, if the + 30V power supply voltage that drops faster than + 12V is monitored and the power cutoff is recognized, the power supply is turned on before the switch output turns on. It is possible to enter a state of waiting for restoration and to enter a state where the switch output is not detected.

Further, since the power supply monitoring IC 902 is mounted on the power supply board 910 separate from the electric component control board, the power supply monitoring circuit can supply a power-off signal to the plurality of electric component control boards. No matter how many electrical component control boards need a power-off signal, it is sufficient that only one power supply monitoring means is provided. Therefore, even if each electrical component control means in each electrical component control board performs return control described later, However, the cost of gaming machines does not increase much.

In the configuration shown in FIG. 13, the detection output (power cutoff signal) of the power supply monitoring IC 902 is supplied to the respective electric component control boards (for example, the main board 31 and the payout control signal) via buffer circuits 918 and 919. Although transmitted to the board 37), for example, a configuration in which one detection output is transmitted to the relay board, and the same signal is distributed from the relay board to each electric component control board may be employed. Further, a buffer circuit may be provided according to the number of substrates that require a power-off signal.

Further, on the power supply board 910, a reset management circuit 940 for supplying a reset signal and a return signal to each board is mounted. The reset management circuit 940 includes:
It is an example of realization of a boot order control means.

FIG. 14 is a block diagram showing a configuration example of the reset management circuit 940. In the reset management circuit 940, the reset IC 651 in the reset circuit 65
When the power is turned on, the output is set to the low level for a predetermined time determined by the capacity of the external capacitor, and the output is set to the high level after the predetermined time has elapsed. The output of the reset IC 651 is supplied to the buffer circuit 9 via the circuits 941 to 949.
61 to 964 and the delay circuit 960. The output of the delay circuit 960 is input to the buffer circuit 965. Then, the buffer circuits 961 to 965 are supplied as reset signals to the respective electric component control boards. Therefore, when the output of the reset IC 651 becomes high level, the CPU in each electric component control board becomes operable.

The reset IC 651 monitors the power supply voltage VSL, which is the same power supply voltage as the power supply voltage monitored by the power supply monitoring IC 902, and adjusts the voltage value to a predetermined value (the power supply monitoring IC 902 outputs a power-off signal. (Lower than the voltage value). Therefore, CPU
56 and the payout control CPU 371 are power monitoring ICs.
After performing a predetermined power supply stop preparation process in response to the power-off signal from the power supply 902, the system is reset.

As shown in FIG. 14, the reset IC 651
Is input to the NAND circuit 947 and also to the clear terminal of the counter IC 941 via the inverting circuit (NOT circuit) 944. When the input to the clear terminal goes low, the counter IC 941 counts the clock signal from the oscillator 943.
The Q5 output of the counter IC 941 is output to the NOT circuit 9
45, 946 and input to the NAND circuit 947.

The Q6 output of the counter IC 941 is
The clock is input to a flip-flop (FF) 942. The D input of the flip-flop 942 is fixed at a high level, and the Q output is input to an OR circuit (OR circuit) 949. NAN is input to the other input of the OR circuit 949.
The output of the D circuit 947 is introduced via a NOT circuit 948. The output of the OR circuit 949 is supplied to each CPU via the buffer circuits 961 to 965. According to such a configuration, when the power is turned on, two reset signals (low-level signals) are supplied to the reset terminal of each CPU, so that each CPU reliably starts operating.

Then, for example, the detection voltage of the power supply monitoring IC 902 as the power supply monitoring means (the voltage at which the power supply cutoff signal is output) is set to +22 V, and the detection voltage of the reset IC 651 is set to +9 V. In such a configuration, the power supply monitoring means and the reset IC 651 monitor the voltage of the same power supply VSL. Therefore, the timing at which the power supply monitoring means outputs the power cutoff signal and the low level at which the reset IC 651 is at the reset level Can be surely set to a desired predetermined period. The desired predetermined period is a period from the start of the power supply stop preparation process (the process at the time of power supply stop) in response to the power-off signal from the power supply monitoring unit until the process is reliably completed.

In this example, the detection condition under which the power supply monitoring means outputs the detection signal is that the power supply voltage of +30 V is +22.
That is, the condition that the reset IC 651 outputs the low level, which is the reset level, means that the +30 V power supply voltage has dropped to +9 V. However, the voltage value used here is an example, and another value may be used.

However, although the monitoring range is narrowed, it is also possible to use a + 5V power supply voltage as the monitoring voltage of the power supply monitoring means and the reset IC 651. Also in that case, the detection voltage of the power supply monitoring circuit is set higher than the detection voltage of the reset IC 651.

The CP of the main board 31 and the payout control board 37
While power is not being supplied from the + 5V power supply which is the drive power supply of U56 and the payout control CPU 371, at least a part of the RAM is backed up by the backup power supply supplied from the power supply board 910, and the power to the gaming machine is cut off. The contents are also preserved. Then, when the power is restored, the reset signal from the reset management circuit 940 becomes high level, so that the CPU 56 and the payout control C
PU 371 returns to the normal operation state. then,
Since the necessary data is stored in the backup RAM, it is possible to return to the gaming state at the time of power failure occurrence (which may mean immediately before the power supply is stopped) upon recovery from a power failure or the like.

FIG. 14 shows a configuration in which two reset signals (low level signals) are supplied to the reset terminal of the CPU of each electric component control board when the power is turned on.
In the case of using a CPU in which reset is surely released even if the reset signal rises only once, the circuit elements indicated by reference numerals 941 to 949 are unnecessary. In that case, the output of the reset IC 651 is directly connected to the buffer circuits 961 to 964 and the delay circuit 960.

In this embodiment, the power supply board 91
When a reset signal is supplied from 0 to the CPU of each electric component control board, the delay circuit
Delay the reset signal for U56. Therefore, when the power is turned on, the reset signal to the CPU 56 of the main board 31 rises later than the reset signal to the CPUs of the other electric component control boards.

For example, when the CPU 56 of the main board 31 outputs a control command to another electric component control board,
Since the CPUs of the other electrical component control boards have already been started, the control commands are reliably received by the CPU of the electrical component control board on the receiving side.

Further, a counter 971 which is an example of timer means is mounted on the power supply board 910. The counter 971 counts the clock signal from the oscillator 943 when the power-off signal goes low to clear the signal. And when counting up, as Q output,
Generates one high-level pulse. The pulse signal is logically inverted by the inverting circuit 972 and input to the buffer circuit 973 and the delay circuit 974. The delay circuit 974 delays the input signal by a predetermined period and inputs the input signal to the buffer circuit 975.

The output of the buffer circuit 973 becomes a return signal to the payout control board 37. The buffer circuit 975
Is a return signal to the main board 31. The buffer circuits 973 and 975 may be provided on the payout control board 37 and the main board 31.

FIG. 15 is a timing chart for explaining the operation of counter 971. As shown in (A), when the power supply voltage decreases and the voltage value of VSL decreases to the power-off signal output level (+22 V in this example), a power-off signal is generated. Specifically, the power-off signal goes low.
Then, as will be described later, the CPU 31 of the main board 31 and the payout control CPU 371 start execution of the process at the time of power supply stop, and when the process is completed, enters a loop state (standby state) in which no control is performed.

The counter 971 starts counting when the power-off signal goes low. The count-up value is set to VSL after the power-off signal goes low.
Is set to a time equal to or longer than the time during which the voltage value of the voltage is reduced to the voltage capable of generating Vcc. That is, the power supply voltage is set to be at least longer than the time during which the power supply voltage is reduced to a voltage at which the control operation cannot be performed. Since the counter 971 operates using Vcc as a power supply, the count-up value is set to a value equal to or longer than the value corresponding to the operable period of the counter 971. Therefore, in general,
Before the counter 971 counts up and the return signal is output, the counter 971 and other circuit components stop operating.

When an instantaneous interruption of the power supply occurs, as shown in FIG. 15B, the power supply is restored after the voltage level of VSL is reduced for a short period. When the voltage level of VSL becomes equal to or lower than the power-off signal output level, the power-off signal becomes low level, and the process at the time of power supply stop is started. Then, the CPU 56 and the payout control CPU 371 enter a loop state after the end of the power supply stop processing. If no control is performed, the loop processing cannot be exited. In this case, the counter 971 counts up and a return signal is generated.

As shown in FIGS. 6 and 7, in the main board 31 and the payout control board 371, the return signal is
The signals are input to the reset terminals of the CPU 56 and the payout control CPU 371 via the AND circuits 161 and 385.
Therefore, a system reset is applied to the CPU 56 and the payout control CPU 371. As a result, the CPU 56 and the payout control CPU 371 can exit the loop state.

FIG. 15B shows a counter 971.
In this case, the return signal is output immediately after the count-up of the main circuit 31. However, as shown in FIG.
The supply timing of the return signal to the PU 56 is later than the supply timing of the return signal to the payout control CPU 371. That is, similarly to the case where the reset signal is given at the start of the normal power supply, the reset release timing of the game control means is delayed with respect to the reset release timing of the payout control means. Therefore, even when the control operation is restored by the return signal, the game control means is activated with a delay with respect to the other electric component control means.

FIG. 16 and FIG. 17 are explanatory diagrams showing the assignment of output ports of the game control means in this embodiment. As shown in FIG. 16, the output port 0 is an output port for a strobe signal (INT signal) of a control command sent to each electric component control board. The 8-bit data of the payout control command sent to the payout control board 37 is output from the output port 1, and the 8-bit data of the display control command sent to the symbol control board 80 is output from the output port 2. The 8-bit data of the lamp control command sent to the lamp control board 35 is output from the output port 3. Then, as shown in FIG. 17, 8-bit data of the voice control command transmitted to the voice control board 70 is output from the output port 4.

The output port 5 is connected to the information output circuit 6
4, various information output signals reaching the information terminal board 34 and the like, that is, output data of information related to control are output.
Then, from the output port 6, a solenoid 16 for opening and closing the variable winning ball device 15, a solenoid 21 for opening and closing the opening and closing plate 2 of the special winning opening, and a solenoid 21A for switching a path in the special winning opening are driven. A signal is output.

FIG. 18 is an explanatory diagram showing bit assignment of an input port in this embodiment. As shown in FIG. 18, bits 0 to 7 of the input port 0 include a winning opening switch 24a, a winning opening switch 24b, a winning opening switch 19a, a winning opening switch 19b, a starting opening switch 17, a count switch 23, and a V switch, respectively. The detection signals of the winning switch (specific area switch) 22 and the gate switch 12 are input. Also, bits 0 to 3 of input port 1
, A detection signal of the prize ball count switch 301A, the full tank switch 48, the ball out switch 187, and a count switch short circuit signal are input.

Next, the operation of the gaming machine will be described. FIG.
9 is a flowchart showing a main process executed by the CPU 56 on the main board 31. When the power is turned on to the gaming machine and the CPU 56 is started, in the main processing, the CPU 56 first performs necessary initial settings.

In the initial setting process, the CPU 56 first sets interrupt prohibition (step S1). Next, the interrupt mode is set to the interrupt mode 2 (step S2), and a stack pointer designated address is set to the stack pointer (step S3). Then, the internal device registers are initialized (step S4). After initializing a built-in device (built-in peripheral circuit) CTC (counter / timer) and PIO (parallel input / output port) (step S5), the RAM is set to an accessible state (step S6).

The CPU 56 used in this embodiment
Incorporates an I / O port (PIO) and a timer / counter circuit (CTC). Also, CTC has two external clock / timer trigger inputs CLK / TRG2, 3
And two timer outputs ZC / TO0,1.

CPU 5 used in this embodiment
6 has the following three types of modes as maskable interrupt (INT) modes. When an interrupt that can be masked occurs, the CPU 56 automatically sets the interrupt disabled state and saves the contents of the program counter on the stack.

Interrupt mode 0: The built-in device that has issued the interrupt request receives an RST instruction (1 byte) or a CALL instruction (3 bytes).
Byte) on the internal data bus of the CPU. Therefore, the CPU 56 executes the instruction at the address corresponding to the RST instruction or the address specified by the CALL instruction. Upon reset, CPU 56 automatically switches to interrupt mode 0
become. Therefore, when it is desired to set the mode to the interrupt mode 1 or the interrupt mode 2, it is necessary to perform a process for setting the mode to the interrupt mode 1 or the interrupt mode 2 in the initial setting process.

Interrupt mode 1: When an interrupt is accepted,
In this mode, the camera always jumps to the address 0038 (h).

Interrupt mode 2: The address synthesized from the value (1 byte) of the specific register (I register) of the CPU 56 and the interrupt vector (1 byte: least significant bit 0) output from the built-in device is the interrupt address. Mode. That is, the interrupt address is an address indicated by 2 bytes in which the upper address is the value of the specific register and the lower address is the interrupt vector. Therefore, an interrupt process can be set at an arbitrary (albeit skipped) even address. Each built-in device has a function of sending an interrupt vector when making an interrupt request.

Therefore, when the interrupt mode 2 is set, it is possible to easily process an interrupt request from each built-in device, and it is possible to set an interrupt process at an arbitrary position in a program. Will be possible. Further, unlike the interrupt mode 1, it is easy to prepare an interrupt process for each interrupt occurrence factor. As described above, in this embodiment, the CPU 56 is set to the interrupt mode 2 in step S2 of the initial setting process.

Then, it is checked whether or not the data protection processing of the backup RAM area (for example, the power failure occurrence NMI processing such as the addition of parity data) has been performed when the power is turned off (step S7). In this embodiment, when an unexpected power failure occurs, a process for protecting data in the backup RAM area is performed. The case where such protection processing has been performed is regarded as backup. After confirming that there is no backup, the CPU 56 executes an initialization process.

In this embodiment, the backup RAM
Whether or not there is backup data in the area is confirmed by the state of the backup flag set in the backup RAM area when the power is turned off. In this example, as shown in FIG. 20, if "55H" is set in the backup flag area, it means that there is a backup (on state),
If a value other than “55H” is set, it means that there is no backup (off state).

After confirming that there is a backup, the CPU 5
Reference numeral 6 performs data check (parity check in this example) of the backup RAM area. If the power is restored after an unexpected power failure, the data in the backup RAM area should have been saved, and the check result becomes normal. If the check result is not normal, since the internal state cannot be returned to the state at the time of power-off, the initialization processing executed at the time of power-on without power recovery is executed.

If the check result is normal (step S
8) The CPU 56 performs a game state restoring process for returning the internal state of the game control means and the control state of the electric component control means such as the display control means to the state at the time of power-off (step S).
9). Then, the saved value of the PC (program counter) stored in the backup RAM area is set in the PC, and the program returns to that address.

In the initialization processing, the CPU 56 first sets R
An AM clear process is performed (step S11). In addition, a predetermined work area (for example, a normal symbol determination random number counter, a normal symbol determination buffer, a special symbol left middle right symbol buffer,
An initial value setting process for setting an initial value to a payout command storage pointer or the like is also performed. Further, a process for initializing the sub-boards (the lamp control board 35, the payout control board 37, the voice control board 70, and the symbol control board 80) is executed (step S13). The process of initializing the sub board is
For example, a process of transmitting an initialization command.

Then, the register of the CTC provided in the CPU 56 is set so that the timer is interrupted periodically every 2 ms (step S14). That is,
A value corresponding to 2 ms is set in a predetermined register (time constant register) as an initial value. Since the interrupt is prohibited in step S1 of the initial setting process, the interrupt is permitted before the initialization process is completed (step S1).
5).

In this embodiment, the built-in C
The TC is set to repeatedly generate a timer interrupt. In this embodiment, the repetition period is set to 2 ms. Then, when the timer interrupt occurs, as shown in FIG. 21, the CPU 56 sets, for example, a timer interrupt flag indicating that the timer interrupt has occurred (Step S).
12).

Execution of initialization processing (steps S11 to S1)
When 5) is completed, the process proceeds to a loop process in which the main process checks whether or not a timer interrupt has occurred (step S17). In the loop, a display random number update process (step S16) is also executed.

The CPU 56 determines in step S17 that
Upon recognizing that a timer interrupt has occurred, step S2
The game control processing of 1 to S31 is executed. In the game control process, the CPU 56 firstly receives, via the switch circuit 58, the gate sensor 12, the starting port sensor 17, the count sensor 23, and the winning port switches 19a, 19b, 24.
The states of the switches such as a and 24b are input and their states are determined (switch processing: step S21).

Next, various abnormality diagnosis processes are performed by the self-diagnosis function provided in the pachinko gaming machine 1, and an alarm is issued if necessary according to the result (error process: step S22).

Next, a process of updating each counter indicating a random number for determination such as a random number for big hit determination used in game control is performed (step S23). The CPU 56 further includes:
A process for updating a display random number such as a random number for determining the type of stop symbol is performed (step S24).

Further, the CPU 56 performs a special symbol process (step S25). In the special symbol process control, a corresponding process is selected and executed according to a special symbol process flag for controlling the pachinko gaming machine 1 in a predetermined order according to a gaming state. Then, the value of the special symbol process flag is updated during each processing according to the gaming state. Also, a normal symbol process is performed (step S26). In the normal symbol process process, a corresponding process is selected and executed according to a normal symbol process flag for controlling the variable display 10 using the 7-segment LED in a predetermined order. Then, the value of the normal symbol process flag is updated during each process according to the gaming state.

Next, the CPU 56 sets a display control command relating to the special symbol in a predetermined area of the RAM 55 and transmits the display control command (special symbol command control process: step S27). Further, a display control command relating to a normal symbol is set in a predetermined area of the RAM 55, and a process of transmitting the display control command is performed (ordinary symbol command control process: step S28).

Further, the CPU 56 performs an information output process for outputting data such as big hit information, start information, and probability fluctuation information supplied to the hall management computer (step S29).

When a predetermined condition is satisfied, the CPU 56 issues a drive command to the solenoid circuit 59 (step S30). The solenoid circuit 59 drives the solenoids 16 and 21 in response to the drive command, and brings the variable winning ball device 15 or the open / close plate 20 into an open state or a closed state.

The CPU 56 has switches 17, 23, 19a, and 19 for detecting winning in each winning opening.
A prize ball process for setting the number of prize balls based on the detection outputs of b, 24a and 24b is executed (step S31). Specifically, a payout control command is output to the payout control board 37 in response to the winning detection. The payout control CPU 371 mounted on the payout control board 37 drives the ball payout device 97 according to the payout control command.

According to the above control, in this embodiment, the game control process is started every 2 ms.
In this embodiment, for example, in the timer interrupt processing, only a flag indicating that an interrupt has occurred is set, and the game control processing is executed in the main processing.
The game control process may be executed by a timer interrupt process.

The main process includes a process for determining whether or not to shift to the game control process. The internal timer of the CPU 56 performs a timer interrupt process based on a timer interrupt that is periodically generated. Since a flag for determining whether or not to shift is set or the like, all of the game control processing is reliably executed. In other words, until all of the game control processes have been executed, it is not determined whether or not to shift to the next game control process, so it is guaranteed that all processes in the game control process will be completed. ing.

As described above, in this embodiment, the interrupt mode 2 is set in the CPU 56 having the built-in CTC and PIO in the initial setting process. Accordingly, a periodic timer interrupt process using the built-in CTC can be easily realized. Further, the timer interrupt processing can be set at an arbitrary position on the program. Further, switch detection processing using the built-in PIO can be easily realized by interruption processing. As a result, effects such as simplification of the program configuration and reduction in the number of program development steps can be obtained.

The output ports 0, 1, 2, 3, and 4 of the output ports 0 to 6 shown in FIGS.
Is accessed in a special symbol command control process (step S25), a normal symbol command control process (step S27), a prize ball process (step S31) and the like in the game control process. The output port 5 is accessed in information output processing (step S29), and the output port 6 is accessed in special symbol processing (step S25) and ordinary symbol processing (step S26).

Next, a specific example of the switch processing (step S21) in the main processing will be described. In this embodiment, when the on state of the detection signal continues for a predetermined time, it is determined that the switch has been turned on, and the processing corresponding to the switch on is started. A switch timer is used to measure a predetermined time. The switch timer is a 1-byte counter formed in the backup RAM area, and is incremented by 1 every 2 ms when the detection signal indicates the ON state. As shown in FIG. 22, the switch timers are provided by the number N of the detection signals. In this embodiment, N = 12. In the RAM, the address of each switch timer is in the order of the bit arrangement of the input port (FIG. 18).
From the top to the bottom shown in the figure).

FIG. 23 is a flowchart showing a processing example of the switch processing in step S21 in the game control processing. The switch process is first executed in the game control process as shown in FIG. In the switch processing, the CPU 56 first inputs data input to the input port 0 (step S71). Next, "8" is set as the number of processes (step S72), and the address of the switch timer for the winning opening switch 24a is set in the pointer (step S73). Then, a switch check processing subroutine is called (step S74).

FIG. 24 is a flowchart showing a switch check processing subroutine. In the switch check processing subroutine, the CPU 56 sets the port input data, in this case, the input data from the input port 0, as a “comparison value” (step S81). Also,
Set clear data (00) (step S8)
2). Then, the switch timer indicated by the pointer (the address of the switch timer is set) is loaded (step S83), and the comparison value is shifted to the right (from the upper bit to the lower bit) (step S8).
4). The data of the input port 0 is set as the comparison value. Then, in this case, the detection signal of the winning opening switch 24a is pushed out by the carry flag.

If the value of the carry flag is "1" (step S85), that is, if the detection signal of the winning opening switch 24a is on, the value of the switch timer is incremented by 1 (step S87). If the value after the addition is not 0, the added value is returned to the switch timer (steps S88 and S8).
9). When the value after the addition becomes 0, the added value is not returned to the switch timer. That is, if the value of the switch timer has already reached the maximum value (255), the value is not increased further.

If the value of the carry flag is "0", that is, if the detection signal of the winning opening switch 24a is in the OFF state, clear data is set in the switch timer (step S86). That is, if the switch is off, the value of the switch timer returns to zero.

Thereafter, the CPU 56 increments the pointer (address of the switch timer) by 1 (step S90) and decrements the number of processes by 1 (step S91). If the number of processes has not become zero, the process returns to step S82. Then, the processing of steps S82 to S92 is repeated.

The processes of steps S82 to S92 are repeated for the number of processes, that is, eight times. In the meantime, the detection signals of the switches input to the 8 bits of the input port 0 are sequentially turned on or off. A check process is performed, and if it is in the ON state, the value of the corresponding switch timer is incremented by one.

The CPU 56 executes the step S of the switch processing.
At 75, the data input to the input port 1 is input. Next, "4" is set as the number of processes (step S76), and the address of the switch timer for the winning ball count switch 301A is set in the pointer (step S77). Then, a switch check processing subroutine is called (step S78).

In the switch check processing subroutine,
Since the above-described processing is executed, steps S82 to S9 are performed.
2 is repeated for the number of processes, that is, four times. During that time, the detection signal of the switch input to the 4 bits of the input port 1 is sequentially checked to determine whether it is on or off. If it is in the ON state, the value of the corresponding switch timer is increased by one.

In this embodiment, since the game control process is started every 2 ms, the switch process is also executed once every 2 ms. Therefore, the switch timer is incremented by 1 every 2 ms.

FIGS. 25 to 27 are flowcharts showing an example of the prize ball processing in step S31 in the game control processing. In this embodiment, in the prize ball process, it is determined whether or not the winning opening switches 19a, 19b, 24a, 24b, the count switch 23, and the starting opening switch 17 have been reliably turned on. Is controlled to be sent to the payout control board 37,
In addition, the full tank switch 48 and the ball out switch 187
Is turned on without fail, and when turned on, processing such as control is performed so that a predetermined payout control command is sent to the payout control board 37.

In the prize ball processing, the CPU 56 sets “0” as an offset of the input determination value table (step S121), and sets “0” as an offset of the address of the switch timer (step S122). The offset “0” of the input judgment value table means that the first data of the input judgment value table is used. Also,
Since each switch timer is arranged in the same order as the bit order of the input port shown in FIG. 18, the offset "0" of the address of the switch timer means that the switch timer corresponding to the winning opening switch 24a is designated. I do. Also, “4” is set as the number of repetitions (step S
123). Then, the switch-on check routine is called (step S124).

The input determination value table is a table in which a determination value is set for each switch to determine how many consecutive ONs have been detected to determine that the switch has been turned ON.
This is the M area. FIG. 30 shows a configuration example of the input determination value table. As shown in FIG. 30, in the input determination value table, “2”, “50”, “250”, “30”,
Determination values of “250” and “1” are set. Also,
In the switch-on check routine, the judgment value set at the address determined by the start address of the input judgment value table and the offset value is compared with the value of the switch timer determined by the start address of the switch timer and the offset value. If so, for example, a switch-on flag is set.

One example of the switch-on check routine is shown in FIG. In the switch-on check routine, the CPU 56 sets the start address of the input determination value table (see FIG. 30) (step S101).
Then, an offset is added to the address (step S102), and a switch-on determination value is loaded from the address after the addition (step S103).

Next, the CPU 56 sets the start address of the switch timer (step S104), adds an offset to the address (step S105), and loads the value of the switch timer from the address after the addition (step S106). Since each switch timer is arranged in the same order as the bit order of the input port shown in FIG. 18, the value of the switch timer corresponding to the switch is loaded.

Then, the CPU 56 compares the value of the loaded switch timer with the switch-on judgment value (step S107). If they match, a switch-on flag is set (step 108).

In this case, in the switch-on check routine, if the value of the switch timer corresponding to the winning opening switch 24a matches the switch-on determination value "2", the switch-on flag is set (step S1).
25). When the switch-on flag is set, 10 counters are incremented by 1 (step S126). The switch check-on routine is executed for the initially set number of repetitions while the offset of the address of the switch timer is being updated (step S129) (steps S127 and S128).
For a, 19b, 24a, and 24b, the value of the corresponding switch timer is compared with the switch-on determination value “2”. The ten counter is a counter that indicates the number of ten game ball payouts as prizes.

Next, the CPU 56 sets “0” as an offset of the input judgment value table (step S13).
0), “4” is set as the offset of the address of the switch timer (step S131). The offset “0” of the input judgment value table means that the first data of the input judgment value table is used. Since the switch timers are arranged in the same order as the bit order of the input port shown in FIG. 18, the switch timer address offset “4” indicates that the switch timer corresponding to the starting port switch 17 is specified. Means Then, the switch-on check routine is called (step S1).
32).

In the switch-on check routine,
If the value of the switch timer corresponding to the starting port switch 17 matches the switch-on determination value "2", the switch-on flag is set (step S133), and the six counters are incremented by 1 (step S134). . In addition,
The six counter is a counter that indicates the number of payouts of six game balls as prizes.

Next, the CPU 56 sets “0” as an offset of the input judgment value table (step S13).
5), “5” is set as the offset of the address of the switch timer (step S136). The offset “0” of the input judgment value table means that the first data of the input judgment value table is used. Further, since the switch timers are arranged in the same order as the bit order of the input port shown in FIG. 18, the offset “5” of the address of the switch timer indicates that the switch timer corresponding to the count switch 23 is designated. means. Then, the switch-on check routine is called (step S).
137).

In the switch-on check routine,
If the value of the switch timer corresponding to the count switch 23 matches the switch-on determination value "2", the switch-on flag is set (step S138).
The five counters are incremented by 1 (step S134). The 15 counter is a counter indicating the number of payouts of 15 game balls as prizes.

Further, the CPU 56 sets "1" as an offset of the input judgment value table (step S15).
0), “9” is set as the offset of the address of the switch timer (step S151). The offset “1” in the input judgment value table is equal to 2 in the input judgment value table.
This means that the second data “50” is used. Also, since each switch timer is arranged in the same order as the bit order of the input port shown in FIG. 18, the switch timer address offset “9” indicates that the switch timer corresponding to the full switch 48 is designated. Means Then, the switch-on check routine is called (step S152).

In the switch-on check routine,
If the value of the switch timer corresponding to the full tank switch 48 matches the full tank switch-on determination value "50", the switch-on flag is set (step S15).
3) The full tank flag is set (step S15)
4). Although not explicitly shown in FIG. 26, when the value of the switch timer corresponding to the full tank switch 48 becomes 0, the full tank flag is reset.

The CPU 56 sets “2” as the offset of the input judgment value table (step S15).
6), “0A (H)” is set as the offset of the address of the switch timer (step S157). The offset “2” in the input determination value table means that the third data “250” in the input determination value table is used. Also, since each switch timer is arranged in the same order as the bit order of the input port shown in FIG. 18, the offset “0A (H)” of the address of the switch timer is designated by the switch timer corresponding to the ball out switch 187. Means to be done. Then, the switch-on check routine is called (step S158).

In the switch-on check routine,
If the value of the switch timer corresponding to the out-of-ball switch 187 matches the out-of-ball switch-on determination value "250", the switch-on flag is set (step S1).
59), a ball out flag is set (step S16)
0). Although not explicitly shown in FIG. 26, a switch-off timer corresponding to the out-of-ball switch 187 is prepared, and when its value reaches 50, the out-of-ball flag is reset.

[0186] Then, the CPU 56 checks whether or not the payout is stopped (step S201). The payout stop state is a state after a payout stop state designation command is sent to the payout control board 37. If it is not the payout stop state, it is checked whether the above-mentioned ball out-of-ball state flag or the full tank flag is turned on (step S202).

When either of them changes to the ON state,
A command transmission control process for payout stop state designation is performed (step S203). In the command transmission control process, after predetermined data is set in the command transmission table for the payout control command, a process of transmitting the payout control command is executed. In step S202, when one of the flags is already on, and the other flag is on, the command transmission control process (step S203) is not performed.

If the payout is stopped, it is checked whether both the out-of-ball state flag and the full state flag have been turned off (step S204). When both are turned off, a command transmission control process for payout stop release designation is performed (step S205).

Next, the CPU 56 sets a payout control command relating to the number of winning balls according to the winning in the command transmission table, and performs control to transmit the payout control command according to the set contents. First, the values of the 15 counters are checked (step S221). As described above, the fifteen counters are counted up when the game ball wins the big winning opening and the count switch 23 is turned on. If the value of the fifteen counters is not 0, a command transmission control process for the fifteen winning ball number instructions is performed (step S22).
2). In the command transmission control process, after predetermined data is set in the command transmission table for the payout control command, a process of transmitting the payout control command is executed. Also,
The value of the 15 counters is decremented by one (step S223).
Further, 15 is added to the value stored in the total prize ball storage buffer (step S224).

The total prize ball number storage buffer is a buffer for storing the cumulative value of the prize ball numbers instructed to the payout control means (however, it is subtracted when the payout is made).
It is formed in the backup RAM.

If the value of the 15 counter is 0, the value of the 10 counter is checked (step S225). As described above, the ten counters indicate that the gaming ball has won the winning opening and the winning opening switches 19a, 19b, 24a, 24b
Counts up when turns on. If the value of the ten counter is not 0, a command transmission control process for the ten winning ball number instructions is performed (step S226). Further, the value of the ten counters is decremented by one (step S22).
7). Further, 10 is added to the value stored in the total prize ball storage buffer (step S228).

If the value of the ten counter is 0, the value of the six counter is checked (step S231). As described above, the six counters are counted up when the game ball wins the starting winning port and the starting port switch 17 is turned on. If the value of the six counter is not 0, a command transmission control process relating to an instruction for the number of six winning balls is performed (step S232). Further, the value of the six counters is decremented by one (step S233). Further, 6 is added to the value stored in the total prize ball storage buffer (step S234).

As described above, when the payout control command for instructing the number of prize balls is to be output from the game control means to the payout control board 37, after the command transmission table is set, the command transmission table is displayed. The set payout control command is sent to the payout control board 37. Then, when the payout control command indicating the number of winning balls is transmitted, the awarding ball paying flag is turned on (step S235). When the award ball paying flag is on (step S236), the number of award balls actually paid out from the ball payout device 97 is monitored and the value stored in the total award ball number storage buffer is subtracted. A number subtraction process is performed (step S237). When the award ball payout flag changes from on to off, the lamp control board 35
A lamp control command instructing lighting of the prize ball lamp 51 is transmitted.

FIG. 29 is a flowchart showing an example of the prize ball number subtraction processing. In the prize ball number subtraction process, C
The PU 56 first loads the value stored in the total prize balls storage buffer (step S241). Then, it is determined whether or not the stored value is 0 (step S242). If it is 0, the process ends.

If it is not 0, the switch timer for the prize ball count switch is loaded (step S243), and the loaded value is compared with the ON determination value (in this case, "2") (step S244). If they match (step S24
5) Assuming that the prize ball count switch 301A has certainly turned on, that is, one game ball has surely
7 is subtracted from the value stored in the total prize ball storage buffer (step S246).

The value of the prize ball information counter is incremented by 1 (step S247). If the value of the prize ball information counter is 10 or more (step S248), the value of the prize ball information output counter is incremented by 1 (step S24).
9), the value of the prize ball information counter is reduced by -10 (step S)
250). The value of the prize ball information output counter is as shown in FIG.
In the information output process (step S29) in the main process shown in (1), if the value is 1 or more, one pulse is output as a prize ball signal (bit 7 of the output port 5: see FIG. 17). Therefore, in this embodiment, 10
Each time one gaming ball is paid out as a prize ball, one prize ball signal is output outside the gaming machine.

Then, when the stored value of the total prize ball storage buffer becomes 0 (step S251), the paying ball payout flag is cleared (step S252), and it is notified that there is no remaining prize ball. After setting command data indicating turning off of the prize ball lamp 51 in the command transmission table for the lamp control command (step S253), a lamp control command transmission process is executed (step S254).

Next, a method of transmitting a control command from the game control means to each electric component control means will be described. FIG. 31 is an explanatory diagram illustrating an example of a command form of a control command sent from the main board 31 to another electrical component control board. In this embodiment, the control command has a 2-byte configuration, the first byte represents MODE (classification of command), and the second byte represents EXT (type of command). The first bit (bit 7) of MODE data is always "1", and the first bit (bit 7) of EXT data
Is always set to “0”. The command form shown in FIG. 31 is an example, and another command form may be used.

FIG. 32 is a timing chart showing the relationship between an 8-bit control signal constituting a control command from the game control board to each of the other electric component control boards and an INT signal (strobe signal). As shown in FIG.
Or, after the EXT data is output to the output port,
When the predetermined period has elapsed, the CPU 56 turns on the INT signal, which is a signal indicating data output. When a predetermined period elapses therefrom, the INT signal is turned off.

FIG. 33 is an explanatory diagram showing an example of the content of the payout control command. In the example shown in FIG.
Command F of ODE = FF (H) and EXT = 00 (H)
F00 (H) is a payout control command for specifying a payable state. MODE = FF (H), EXT = 01
The command FF01 (H) of (H) is a payout control command for specifying a payout stop state. MODE = F0
The command F0XX (H) of (H) is a payout control command for specifying the number of winning balls. "XX" which is EXT indicates the number of payouts.

When the payout control means receives the payout control command of FF01 (H) from the game control means of the main board 31, the payout control means stops the prize ball payout and the ball lending.
When the payout control command of (H) is received, it becomes possible to pay out prize balls and lend a ball. Further, when a payout control command specifying the number of winning balls is received, prize ball payout control according to the number specified by the received command is performed.

The payout control command is sent only once so that the payout control means can recognize it. Recognizable means that the INT signal is in the ON state in this example, and is transmitted only once so that it can be recognized. In this example, the INT signal is sent to the first and second bytes of the payout control signal. Accordingly, the INT signal is turned on only once.

When a control command is to be output from the game control means to each electric component control board such as a payout control board, a command transmission table is set. FIG.
(A) is an explanatory view showing a configuration example of a command transmission table. One command transmission table is composed of three bytes, and INT data is set in the first byte. In the command data 1 of the second byte, MODE data of the first byte of the control command is set. And
The command data 2 in the third byte includes the control command 2
The EXT data of the byte is set.

Although the EXT data itself may be set in the command data 2 area, the command data 2
May be set to data for specifying an address of a table in which EXT data is stored. In this embodiment, bit 7 of command data 2
If (work area reference bit) is 0, it indicates that the EXT data itself is set in the command data 2. Such EXT data is data in which bit 7 is 0. If the work area reference bit is 1, the other 7
The bit indicates that it is an offset for specifying the address of the table in which the EXT data is stored.
In this embodiment, a command transmission table is prepared for each control command.

FIG. 34B is an explanatory diagram showing an example of the configuration of INT data. Bit 0 in the INT data indicates whether or not a payout control command should be sent to the payout control board 37. If bit 0 is "1", it indicates that a payout control command should be sent. Therefore, the CPU 56
For example, when sending out the payout control command in the prize ball processing, “01 (H)” is set in the INT data of the command transmission table for the payout control command.

Bits 1, 2, and 3 of the INT data are bits indicating whether a display control command, a lamp control command, and a voice control command are to be transmitted, respectively.
If the PU 56 is to send those commands,
INT is stored in the command transmission table indicated by the pointer.
Data, command data 1 and command data 2 are set. When sending those commands, INT
The corresponding bit of the data is set to “1”, and MODE data and E
XT data is set.

A control command to each electric component control board is
When outputting to a corresponding output port (output ports 1 to 4), any one of bits 0 to 3 of output port 0 is turned on for a predetermined period. This corresponds to the bit arrangement at port 0. Therefore, when transmitting a control command to each electric component control board, it is possible to easily output an INT signal based on the INT data set in the command transmission table.

FIGS. 35 to 37 are flowcharts showing an example of a non-maskable interrupt process (power supply stop process) executed in response to a power-off signal from the power supply board 910.

In the power supply stop processing, the CPU 56
Saves the AF register (accumulator and flag register) in a predetermined backup RAM area (step S451). Further, the interrupt flag is copied to the parity flag (step S452). The parity flag is formed in the backup RAM area. Further, the BC register, the DE register, the HL register, the IX register, and the stack pointer are saved in the backup RAM area (Steps S454 to S458). When the power is restored, the register contents are restored based on the saved contents, and an internal setting of an interrupt permission state / inhibition state is made according to the contents of the parity flag.

Next, in this embodiment, for a predetermined period,
The detection signal of the winning ball count switch 301A is checked. When the award ball count switch 301A is turned on, the content of the total award ball number buffer is reduced by one.

In this embodiment, a counter for measuring a predetermined period is used to measure a predetermined period.
The value of the counter for the predetermined period measurement is decremented from the initial value m by one every time a loop of the switch detection process described below (a loop starting from S461 and returning to S461) is executed once.
When the value becomes 0, it is assumed that the predetermined period has ended. In the detection processing loop, although there is an exception, almost constant processing is performed. Therefore, a time that is m times the time required for one round of the loop substantially corresponds to a predetermined period.

In order to measure a predetermined period, a built-in timer of CPU 56 may be used. That is, at the start of the switch detection process, a predetermined value (corresponding to a predetermined period) is set in the built-in timer. Then, the loop of the switch detection processing is 1
Each time it is executed, the count value of the built-in timer is checked. Then, when the count value becomes 0, it is assumed that the predetermined period has ended. Although an interrupt by the built-in timer can be used to detect that the value of the built-in timer has become 0, at this stage, the control is performed so as not to change the control contents (each value stored in the RAM). It is preferable to use a program configuration in which the count value of the built-in timer is read out and checked without using the program.

For a predetermined period, the game ball is dropped from the ball dispensing device 97 and the prize ball count switch 30 is set.
The time is set to be equal to or longer than the time required to reach 1A. Assuming that the distance from the ball dispensing device 97 to the prize ball count switch 301A is L, the falling time t during that time is t = √ (2L /
g) (g: gravitational acceleration), so the predetermined period is set longer.

At least during a predetermined period during which the switch detection process is executed, the prize ball count switch 301A must be in a state capable of detecting a game ball. Therefore, in this embodiment, as shown in FIG.
A capacitor 923 as an auxiliary driving power source having a relatively large capacity is connected to the input side of the converter IC 922 in FIG. Therefore, even when the power supply to the gaming machine is stopped, the +12 V power supply voltage is maintained within the range in which the switch can be driven for a certain period, and the prize ball count switch 301A
Becomes operable. The capacity of the capacitor is determined so that the period is equal to or longer than the predetermined period.

Note that the input port and the CPU 56 are also driven by the +5 V power supply created by the converter IC 922, so that they can operate for a relatively long time even when the power supply is stopped.

In step S461, an initial value n corresponding to a time of 2 ms is set in the 2 ms counter. Then, until the value of the 2 ms measurement counter becomes 0 (step S462), the value of the 2 ms measurement counter becomes −
1 (step S463).

When the value of the 2 ms measurement counter becomes 0,
The input check of the detection signal of the winning ball count switch 301A is performed. That is, processing similar to the switch processing and switch check processing shown in FIGS. 23 and 24 is performed. Specifically, the data input to the input port 1 is input (step S464). Next, clear data (00) is set (step S4).
65). Further, the port input data, in this case, the input data from the input port 1 is set as a “comparison value” (step S466). Further, the address of the switch timer for the award ball count switch 301A is set in the pointer (step S467).

Then, the switch timer pointed to by the pointer (the address of the switch timer is set) is loaded (step S468), and the comparison value is shifted to the right (from the upper bit to the lower bit) (step S469). ). The data of the input port 1 is set as the comparison value. Then, in this case, the detection signal of the winning ball count switch 301A is pushed out by the carry flag.

If the value of the carry flag is "1" (step S470), that is, the award ball count switch 30
If the 1A detection signal is on, the value of the switch timer is incremented by 1 (step S471). If the value of the carry flag is "0", that is, if the detection signal of the award ball count switch 301A is in an off state, clear data is set in the switch timer (step S472).
That is, if the switch is off, the value of the switch timer returns to zero.

When the value of the switch timer becomes 2 (step S473), the value stored in the total prize ball storage buffer is decremented by 1 (step S474), and the value of the prize ball information counter is incremented by 1 (step S474). Step S475).
If the value of the award ball information counter is 10 or more (step S476), the value of the award ball information output counter is incremented by 1 (step S477), and the value of the award ball information counter is decreased by 10 (step S478).

Next, the value of the counter for measuring a predetermined period is
1 (step S479), and if the value is not 0, the process returns to step S461.

With the above processing, when the winning ball count switch 301A is turned on within a predetermined period, the value of the total winning ball number storage buffer is decremented by one. Since the process for storing the contents of the backup RAM is performed after such a switch detection process, the total prize ball number storage buffer is always decremented by one for the prize balls that have been paid out. Therefore, it is possible to prevent inconsistency in the stored control state regarding the payout of the game balls. In the above switch detection processing, timer processing using a detection period counter is performed. That is, the prize ball count switch 30 is set every 2 ms.
The detection output of 1A is checked, and when the ON is detected twice consecutively, it is considered that the winning ball count switch 301A is surely turned ON. Therefore, erroneous switch-on detection is prevented. Also, in the switch detection processing, the calculation of the prize ball information output frequency counter for outputting the prize ball information to the outside of the gaming machine is also performed.
There is no discrepancy between the prize ball information output to the outside and the actual number of payout prize balls.

In this embodiment, the switch detection processing of only the prize ball count switch 301A is performed. However, the same applies to the switch of the starting winning opening and the V winning switch 22 and the count switch related to the large winning opening. Switch detection processing may be performed. The same switch detection processing may be performed for other winnings. When such an on-check is also performed, even if a power failure occurs immediately after a game ball has won a winning hole, the winning is reliably detected and reflected in the saved game state.

When a predetermined period has elapsed (step S48)
0), that is, when the value of the counter for measurement for a predetermined period becomes 0, the designated value with backup (“55” in this example)
H ”) is stored in the backup flag (step S).
481). The backup flag is formed in the backup RAM area. Next, parity data is created (steps S482 to S491). That is, first,
The clear data (00) is set in the checksum data area (step S482), and the checksum calculation start address is set in the pointer (step S483).
Also, the number of checksum calculations is set (step S
484).

Then, an exclusive OR of the contents of the checksum data area and the contents of the RAM area pointed to by the pointer is calculated (step S485). The calculation result is stored in the checksum data area (step S48).
6) Increase the value of the pointer by 1 (step S487),
The value of the number of checksum calculations is subtracted by 1 (step S4)
88). The processing of steps S485 to S488 is repeated until the value of the number of times of checksum calculation becomes 0 (step S489).

When the value of the number of checksum calculation times becomes 0, the CPU 56 inverts the value of each bit of the contents of the checksum data area (step S490). Then, the inverted data is stored in the checksum data area (step S491). This data is the parity data that is checked when the power is turned on. Then, R
An access prohibition value is set in the AM access register (step S492). Thereafter, the internal RAM 55 cannot be accessed.

In this embodiment, the RAM area in which data used in the game control process is stored is all backed up by a power supply. Therefore, a process of generating a checksum indicating whether or not the content is correctly stored, and an R for preventing the content from being rewritten.
The AM access prevention process corresponds to a process for saving a gaming state.

When the process of prohibiting access to the built-in RAM 55 is executed, the CPU 56 enters a standby state (loop state).
to go into. Therefore, nothing is done until the system is reset.

In this embodiment, the power supply stop processing is executed in response to the NMI.
It may be connected to the maskable terminal of the PU 56 to execute the power supply stop processing by the maskable interrupt processing. Alternatively, the power-off signal may be input to the input port, and the power supply stop processing may be executed according to the check result of the input port.

In this embodiment, the register saving processing is performed at the beginning of the processing started in response to the power-off signal. However, when the register is not used in the switch detection processing, the register detection processing is performed. After execution, that is, before register backup processing and checksum calculation processing, register storage processing can be performed. In that case, the register saving processing, the backup flag setting processing, and the checksum calculation processing can be regarded as the power supply stop processing. Furthermore, even when some registers are used in the switch detection processing, register saving processing can be performed on unused registers before setting the backup flag and calculating the checksum.

FIG. 38 is a timing chart showing an example of how the input processing of the detection signal from the payout detecting means is executed. In this embodiment, the power-off signal is transmitted to the main board 31.
Is input to the payout control board 37 and the CP of the main board 31
It is input to U56 and the NMI terminal of the payout control CPU 371. The CPU 56 of the main board 31 executes the above-described power supply stop processing by the non-maskable interrupt processing.

As shown in FIG. 38, when the prize ball payout is executed around the time when the power-off signal is turned on (in this example, changed from high level to low level), the input processing of the detection signal from the payout detection means is performed. The prize ball count switch 301A is turned on within a predetermined period to be executed. Therefore, the ball payout executed when the power-off signal is turned on can be reflected in the total winning ball count buffer when the power supply stop processing is executed.

When the voltage value of VSL further decreases to a predetermined value (+9 V in this example), reset IC constituting reset management circuit 940 as shown in FIG.
The output at 651 goes low, and the CPU 56 enters a system reset state. Note that the CPU 56 has completed the power supply stop processing before the system is reset.

If the voltage value of VSL further drops below the voltage at which Vcc (+5 V for driving various circuits) can be generated, each circuit cannot operate on each substrate. However, in the main board 31, the power supply stop processing is executed, and the CPU 56 is in a system reset state.

As described later, the payout control board 37
Similarly, the payout control CPU 371 enters the system reset state after performing the power supply stop processing.

The pachinko gaming machine 1 of the above embodiment is
The first-type pachinko gaming machine, in which a predetermined game value can be given to a player when a stop symbol of a special symbol variably displayed on the variable display portion 9 based on a start winning prize is a combination of a predetermined symbol, A third-type pachinko gaming machine in which a predetermined right is generated or continued when there is a prize in a predetermined electric accessory which is opened when a stop symbol of a symbol variably displayed based on a start winning prize is a predetermined combination of symbols. Even so, the present invention can be applied.

FIG. 39 is an explanatory view showing an example of the game area 7 of the third type pachinko gaming machine. In this example, when there is a winning in the starting winning port 30A, the variable display section 9 starts variable display of symbols. When the stop symbol of the symbol is a predetermined symbol combination, the right-generating electric accessory 30
B is opened for a predetermined period to be in a state where it is easy to win. In this state, when a right is generated by winning the right-generating electric accessory 30B, a game ball entering the rotor 30C driven by a motor or the like is guided to the starting port switch of the large winning port 30D,
When the start port switch is detected, the special winning port 30D is opened. Each switch is provided for detecting a game ball which has won the starting winning port 30A, the right-generating electric accessory 30B, the rotor 30C, and the special winning port 30D.

In such a type 3 pachinko gaming machine, even when the control state is stored in response to the occurrence of a power failure or the like, the processing is started, for example, in response to a power-off signal. Rotor 30C by port clear processing
Stop the motor and the like for driving the motor. And the rotor 30C
The game ball guided to the starting port switch (the switch for detecting the game ball entering the rotor 30C) is subjected to the switch detection process for a predetermined period even after the power-off is detected. Can be detected. Therefore, when the power is restored, it is guaranteed that the operating condition of the special winning opening 30D is satisfied. In this case, the predetermined period is a period of time equal to or longer than the time required for the game ball to move from the portion of the rotor 30C that holds the game ball to the starting port switch. Further, the switch provided on the right-generating electric accessory 30B is also subjected to the detection processing for a predetermined period even after the power-off is detected, thereby preventing the right from being unduly erased. .

When all the switches are detected in the switch detection process in the process started in response to the generation of the power-off signal, the switch process shown in FIG. 23 is called during a predetermined period. You may. Then, in the case of such a configuration, the processing when the switch timer value reaches the ON determination value is also performed. For example, when the switch timer value of the winning ball switch reaches the ON determination value, a process for setting the number of winning balls is performed (increment of 15 counters, etc.), or the switch timer value of the V winning switch 22 becomes the ON determination value. Upon reaching, a process such as setting a flag indicating that there is a V winning is performed.

Hereinafter, the game state restoring process will be described. FIG. 40 is a flowchart showing an example of the gaming state restoring process shown in step S9 of FIG. In this example, the CPU 56 restores the value stored in the backup RAM to each register (Step S91). Then, based on the data stored in the backup RAM, the game state at the time of the power failure is confirmed and restored. That is, based on the data stored in the backup RAM, the solenoid 16
And the solenoid 21 are driven, and the starting winning opening 14 and the opening and closing plate 2
0 is restored (steps S92 and S9).
3). In addition, according to the value of the special symbol process flag and the normal symbol process flag that have been saved even during the power-off, the control command corresponding to the progress status of the special symbol process process and the normal symbol process process at the time of power-off, The information is sent to the symbol control board 80, the lamp control board 35, and the voice control board 70 (step S94).

As described above, in the game state restoring process, the state of various electric components is restored according to the restored internal state, and the symbol control board 80, the lamp control board 35, and the voice control board 70 are restored. Then, a control command for returning the control state to the power-off state (a control command for generating the control state at the time of power-off) is transmitted.
Such a control command is generally one or more control commands that were last sent out before power down.

When the game state is returned to the state at the time of power-off, in this embodiment, the CPU 56 restores the interrupt permission / prohibition state at the time of the previous power-off to save the parity stored in the backup RAM. The value of the flag is confirmed (step S95). If the parity flag is off, interrupt permission setting is performed (step S96). However, if the parity flag is in the on state, the game state restoring process is terminated as it is (with the interrupt prohibition state set in step S1). The on state of the parity flag means that the interrupt was disabled at the time of the previous power-off, as shown in step S452 in FIG. Therefore, when the parity flag is in the ON state, the interruption is not permitted.

In this embodiment, the following state restoration can be performed by the above-described game state restoration processing.

The start winning opening 14 and the grand winning opening (opening and closing plate 2)
The state of 0) is restored. Display state of normal symbols controlled by display control means (display state of variable display 10)
Is restored except when it is changing when the power is turned off. The display state of the special symbol controlled by the display control means (the display state of the variable display unit 9) is restored except for the case where it is changing when the power is turned off. Further, the variable display unit 9
Are restored except during the special symbol change and during the big hit game.

When the power is turned off during the change of the special symbol, information on the change time (for example, 10 seconds) of the variable display pattern and the time already executed (for example, 4 seconds) are backed up. Then, at the time of restoration, the main board 31 outputs a display control command indicating a display pattern and a display control command indicating a stop symbol to the display control board 80, and stops the symbol after a lapse of the remaining time (6 seconds in the above example). Output a display control command to cause Therefore, when the special symbol is changing when the power is turned off, the display state of the special symbol is variably displayed for the remaining time (6 seconds in the above example) not displayed at the time of restoration. The display control command indicating the display pattern output to the display control board 80 at the time of restoration may be the same as the display control command indicating the display pattern output before the power is turned off. It is good also as a command for displaying an image like "in the middle." In this case, the display "recovering from power failure" is displayed for the remaining time (6 seconds in the above example). The same control as described above is performed for the display state of the ordinary symbol when the power is turned off during the change of the special symbol.

[0246] When the power is turned off during the big hit game, the remaining time of the round or the interval between the rounds is restored when the power is turned off during the change of the special symbol. , Display, sound, lamp,
While controlling the solenoid 21 and the like, the main board 31 outputs a display control command to the display control board 80 for designating a symbol at the time of confirmation (stop symbol) output before the power is turned off.
Thereby, the effect by the big hit symbol during the round or between the rounds becomes possible (for the model that performs the big hit with the big hit symbol), and the display control board 80 can also recognize the symbol displayed at the start of the change after the big hit end. .

Decorative lamp 2 controlled by lamp control means
5, start memory display 18, gate passage memory display 41,
The display states of the award ball lamp 51 and the ball out lamp 52 are restored. Game effect lamps / LEDs 28a, 28b, 2
The display state of 8c is restored except when the special symbol is being changed and the big hit is being played. However, if a big hit is being played when the power is turned off, the initial state of each control section can be restored. The control sections are, for example, a jackpot start notification state, a state before the opening of the special winning opening, a state during opening of the special winning opening, and a notification state of the big hit end. When the power is turned off during the change of the special symbol and the power is turned off, the game effect lamps / LEDs 28a, 28b, and 2 are provided for the remaining time, similarly to the display control of the variable display unit 9 and the variable display device 10 described above.
Although the display state of 8c may be controlled, it may be turned off or turned on or off in a pattern specific to turning off or restoring the power failure.

The sound generation state controlled by the voice control means is restored except during a special symbol change and a big hit game. However, if a big hit is being played when the power is turned off, the initial state of each control section can be restored.
When the power is turned off during the special symbol change and the power is restored, the sound generation state is controlled for the remaining time in the same manner as the display control of the variable display unit 9 and the variable display device 10 described above. Alternatively, a sound pattern specific to silence or power recovery from a power failure (for example, a voice saying “power recovery is in progress”) may be output.

In this embodiment, at the time of restoration from power-off, a control command for restoring a state is sent from the game control means of the main board 31 to the display control means, the lamp control means and the voice control means. However, when the display control means, the lamp control means, and the sound control means are backed up by a power source, the display control means, the lamp control means, and the sound control means independently control without using a control command from the main board 31. The state may be restored.

Also, as described later, the payout control board 37
The payout control means mounted on the power supply is backed up by a power supply, so that upon recovery from a power failure, the prize ball payout state and the ball lending control state are changed to the state at the time of the power failure (for a predetermined time from when the voltage drop is detected). To the state after elapse of). In this embodiment, since the firing control board is connected to the payout control means, the control state of the firing control board 91 is similarly restored.

In the above embodiment, the case has been described where the game control means performs the data saving processing and the recovery processing. However, the payout control means, the voice control means, the ramp control means, and the RAM in the display control means have been described.
May be backed up by a power source, and the payout control unit, the display control unit, the sound control unit, and the lamp control unit may also perform the above-described processing. However, the payout control means, the display control means, the sound control means, and the lamp control means do not need to perform the command transmission processing at the time of restoration.

Next, as an example of the case where the data saving processing and the restoring processing are performed in the electric component control means other than the game control means, the case where the payout control means performs the data saving and the recovery will be described.

As shown in FIG. 7, the payout control board 37
In, a power-off signal from the power supply board 910 is connected to the non-maskable interrupt terminal (XNMI terminal) of the payout control CPU 371 via the AND circuit 385. Therefore,
The payout control CPU 371 can confirm the occurrence of power interruption by the non-maskable interrupt processing.

CLK / TRG of payout control CPU 371
The INT signal from the main board 31 is connected to the two terminals. When a clock signal is input to the CLK / TRG2 terminal, the value of the timer counter register CLK / TRG2 incorporated in the payout control CPU 371 is counted down. When the register value becomes 0, an interrupt occurs. Therefore, the timer counter register CLK / TRG
If the initial value of 2 is set to "1", an interrupt will be generated in response to the input of the INT signal.

FIG. 41 is an explanatory diagram showing the assignment of output ports in this embodiment. As shown in FIG. 41, the output port C (address 00H) is
The output port of the drive signal output to 89. Also,
Output port D (address 01H) is 7 segment LE
This is an output port of a display control signal output to the error display LED 374 which is D. The output port E (address 02H) is an output port for outputting a drive signal output to the distribution solenoid 310 and an EXS signal and a PRDY signal to the card unit 50.

FIG. 42 is an explanatory diagram showing bit assignment of input ports in this embodiment. As shown in FIG. 42, the input port A (address 06H) is an input port for receiving an 8-bit payout control signal of the payout control command sent from the main board 31. Further, detection signals of the prize ball count switch 301A, the ball lending count switch 301B, and the motor position sensor are input to bits 0 to 2 of the input port B (address 07H), respectively. In bits 3 to 5, the BRDY signal, the BRQ signal, and the VL signal from the card unit 50 are input.

FIG. 43 is a flowchart showing the main processing executed by the payout control CPU 371. When the power is supplied to the gaming machine and the payout control CPU 371 is activated, the payout control CPU 371 is executed in the main processing.
First, perform necessary initial settings. That is, the payout control CPU 371 sets interrupt prohibition (step S7).
01). Next, the interrupt mode is set to the interrupt mode 2 (step S702), and a stack pointer designated address is set to the stack pointer (step S703). Also, the payout control CPU 371 initializes the built-in device register (step S704), and sets the CTC and P
After initializing the IO (step S705), RA
M is set to an accessible state (step S70)
6).

In this embodiment, one channel of the built-in CTC is used in the timer mode. Therefore,
In the internal device register setting process in step S704 and the process in step S705, a register setting for setting a channel to be used to the timer mode, a register setting for permitting interrupt generation, and a register for setting an interrupt vector The settings are made. Then, the interruption by the channel is used as a timer interruption. When it is desired to generate a timer interrupt every 2 ms, for example, a value corresponding to 2 ms is set in a predetermined register (time constant register) as an initial value.

The interrupt vector set for the channel set in the timer mode (channel 3 in this embodiment) corresponds to the start address of the timer interrupt processing. Specifically, the start address of the timer interrupt processing is specified by the value set in the I register and the interrupt vector. In the timer interrupt process, the timer interrupt flag is set, and when it is detected in the main process that the timer interrupt flag is set, the payout control process is executed. That is, in the timer interrupt process, a setting for executing the payout control process, which is an example of the electrical component control process, is performed.

Another one of the built-in CTCs (channel 2 in this embodiment) is used as a channel for generating an interrupt for receiving a payout control command from the game control means. Is used in the counter mode. Therefore, in the setting processing of the internal device register in step S704 and the processing in step S705, the register setting for setting the channel to be used to the counter mode, the register setting for permitting the interrupt generation, and the interrupt vector setting are performed. Is set.

The interrupt vector set for the channel (channel 2) set in the counter mode corresponds to the start address of the command reception interrupt process described later. Specifically, the start address of the command reception interrupt processing is specified by the value set in the I register and the interrupt vector.

In this embodiment, the payout control CPU 3
At 71, the interrupt mode 2 is set. Therefore, the built-in CT
An interrupt process based on the count-up of C can be used. Further, it is possible to set an interrupt processing start address according to the interrupt vector transmitted by the CTC.

The interrupt based on the count-up of channel 2 (CH2) of the CTC is an interrupt generated when the value of the timer counter register CLK / TRG2 becomes "0". Therefore, for example, in step S705, the timer counter register C as a specific register
The initial value “1” is set in LK / TRG2. Also, C
The interruption based on the count-up of the channel 3 (CH3) of the TC is based on the internal clock (system clock) of the CPU.
Is counted down and the register value becomes "0", and is used as a 2 ms timer interrupt described later. Specifically, the register value of CH3 is subtracted in 1/256 cycle of the system clock. Step S7
At 05, the register of CH3 contains 2 as an initial value.
A value corresponding to ms is set.

An interrupt based on the count-up of CH2 of the CTC has a higher priority than an interrupt based on the count-up of CH3. Therefore, when the count-up occurs at the same time, an interrupt based on the count-up of CH2,
That is, the interrupt that triggers the execution of the command reception interrupt process has priority.

The payout control CPU 371 checks whether backup data exists in the payout control backup RAM area (step S70).
7). That is, for example, similarly to the processing of the CPU 56 of the main board 31, it is determined whether or not backup data exists by determining whether or not a backup flag that is set when the power is turned off is in a set state. If the backup flag is set, it is determined that there is backup data.

After confirming that there is a backup, the payout control CPU 371 checks the data in the backup RAM area (parity check in this example). If the power is restored after an unexpected power failure, the backup R
Since the data in the AM area should have been saved, the check result becomes normal. If the check result is not normal, since the internal state cannot be returned to the state at the time of power-off, the initialization processing executed at the time of power-on without power recovery is executed.

If the check result is normal (step S
708), the payout control CPU 371 performs a payout state restoring process for returning the internal state to the state at the time of power-off (step S709). Then, the process returns to the address indicated by the PC (program counter) stored in the backup RAM area.

In the initialization processing, the payout control CPU 371
Performs RAM clear processing first (step S71).
1). A CTC provided in the payout control CPU 371 so that a timer interrupt is periodically performed every 2 ms.
Are set (step S712). That is, a value corresponding to 2 ms is set in a predetermined register (time constant register) as an initial value. Since the interrupt is prohibited in step S701 of the initial setting process, the interrupt is permitted before the initialization process is completed (step S713).

In this embodiment, the payout control CPU 3
The built-in CTC 71 is set to repeatedly generate a timer interrupt. In this embodiment, the repetition period is 2
ms. And when a timer interrupt occurs,
As shown in FIG. 44, the payout control CPU 371 sets, for example, a timer interrupt flag indicating that a timer interrupt has occurred (step S721). Note that FIG. 44 also clearly indicates that interruption is permitted (step S72).
0) In the 2 ms timer interrupt processing, the interrupt is first set to the permission state. That is, since the interrupt is permitted during the 2 ms timer interrupt process, the payout control command receiving process based on the input of the INT signal can be preferentially executed.

The payout control CPU 371 proceeds to step S7.
At 24, when it is detected that the timer interrupt flag has been set, the payout control process from step S751 is executed. According to the above control, in this embodiment, the payout control process is started every 2 ms. In this embodiment, only the flag is set in the timer interrupt processing, and the payout control processing is executed in the main processing. However, the payout control processing may be executed in the timer interrupt processing.

In the payout control process, the payout control CPU
371 is the input port 37 via the relay board 72 first.
It is determined whether or not the prize ball count switch 301A and ball lending count switch 301B input to 2b are turned on (switch processing: step S751).

Next, the payout control CPU 371 performs processing such as checking the state of signal input from a sensor (for example, a motor position sensor for detecting the number of revolutions of the payout motor 289) to determine the state of the sensor (for example). Input determination processing: Step S752). The payout control CPU 371 further analyzes the received payout control command and executes processing according to the analysis result (command analysis execution processing: step S75).
3).

Next, the payout control CPU 371 sets the payout stop state if the payout stop instruction command is received from the main board 31, and cancels the payout stop state if the payout start instruction command is received (step S754). ).
Further, a prepaid card unit control process is performed (step S755).

Next, the payout control CPU 371 performs control to pay out the lent ball in response to the ball lending request (step S756). At this time, the payout control CPU 371 sets the ball distribution member 311 to the ball lending side by the distribution solenoid 310.

Further, the payout control CPU 371 performs a prize ball control process of paying out the prize balls of the number stored in the total number storage (step S757). At this time, the payout control CPU 371 sets the ball distribution member 311 to the winning ball side by the distribution solenoid 310. And output port 3
A drive signal is output to the payout motor 289 in the payout mechanism of the ball payout device 97 via the relay board 72c and the relay board 72, and a payout motor control process for rotating the payout motor 289 by a predetermined number of revolutions is performed (step S758). .

In this embodiment, the delivery motor 2
A stepping motor is used as 89, and a 1-2 phase excitation method is used to control them. Therefore,
Specifically, in the payout motor control processing, eight types of excitation pattern data are repeatedly output to the payout motor 289. In this embodiment, each excitation pattern data is output for 4 ms.

Next, error detection processing is performed, and a predetermined display is performed on the error display LED 374 according to the result (error processing: step S759).

Note that the output port C is accessed in the payout motor control processing (step S758) in the payout control processing. The output port D is accessed in an error process (step S759) in the payout control process.
The output port E is accessed in the ball lending control process (step S756) and the prize ball control process (step S757) in the payout control process.

FIG. 45 is an explanatory diagram showing an example of use of the RAM incorporated in the payout control CPU 371. In this example,
In the backup RAM area, a total number storage (for example, 2 bytes) and a rental ball number storage are respectively formed.
The total number storage stores the total number of awarded ball payouts instructed from the main board 31 side. The rental ball number storage stores the number of unpaid ball rentals.

As described above, since the number of unpaid prize balls and the number of loaned balls are stored in the backup RAM area capable of holding the contents for a predetermined period, even if an unexpected power-off such as a power failure occurs, If the power is restored within a predetermined period, the prize ball processing and the ball lending processing stored in the backup RAM area can be continued. Therefore, the disadvantage given to the player can be reduced.

FIG. 46 is an explanatory diagram showing an example of the configuration of a receiving buffer for storing the payout control command received from the main board 31. In this example, a ring buffer type receiving buffer capable of storing six payout control commands having a 2-byte configuration is used. Therefore, the reception buffer is constituted by a 12-byte area of the fixed command buffers 1 to 12. Then, a command reception number counter indicating in which area the received command is stored is used. The command reception number counter takes a value from 0 to 11.

FIG. 47 is a flowchart showing a payout control command receiving process by the interrupt process. An INT signal for payout control from the main board 31 is supplied to a payout control CPU 371.
Are input to the CLK / TRG2 terminal. Therefore, when the INT signal from the main board 31 is turned on, the value of the timer counter register CLK / TRG2, which has been set to “1” as the initial value, becomes 0, and the payout control CPU 3
At 71, an interrupt occurs. Then, the receiving process of the payout control command shown in FIG. 47 is started. The start address of the payout control command receiving process is an address determined by the interrupt vector output from the built-in CTC and the value set in the I register. Also, the timer counter register CLK
When the value of / TRG2 becomes 0, that value is automatically returned to the initial value ("1" in this example).

In the process of receiving the payout control command, the payout control CPU 371 first saves each register in the stack (step S850). Note that when an interrupt occurs, the CPU 371 automatically sets the interrupt prohibition state. However, when a CPU that does not automatically enter the interrupt prohibition state is used, the interrupt prohibition is performed before the execution of the process of step S850. It is preferable to issue an instruction (DI instruction). Next, data is read from the input port 372a assigned to the input of the payout control command data (step S851). Then, it is confirmed whether or not this is the first byte of the payout control command having the 2-byte structure (step S).
852). Whether it is the first byte or not is confirmed by whether or not the first bit of the received command is “1”. The first bit should be “1” in the MODE byte (first byte) of the payout control command having a 2-byte configuration (see FIG. 31). Therefore, if the first bit is “1”, the payout control CPU 371 determines that the valid first byte has been received, and stores the received command in the confirmed command buffer indicated by the command reception number counter in the reception buffer area (step S85
3).

If it is not the first byte of the payout control command, it is confirmed whether or not the first byte has already been received (step S854). Whether or not the data has already been received is confirmed based on whether or not valid data is set in the reception buffer (fixed command buffer).

If the first byte has already been received,
It is checked whether the first bit of the received 1 byte is “0”. And if the first bit is “0”,
Assuming that the valid second byte has been received, the received command is stored in the fixed command buffer indicated by the command reception number counter +1 in the reception buffer area (step S855). The first bit must be “0” in the EXT byte (second byte) of the payout control command having a 2-byte configuration (see FIG. 31). If it is determined in step S854 that the first byte has already been received, the process ends if the first bit of the data received as the second byte is not “0”.

When the command data of the second byte is stored in step S855, 2 is added to the command reception number counter (step S856). Then, it is checked whether or not the command reception counter is 12 or more (step S857), and if it is 12, the command reception number counter is cleared (step S858). After that, the saved register is restored (step S859),
Interrupt permission is set (step S859).

[0287] During the command reception interruption process, the interruption is prohibited. As described above, the interrupt is permitted during the 2 ms timer interrupt process. Therefore, if a command reception interrupt occurs during the 2 ms timer interrupt, the command reception interrupt process is executed with priority. You. Further, even if a 2 ms timer interrupt occurs during the command reception interrupt process, the interrupt process is kept waiting. As described above, in this embodiment, the processing priority of the command reception processing from the main board 31 is high.

It is to be noted that the payout control command has a 2-byte structure, and the first byte (MODE) and the second byte (EX)
T) is configured to be immediately distinguishable on the receiving side.
In other words, the receiving side can immediately detect whether the data as MODE or the data as EXT has been received by the first bit. Therefore, as described above, it can be easily determined whether or not appropriate data has been received.

FIG. 48 is a flowchart showing an example of the command analysis execution processing in step S753. In the command analysis execution processing, the payout control CPU 371
It is checked whether there is a received command in the confirmed command buffer area (step S753a). If there is a received command, it is checked whether the received payout control command is a payout number instruction command (step S753).
b). If there are a plurality of received commands in the confirmed command buffer area, whether or not the received payout control command is the payout number instruction command is checked for the earliest received received command. Will be

If the received payout control command is a payout number instruction command, the number specified by the payout number instruction command is added to the total number storage (step S753).
c). That is, the payout control CPU 371 is connected to the main board 3
The number of prize balls included in the number-of-payouts instruction command sent from the first CPU 56 is stored in the backup RAM area (total number storage). It should be noted that the payout control CPU 371 performs a subtraction of the command reception number counter and a reception command shift process in the confirmed command buffer area, if necessary.

FIG. 49 is a flowchart showing an example of the payout stop state setting processing in step S754. In the payout stop state setting process, the payout control CPU 371
It is checked whether there is a received command in the confirmed command buffer area (step S754a). If there is a received command in the confirmed command buffer area, it is checked whether or not the received payout control command is a payout stop instruction command (step S754b). If the command is the payout stop instruction command, the payout control CPU 371 sets the payout stop state (step S754c).

If it is confirmed in step S754b that the received command is not a payout stop instruction command, it is checked whether the received payout control command is a payout start instruction command (step S754d). If the command is a payout start instruction command, the payout stop state is released (step S7).
54e).

FIG. 50 is a flowchart showing an example of the switch processing in step S751. In the switch processing, the payout control CPU 371 checks whether or not the award ball count switch 301A indicates the ON state (step S751a). If it indicates the ON state, the payout control CPU 371 increments the winning ball count switch ON counter by one (step S751b). The prize ball count switch on counter includes the prize ball count switch 30.
This is a counter for counting the number of times the 1A ON state is detected.

Then, the value of the award ball count switch on counter is checked, and if the value is 250 (step S751c), the award ball clogging flag is set (step S751d). That is, when the ON state of the prize ball count switch 301A continues for a long time, the prize ball clogging flag is set.

When the value of the prize ball count switch on counter has become 2 (step S751e), it is determined that the prize ball count switch 301A has been turned on without fail.
The award ball count switch on flag is set (step S751f).

If it is confirmed in step S751a that the prize ball count switch 301A is not on, the payout control CPU 371 resets the prize ball count switch on flag (step S751).
h), the award ball count switch on counter is cleared (step S751i). Then, it is determined whether or not the ball lending count switch 301B indicates the ON state (step S751j). If the ON state is indicated, the payout control CPU 371 increments the ball lending count switch ON counter by one (step S751k). The ball lending count switch on counter is a counter for counting the number of times that the ball lending count switch 301B has been turned on.

Then, the value of the ball lending count switch on counter is checked, and if the value is 250 (step S7511), a lending ball clogging flag is set (step S751m). That is, when the ball lending count switch 301B has been on for a long period of time, the lending ball clogging flag is set.

When the value of the ball lending count switch on counter has become 2 (step S751n),
It is determined that the ball lending count switch 301B has been turned on, and the ball lending count switch on flag is set (step S751o).

If it is determined in step S751j that the ball lending count switch 301B is not on, the payout control CPU 371 resets the ball lending count switch on flag (step S75).
1p) The ball lending count switch on counter is cleared (step S751q).

FIG. 51 is a flowchart showing an example of the ball lending control process in step S756. In this embodiment, the maximum value of the number of consecutive payouts is one unit of the lending ball (for example, 25), but the maximum value of the number of consecutive payouts may be another number.

In the ball lending control process, the payout control CP
U371 confirms whether or not the ball lending is suspended (step S501). If the ball lending is not stopped, the payout control CPU 371 checks whether or not the ball is being loaned (step S511). If the ball is being loaned, the payout control CPU 371 proceeds to the processing during the ball lending after step S518. Transition. Whether or not the ball is being paid out is determined based on the state of a ball lending process flag described later. If the rental ball is not being paid out, the payout control CPU 371 sends the card unit 5
It is checked whether a ball lending request has been made from 0 (step S512). If there is a request, the ball lending process flag is turned on (step S513), and 25 (the number of ball lending units: 100 yen here) is set in the lending ball number storage in the backup RAM area (step S514). Then, the payout control CPU 371 turns on the EXS signal (step S515), and drives the distribution solenoid 310 to set the ball distribution member 311 below the ball payout device 97 to the ball lending side (step S515). S516). The payout motor 289 is turned on (step S517).

The turning on of the payout motor 289 is performed by
Strictly speaking, the BRQ signal is turned off to indicate that the card unit 50 has recognized the reception. The ball lending processing flag is set in the backup RAM area.

In step S518, the payout control C
The PU 371 confirms whether or not it is during the rental ball passage waiting time (step S518). If it is not during the lending ball passage waiting time, a ball lending sensor (in this example, a payout motor position sensor) is checked (step S519), and a ball lending count switch check process described later is performed (step S520).

Next, the payout control CPU 371 checks whether or not the drive of the payout motor 289 should be terminated (whether one unit of the payout operation has been completed) (step S52).
1). Specifically, it is confirmed whether or not the rotation corresponding to the predetermined number of payouts has been completed. The rotation corresponding to the predetermined number of payouts is monitored by the output of the payout motor position sensor. When the rotation corresponding to the predetermined number of payouts is completed, the payout control CPU 371 stops driving the payout motor 289 (step S522), and sets a rental ball passage waiting time (step S523).

If it is determined in step S518 that the waiting time for passing a ball is being passed, the payout control CPU 371 performs a ball lending count switch check process to be described later (step S524), and determines whether the waiting time for passing a ball is expired. Confirmation is performed (step S525). The lending ball passing waiting time is the time from when the last payout ball is paid out by the payout motor 289 to when it passes through the ball lending count switch 301B.

When confirming the end of the waiting time for passing the rental ball,
Since all the lending balls have been paid out, the sorting solenoid 310 is turned off and the card unit 50
The EXS signal is turned off in order to indicate that the next ball lending request can be accepted (step S52).
6). The ball lending processing flag is turned off (step S527).

After the EXS signal indicating the acceptance of the ball lending request is turned off and the BRQ signal, which is the ball lending request signal, is turned on again within a predetermined period, the sorting solenoid 310,
Alternatively, the ball lending process may be continued without turning off the payout motor 289. That is, instead of performing the ball lending process for each predetermined unit (in this example, 100 yen unit), the ball lending process may be performed continuously.

[0308] The contents of the number of lent balls are stored by the backup power supply of the power supply board 910 for a predetermined period even if the power of the gaming machine is turned off. Therefore, when the power is restored during the predetermined period, the payout control CPU 371 can continue the ball lending process based on the contents of the lending ball number storage.

FIG. 52 shows steps S520 and S52.
9 is a flowchart showing a ball lending count switch check process executed in Step 4. The ball lending count switch check process is a process of monitoring the state of the ball lending count switch 301B and subtracting the lending ball number storage.

In the ball lending count switch check processing, the payout control CPU 371 first checks whether or not the ball lending count switch ON waiting flag is set (step S520a). If the ball lending count switch ON waiting flag is set, the system waits until the ball lending count switch ON flag is turned on (step S520b). The ball lending count switch-on flag is set in step S751o in the switch processing shown in FIG. If the timer T11 times out before the ball lending count switch on flag is turned on, the ball lending path error flag is set (steps S520f and S520g). When the ball lending count switch 301B is turned on, the timer T11 is stopped (step S520c), and the ball lending count switch O
The N wait flag is reset (step S520d).
The timer T11 is a ball rental count switch 301
This is a timer for confirming whether or not B is turned on within a predetermined period.

When the ball lending count switch 301B is turned on, a ball lending count switch OFF waiting flag indicating that the ball lending count switch 301B is in a state of waiting for being turned off is set in order to confirm that the ball lending count switch 301B is turned off. Step S520e).

Therefore, if the ball lending count switch OFF waiting flag is on (step S520h), the payout control CPU 371 waits until the ball lending count switch on flag is turned off (step S520k). When the ball lending count switch on flag is turned off, the ball lending count switch OFF waiting flag is reset (step S520l). Then, it is determined that one game ball has been paid out, and the number of rental balls stored is decremented by one (step S520m).

If it is confirmed in step S520h that the ball lending count switch OFF waiting flag is not on, the timer T11 is started (step S520i), and the ball lending count switch ON waiting flag is set (step S520j).

As described above, in this embodiment, every time it is confirmed that one game ball has been lent, the number of stored balls is decremented by one.

FIGS. 53 and 54 show steps S758.
It is a flowchart which shows an example of the award ball control processing. In this example, the maximum value of the number of continuous payouts is the same as one unit of the lending ball (for example, 25), but the maximum value of the number of continuous payouts may be another number.

In the prize ball control processing, the payout control CPU
The 371 checks whether or not the rental ball is being paid out (step S531). Whether or not the ball is being paid out is determined based on the state of the ball lending process flag. If the ball is not being paid out, it is confirmed whether or not the prize ball is being paid out (step S).
532) If the prize ball is being paid out, the processing shifts to the processing during the prize ball shown in FIG. Whether or not a prize ball is being paid out is determined by a state of a prize ball processing flag described later.

If neither a loaned ball is being paid out nor a prize ball is being paid out, the payout control CPU 371 checks whether there is a ball lending preparation request from the card unit 50 (step S).
533). Whether or not there is a ball lending preparation request is performed by confirming whether the BRDY signal input from the card unit 50 is on (requested) or off (no request).

If there is no ball lending preparation request from the card unit 50, the payout control CPU 371 checks whether or not the number of prize balls (the number of unpaid prize balls) stored in the total number memory is not zero (see FIG. 3). Step S534). If the number of award balls stored in the total number memory is not 0, the award ball control CP
U371 turns on the award ball processing flag (step S5).
35) It is checked whether or not the value of the total number storage is 25 or more (step S536). The award ball processing flag is set in the backup RAM area.

The number of award balls stored in the total number storage is 2
If it is 5 or more, the payout control CPU 371 sets the 25 payout operation to output a drive signal to the payout motor 289 so as to rotate the payout motor 289 until 25 game balls are paid out. (Step S53)
7). If the number of prize balls stored in the total number memory is not 25 or more, the payout control CPU 371 drives the payout motor 289 to rotate the payout motor 289 until all game balls stored in the total number memory are paid out. Is set to output the total number payout operation (step S53).
8). Next, the ball sorting member 31 below the ball dispensing device 97
1 is set to the winning ball side (step S539), and the payout motor 289 is turned on (step S540). And FIG.
The processing shifts to processing during payout of the winning ball in the winning ball control processing shown in FIG.

FIG. 54 is a flowchart showing an example of processing during a prize ball in the payout control processing by the payout control CPU 371. In the processing during the prize ball, the payout control C
The PU 371 confirms whether or not the award ball passing waiting time is in progress (step S541). If it is not during the waiting time for passing a prize ball, a sensor for a prize ball (a payout motor position sensor in this example) is checked (step S542), and a prize ball count switch check process described later is performed (step S543).

Then, the payout control CPU 371 determines whether the driving of the payout motor 289 should be terminated (25 or 25).
It is determined whether or not a predetermined number of payout operations is completed (step S544). Specifically, it is confirmed whether or not the rotation corresponding to the predetermined number of payouts has been completed. The rotation corresponding to the predetermined number of payouts is monitored by the output of the payout motor position sensor. When the rotation corresponding to the predetermined number of payouts is completed, the payout control CPU 371
The driving of the payout motor 289 is stopped (step S54).
5), a prize ball passing waiting time is set (step S54).
6). The prize ball passing waiting time is a time from when the last payout ball is paid out by the payout motor 289 to when it passes through the prize ball count switch 301A.

If it is determined in step S541 that the award ball passage wait time is in progress, the payout control CPU 371 performs an award ball count switch check process described later (step S541).
547) It is checked whether or not the waiting time for award ball passage has ended (step S548). When the prize ball passage waiting time ends, all the prize balls set in step S537 or step S538 have been paid out. Therefore, the payout control CPU 371 turns off the award ball processing flag (step S549). If the last payout ball has not passed through the prize ball count switch 301A before the prize ball passage waiting time elapses, it is determined that a prize ball path error has occurred.

Note that, in this embodiment, step S5
According to the judgment of 31, the ball lending is given priority over the prize ball processing, but the prize ball processing may be given priority over the ball lending.

FIG. 55 shows steps S543 and S54.
7 is a flowchart showing a prize ball count switch check process executed in Step 7. The prize ball count switch check process is a process of monitoring the state of the prize ball count switch 301A and subtracting the total number storage.

In the prize ball count switch check processing, the payout control CPU 371 first checks whether or not a prize ball count switch ON waiting flag is set (step S543a). Prize ball count switch ON
If the wait flag has been set, it waits until the award ball count switch on flag is turned on (step S5).
43b). The prize ball count switch on flag is
Step S75 in the switch processing shown in FIG.
It is set at 1f. If the timer T12 times out before the winning ball count switch on flag is turned on, the winning ball path error flag is set (step S54).
3f, S543g). When the winning ball count switch 301A is turned on, the timer T12 is stopped (step S54).
3c), the award ball count switch ON waiting flag is reset (step S543d). The timer T12 is a timer for confirming whether or not the award ball count switch 301A is turned on within a predetermined period.

When the prize ball count switch 301A is turned on, a prize ball count switch OFF wait flag indicating that the prize ball count switch 301A is in a state of waiting for being turned off is set in order to confirm that the prize ball count switch 301A is turned off ( Step S543e).

Therefore, if the award ball count switch OFF waiting flag is on (step S543h), the payout control CPU 371 waits for the award ball count switch on flag to turn off (step S543k). When the winning ball count switch on flag is turned off, the waiting flag for turning off the winning ball count switch is reset (step S543l). Then, the total number storage is decremented by one (step S543m).

If it is determined in step S543h that the award ball count switch OFF waiting flag is not on, the timer T12 is started (step S543h).
543i), an award ball count switch ON waiting flag is set (step S543j).

The contents of the total number storage and the number of lent balls storage are each stored for a predetermined period by the backup power supply of the power supply board 910 even when the power of the gaming machine is turned off. Therefore, when the power is restored during the predetermined period, the payout control CP
U371 can continue the payout process based on the contents of the total number storage and the rental ball number storage.

The payout control CPU 371 manages the number of prize balls instructed from the main board 31 as the total number in the prize ball number storage, but for each prize ball number (for example, 15, 10 or 6).
). For example, a number counter corresponding to each prize ball number is provided, and when a payout number designation command is received, the number counter corresponding to the number designated by the command is incremented by one. When the prize ball payout corresponding to the number counter is performed, the number counter is decremented by one (in this case, the subtraction processing is performed in the payout control processing).
Also in this case, each number counter is formed in the backup RAM area. Therefore, even if the power of the gaming machine is turned off, if the power is restored during the predetermined period, the payout control CPU 371
Can continue the award ball payout process based on the content of each number counter.

FIGS. 56 to 58 are flow charts showing an example of the non-maskable interrupt processing executed in response to the power-off signal from the power supply board 910. In this example, the NMI
The power supply stop processing is executed according to the power supply stop signal. However, the power supply stop signal may be connected to the maskable terminal of the payout control CPU 371 and the power supply stop processing may be executed by the maskable interrupt processing. Alternatively, the power-off signal may be input to the input port, and the power supply stop processing may be executed according to the check result of the input port.

In the non-maskable interrupt processing, the payout control CPU 371 stores the AF register in the predetermined backup R
Save to the AM area (step S801). Further, the interrupt flag is copied to the parity flag (step S80).
2). The parity flag is formed in the backup RAM area. Also, BC register, DE register, HL
The registers, the IX register, and the stack pointer are saved in the backup RAM area (Steps S804 to S804)
08). When the power is restored, the register contents are restored based on the saved contents, and an internal setting of an interrupt permission state / inhibition state is made according to the contents of the parity flag.

Next, the drive signal output to the payout motor 289 is turned off (step S761). Accordingly, the driving of the ball payout device 97 stops. Thereafter, in this embodiment, a prize ball count switch 301A (corresponding to a prize game medium detecting means) as a payout detecting means for a predetermined period.
And the detection signal of the ball lending count switch 301B (corresponding to a lending game medium detecting means) is checked. And
When the prize ball count switch 301A is turned on, the content of the total number storage is reduced by one. In addition, ball rental count switch 3
When 01B is turned on, the content of the stored number of lent balls is reduced by one.

In this embodiment, a counter for measuring a predetermined period is used to measure a predetermined period.
The value of the counter for the predetermined period measurement is decremented from the initial value m by one every time a switch detection processing loop (a loop starting from S763 and returning to S763) is executed once.
When the value becomes 0, it is assumed that the predetermined period has ended. In the detection processing loop, although there is an exception, almost constant processing is performed. Therefore, a time that is m times the time required for one round of the loop substantially corresponds to a predetermined period.

In order to measure the predetermined period, the payout control C
A built-in timer of the PU 371 may be used. That is, at the start of the switch detection process, a predetermined value (corresponding to a predetermined period) is set in the built-in timer. Then, every time the loop of the switch detection process is executed once, the count value of the built-in timer is checked. Then, when the count value becomes 0, it is assumed that the predetermined period has ended. Although an interrupt by the built-in timer can be used to detect that the value of the built-in timer has become 0, at this stage, the control is performed so as not to change the control contents (each value stored in the RAM). It is preferable to use a program configuration in which the count value of the built-in timer is read out and checked without using the program. The predetermined period is set to be equal to or longer than the time from when the game ball drops from the ball payout device 97 to when it reaches the prize ball count switch 301A or the ball lending count switch 301B.

At least during a predetermined period during which the switch detection processing is executed, the prize ball count switch 301A and the ball lending count switch 301B must be in a state capable of detecting game balls. Therefore, in this embodiment, as shown in FIG. 13, a capacitor 923 as a relatively large-capacity auxiliary driving power supply is connected to the input side of the converter IC 922 in the power supply board 910. Therefore, even when the power supply to the gaming machine is stopped, the +12 V power supply voltage is maintained within the range in which the switches can be driven for a certain period of time, and the prize ball count switch 301A and the ball lending count switch 301B become operable. The capacity of the capacitor is determined so that the period is equal to or longer than the predetermined period.

The input port and payout control CPU
The 371 is also driven by the + 5V power supply created by the converter IC 922, so that it can operate for a relatively long time even when the power supply is stopped.

Further, in this embodiment, the distribution solenoid 310 is used to switch between the prize ball path and the lending ball path. Therefore, the capacitor 9 shown in FIG.
The capacity of 23 is such that the distribution solenoid 310 can be driven at least during the above-mentioned predetermined period.
The capacitor 923 is connected in parallel with the power line of VSL. However, since the game control means turns off the drive signal of another solenoid (for opening and closing a special winning opening) in response to the power-off signal, After the power-off signal is generated, the capacitor 923 is connected to the distribution solenoid 31 among the solenoids.
It is sufficient that only 0 can be driven.

Although the capacitor 923 used in this embodiment is one example of an auxiliary drive power supply, another capacitor may be used as the auxiliary drive power supply. At least during the above-mentioned predetermined period, the prize ball count switch 30
An auxiliary driving power supply of another mode can be used as long as it can drive the payout control means such as the 1A, the ball lending count switch 301B, the distribution solenoid 310, and the payout control CPU 371.

In the input processing (switch detection processing) of the detection signal from the payout detecting means, the payout control CPU 371 is used.
First, a value m corresponding to a predetermined period is set in a counter for measuring a predetermined period (step S762). Then, the payout control CPU 371 decrements the value of the counter for measurement for a predetermined period by one (step S763), and checks the value of the counter for measurement for a predetermined period (step S764). If the value is 0, the switch detection process ends, and the process shifts to a power supply stop process which is a process for saving the control state.

If the value of the counter for the predetermined period has not become 0, it is checked whether or not the award ball count switch is on (step S765). If it is ON, the value of the detection period counter is reduced by 1 (step S76).
6) It is checked whether the value of the detection period counter has become 0 (step S767). If it is 0, the detection signal of the prize ball count switch 301A is confirmed via the input port (step S768). Decrease the stored value by 1 (step S76)
9).

If it is confirmed in step S765 that the award ball count switch is not on, the detection signal of the award ball count switch 301A is confirmed via the input port (step S770). The count switch ON flag is set (step S771), and an initial value n is set in the detection period counter (step S772).

With the above processing, when the winning ball count switch 301A is turned on within a predetermined period, the value of the total number storage is decremented by one. Since the process for storing the contents of the backup RAM is performed after such a switch detection process, the total number storage is always decremented by one for the prize balls for which the payout has been completed. Therefore, it is possible to prevent inconsistency in the stored control state regarding the payout of the game balls. In the above switch detection processing, timer processing using a detection period counter is performed. That is,
Once the ON of the prize ball count switch 301A is detected, and after the elapse of a predetermined time (n times the processing time in the loop from S763 to S767 and returning to S763), the ON is not detected unless it is detected. Therefore, erroneous switch-on detection is prevented.

In the normal switch process (step S751 in FIG. 41), a timer process for preventing erroneous detection is performed. Therefore, such a normal switch process may be called. Although the timer process using the detection period counter is performed here, the timer in the switch detection process using the CPU built-in timer may be used similarly to the case where the CPU built-in timer may be used for measurement of a predetermined period. The processing may be realized.

If the award ball count switch is not being turned on and the on-state of the award ball count switch 301A cannot be detected, switch detection processing is performed on the ball lending count switch 301B. That is, the payout control C
The PU 371 checks whether or not the ball lending count switch is on (step S775). If it is on,
After reducing the value of the detection period counter by 1 (step S7)
76) It is checked whether the value of the detection period counter has become 0 (step S777). If it is 0, the detection signal of the ball lending count switch 301B is confirmed via the input port (step S778). If it indicates the ON state, it is determined that the ball lending count switch 301B is turned on without fail, and the lending ball is determined. The value of the number storage is reduced by 1 (step S779).

If it is confirmed in step S775 that the ball lending count switch is not on, the detection signal of the ball lending count switch 301B is confirmed via the input port (step S780). The count switch ON flag is set (step S781), and the initial value n is set in the detection period counter.
Is set (step S782).

With the above processing, if the ball lending count switch 301B is turned on within a predetermined period, the value of the lending ball number storage value is decremented by one. Since the process for storing the contents of the backup RAM is performed after such a switch detection process, the loaned ball number storage is always decremented by one for the loaned ball that has been paid out. Therefore, it is possible to prevent inconsistency in the stored control state regarding the payout of the game balls. In the above switch detection processing, timer processing using a detection period counter is performed. That is, unless the ball lending count switch 301B is kept on for a predetermined period of time or longer, it is not regarded as switch-on. Therefore, erroneous switch-on detection is prevented.

When the predetermined period has elapsed (step S76)
4), the payout control CPU 371 stores the designated value with backup ("55H" in this example) in the backup flag (step S809). The backup flag is formed in the backup RAM area. Then
Parity data is created by performing processing similar to that of the CPU 56 of the main board 31 and stored in the backup RAM area (steps S810 to S819). Then, an access prohibition value is set in the RAM access register (step S820). Thereafter, the internal RAM cannot be accessed.

In this embodiment, the RAM area in which data used in the payout control processing is stored is all backed up by a power supply. Therefore, a process of generating a checksum indicating whether or not the content is correctly stored, and an R for preventing the content from being rewritten.
The AM access prevention process corresponds to a process for saving the payout control state.

As described above, in this embodiment, when the power-off signal is output in response to the occurrence of a power failure or the like, first, the driving of the ball dispensing device 97 is stopped, and then the ballast dispensing means is turned off for a predetermined period. Input processing of the detection signal is performed, and then processing for saving the payout control state is performed. Therefore,
The game balls that were in the process of being paid out when the power failure occurred are also reflected in the contents stored in the backup RAM.

That is, in this embodiment, when the control state is stored in the backup storage means when the power supply to the gaming machine is stopped, it is possible to prevent inconsistency in the control.

Upon completion of the RAM access prevention processing, the payout control CPU 371 enters a standby state (loop state). Therefore, nothing is done until the system is reset.

As described above, in each of the above-described embodiments, when the power-off signal is output in response to the occurrence of a power failure or the like, first, the driving of the payout device is stopped, and then the payout detecting means is stopped for a predetermined period. Is executed, and thereafter, processing for saving the payout control state including the total number of unpaid prize balls and loaned balls is performed. Therefore, the game balls that were being paid out when the power failure occurred are also reflected in the contents stored in the backup RAM. Therefore, when the control state is stored in the backup storage unit when the power supply to the gaming machine is stopped, it is possible to prevent inconsistency or the like from occurring between the stored control state and the actual control state. it can.

As described above, when a power-off signal is generated due to an instantaneous power-off or the like, the power supply voltage is restored to a normal value and the gaming machine returns to a controllable state. When such a situation occurs, a return signal is supplied from the power supply board 910 to the payout board 37. When the return signal is input, the payout control CPU 371 is reset. Accordingly, the payout control CPU 371 can start executing the main process shown in FIG. At this time, since the gaming state is stored when the power-off signal is output, the payout state restoring process is executed in the process of step S709, and the payout control returns to the state at the time of the power-off signal generation. The payout control is continued from.

In this embodiment, the total number of unpaid prize balls and loaned balls is stored, but when another storage method is used such as storing the number of payouts (for example, 25 per payout ball). Even in this case, if the processing for inputting the detection signal from the payout detection means is executed for a predetermined period in response to the power-off signal, inconsistency occurs in the control state stored. Is prevented.

[0356] Here, the prize ball count switch 3
Timer (detection period counter) when detection signal of 01A or ball lending count switch 301B indicates ON state
If the detection signal indicates the ON state even when the timer expires, it is determined that the switch has been reliably turned on.
The configuration may be such that the detection signal is determined each time the ms timer (2 ms measurement counter) times out.

In this embodiment, the register saving processing is performed at the beginning of the processing started in response to the power-off signal. However, when the register is not used in the switch detection processing, the switch detection processing is performed. After execution, that is, before register backup processing and checksum calculation processing, register storage processing can be performed. In this case, the register saving processing, the backup flag setting processing, and the checksum calculation processing can be regarded as the power supply stop processing. Furthermore, even when some registers are used in the switch detection processing, register saving processing can be performed on unused registers before setting the backup flag and calculating the checksum.

In the above-described embodiment, the operation of the ball dispensing apparatus is stopped at the start of the interrupt processing by the interrupt generated in response to the power-off signal (in the above example, the non-maskable interrupt processing), During the period, input processing of the detection signal from the payout detection means was performed. However, when the power supply to the gaming machine is stopped, a first signal indicating that fact may be generated first, and a further signal may be generated when the voltage further decreases. Then, in response to the first signal, the operation of the ball dispensing device is stopped, a process of inputting a detection signal from the payout detecting means is performed, and a process for storing the control state in the backup RAM is performed in response to the second signal. May go.

In the above embodiment, the return signal from the power supply board 910 is input to the reset terminal of the CPU 56 on the main board 31, but may be input to the input port of the I / O port unit 57. FIG. 59 is a block diagram showing such an embodiment.

FIG. 60 is a flow chart showing a part of the non-maskable interrupt processing (processing at the time of stopping power supply) of the game control means in such a case. The flowchart shown in FIG. 60 is executed following the processing of steps S451 to S491 shown in FIGS. That is, in this embodiment, in a standby state of waiting for a system reset after setting the access prohibition value in the RAM access register (step S492), detection of the return signal being turned on via the input port is executed (step S5).
00). When the return signal is turned on, the process jumps to step S1 of the main process shown in FIG. When the execution of the main processing is started, the game state is stored when the power-off signal is output, and therefore, the step S9 is executed.
The game state restoring processing is executed in the processing described above, and the game control returns to the state at the time of the occurrence of the power-off signal, and the game control is continued from that state.

The return signal is input, for example, to bit 4 of input port 1 (see FIG. 18). Further, in this embodiment, the process jumps to step S1 immediately after the ON of the return signal is detected. However, in order to remove noise or the like, the process jumps to step S1 when a plurality of consecutive ONs are detected. If ON is detected again after a predetermined period has elapsed after the detection, the process may jump to step S1.

Further, in the non-maskable interrupt processing of the payout control means, a return signal input to the input port may be detected.

In each of the above embodiments, the return signal is generated by the power supply board 910, but may be generated by the electrical component control board that requires the return signal. FIG. 61 is a block diagram illustrating a configuration example of the power supply board 910A when the return signal is generated in the electric component control board. FIG.
The power supply board 910A shown in FIG. 1 does not output a return signal, unlike the power supply board 910 shown in FIG.

The reset management circuit 940A may have a configuration in which the return signal generation portion is removed from the circuit configuration shown in FIG. 14, but may be configured as shown in FIG. 62, for example. In the configuration shown in FIG. 62, the reset management circuit 940
In A, reset circuits 65, 65B, and 65C each having a reset IC that introduces VSL and changes the output from a low level to a high level when the voltage value of the VSL rises above a predetermined value are provided. . The output of the reset circuit 65 is supplied as a reset signal to the main board 31 via the reset signal circuit 950 and the buffer circuit 965. Each reset IC changes its output from a high level to a low level when the voltage of VSL falls below a predetermined value.

The output of the reset circuit 65B is supplied as a reset signal to the payout control board 37 via the reset signal circuit 950B and the buffer circuit 961.
The configuration of the reset signal circuits 950 and 950B is the same as the configuration of the reset signal circuit 950 shown in FIG. The output of the reset circuit 65C is supplied as a reset signal to the symbol control board 80, the lamp control board 35, and the audio control board 70 via the buffer circuits 962, 963, and 964.

The predetermined value for each reset IC in the reset circuits 65, 65B, 65C to change the output level is different. Specifically, the predetermined value in the reset IC of the reset circuit 65 is the other reset I
It is larger than a predetermined value in C. Also, the reset circuit 6
The predetermined values in the reset ICs of 5B and 65C are equal or the predetermined value in the reset IC of the reset circuit 65B is larger.

Therefore, when the power is turned on and VSL rises, the output of the reset circuit 65 goes to the high level at the latest. That is, the CPU 56 of the main board 31 rises latest. Further, when VSL decreases when the power is turned off, the output of the reset circuit 65 becomes the low level first. That is, the CPU of the main board 31 is reset at the earliest.

The reset management circuit 940A can be configured as shown in FIG. In the configuration shown in FIG.
When the power is turned on and VSL rises, the main board 3
The reset signal for 1 becomes high level on the condition that the AND circuit 951 sets the reset signal for another substrate to high level. Therefore, the CPU 56 of the main board 31 rises later than the CPUs of the other boards. Therefore, in the case of such a configuration, the predetermined value of each reset IC in the reset circuits 65, 65B and 65C does not need to be set to a value that is so strictly different from the configuration shown in FIG. Good.

FIG. 64 is a flow chart showing an example of the non-maskable interrupt processing (power supply stop processing) of the game control means when no return signal is generated on the power supply board 910A. The flowchart shown in FIG.
It is executed following the processing of steps S451 to S491 shown in FIG. That is, in this embodiment, R
In a standby state waiting for a system reset after setting the access prohibition value in the AM access register (step S492), first, an initial value M of the counter is set (step S111). Then, while decrementing the value of the counter by 1 (step S112), it is confirmed whether or not the value of the counter has become 0 (step S113).

When the value of the counter becomes 0, the process jumps to step S1 of the main processing shown in FIG. When the execution of the main process is started, the game state is stored when the power-off signal is output, so that the game state restoration process is executed in the process of step S9, and the game control is performed when the power-off signal is generated. And the game control is continued from that state.

The time from when the counter is set to the initial value M to when it counts up (becomes 0) is [the time required for the processing in steps S112 and S113] × M. It is set to count a time longer than the time from when the disconnection signal is generated until the CPU 56 operating on the Vcc power supply becomes inoperable. Therefore, generally, the CPU 56 does not operate before the counter counts up and jumps to step S1. That is, there is no jump to step S1.

However, when an instantaneous interruption of the power supply or the like occurs, the power supply is restored after the power supply voltage level decreases for a short period of time. Also in this case, when the voltage level of VSL becomes equal to or lower than the power-off signal output level, the power-off signal becomes low level, and the power supply stop processing is started. Then, the CPU 56 enters a loop state after the power supply stop processing ends. If no control is performed, the loop process cannot be exited. In this case, the counter counts up and the process can return to the main process.

That is, the counter in this embodiment corresponds to a software timer for performing a timer process executed in a standby state in a process corresponding to a power-off signal. Then, when the counter counts up, that is, when the elapse of the predetermined period is measured by the timer processing, the CPU 56 as the return means performs control to return from the standby state to the game control state.

Even in such a configuration, when the power supply voltage is restored to the normal value despite the occurrence of the power supply cutoff signal due to the instantaneous power cutoff or the like, the CPU 56 shown in FIG. The execution of the main processing can be resumed. At this time, since the game state is stored when the power-off signal is output, the game state restoration processing is executed in the processing of step S9, and the game control returns to the state at the time of the power-off signal generation, The game control is continued from.

[0375] Such control can be executed by the payout control means. FIG. 65 is a flowchart illustrating an example of the non-maskable interrupt process (process at the time of power supply stop) of the payout control unit when the return signal is not generated in the power supply board 910A. The flowchart shown in FIG.
Steps S801 to S819 shown in FIGS. 56 to 58
It is executed following the processing of. That is, in this embodiment, in a standby state of waiting for a system reset after setting an access prohibition value in the RAM access register (step S820), first, an initial value M of the counter is set (step S851). Then, the value of the counter is set to 1
While subtracting (step S852), it is checked whether the value of the counter has become 0 (step S853).

When the value of the counter becomes 0, the flow jumps to step S701 of the main processing shown in FIG. When the execution of the main processing is started, the control state is saved when the power-off signal is output, so that the payout state recovery processing is executed in the processing of step S709,
The control returns to the state at the time of occurrence of the power-off signal, and the payout control is continued from that state.

The count-up value (M set in S111 in FIG. 64) handled by the CPU 56 of the main board 31 is preferably a value larger than the count-up value handled by the payout control CPU 371. If the count-up value handled by the CPU 56 is a larger value,
The payout control means is restarted before the game control means. Therefore, the payout control means does not start up first and does not miss the payout control command from the game control means.

As described above, when a return signal is not generated in the power supply board 910A, it is possible to return from the standby state to the control state by performing timer processing by software, but the timer processing may be executed by hardware. Good.

FIG. 66 is a block diagram showing an example of a configuration in which timer processing is performed by hardware when a return signal is not generated in power supply board 910A.
In this example, a counter (watchdog timer circuit) 16 functioning as a watchdog timer is provided on the main board 31.
2 are provided. The watchdog timer circuit 162
When the output pulses of the oscillation circuit 164 are counted and counted up, one high-level pulse is generated as the Q output. The pulse signal is logically inverted by the inverting circuit 163 and input to the AND circuit 161 as a return signal. A
The ND circuit 161 calculates the logical product of the reset signal and the return signal and supplies the logical product to the reset terminal of the CPU 56. Note that C
A system clock or a divided clock thereof may be set to be output from the PU 56, and the clock may be used as an input clock signal of the watchdog timer circuit 162.

The count-up value is set to a time equal to or longer than the time when the voltage value of VSL decreases to the voltage capable of generating Vcc after the power-off signal goes low. Since the watchdog timer circuit 162 operates using Vcc as a power supply, the count-up value is set to a value equal to or longer than the value corresponding to the operable period of the watchdog timer circuit 162. Therefore, when the power supply to the gaming machine is stopped, generally, the watchdog timer circuit 162 and other circuit components do not operate before the watchdog timer circuit 162 counts up and the return signal is output.

When the CPU 56 is performing game control, a clear pulse is periodically given to the watchdog timer circuit 162. The output cycle of the clear pulse is shorter than the time until the watchdog timer circuit 162 counts up. Therefore, no pulse appears on the Q output of the watchdog timer circuit 162 when the CPU 56 performs the normal game control.

FIG. 67 shows the structure of the watchdog timer circuit 16.
It is a flow chart which shows a part of main processing of game control means when 2 is provided. The processing illustrated in FIG. 67 is executed following the processing in steps S1 to S15 illustrated in FIG. In this case, a watchdog timer clearing process (step S32) is executed in a loop of the game control process (steps S16 to S32). Therefore, the watchdog timer clear processing is executed every 2 ms.

In the watchdog timer clearing process (step S32), a process of outputting one pulse to an output port reaching the clear terminal of the watchdog timer circuit 162 is performed. Therefore, during execution of the game control process, a clear pulse is periodically given to the watchdog timer circuit 162, so that the watchdog timer circuit 162 does not count up.

When the supply voltage to the gaming machine decreases and a power-off signal is output, a non-maskable interrupt process as shown in FIGS. 35 to 37 is started. During this process, no clear pulse is output to the watchdog timer circuit 162. Therefore, when the power supply voltage is restored and the watchdog timer circuit 162 operates until counting up, a return signal is output.

FIG. 68 is a timing chart showing the output timing of the return signal when the above-mentioned software timer processing or the watchdog timer circuit 162 generates the return signal. FIG. 68A illustrates an example in which power supply to the gaming machine is stopped. The software timer processing is started after the power supply stop processing ends and the processing enters a standby state. Also, in the non-maskable interrupt processing, a clear pulse is not output to the watchdog timer circuit 162,
Is started from the start of the power supply stop processing. In any case, since the time-up value (count-up value) is set so as not to time-up until the power supply voltage becomes lower than the voltage value capable of generating Vcc, no return signal is generated.

When an instantaneous interruption of the power supply or the like occurs, as shown in FIG. 68B, the power supply is restored after the voltage level of VSL is reduced for a short period. Also in this case, when the voltage level of VSL becomes equal to or lower than the power-off signal output level, the power-off signal becomes low level, and the power supply stop processing is started. And CP
U56 enters a loop state after the end of the power supply stop processing.
If no control is performed, the loop processing cannot be exited. In this case, the watchdog timer circuit 16 counts up and generates a return signal.

As shown in FIG. 66, on the main board 31, the return signal is sent to the CPU via the AND circuit 161.
It is input to 56 reset terminals. Therefore, the CPU 56
Requires a system reset. As a result, the CPU 56
Can get out of the standby state.

FIG. 69 is a block diagram showing an example of a configuration in which timer processing is performed by hardware in the dispensing control board 37 when a return signal is not generated in the power supply board 910A. In this example, the payout control board 3
7, a counter (watchdog timer circuit) 386 that functions as a watchdog timer is provided. The watchdog timer circuit 386 counts output pulses of the oscillation circuit 388, and when counting up, generates one high-level pulse as a Q output. The pulse signal is logically inverted by the inverting circuit 387 and input to the AND circuit 385 as a return signal. AND circuit 385
The logical product of the reset signal and the return signal is calculated and supplied to the reset terminal of the CPU 56.

The count-up value is set to be equal to or longer than the time during which the voltage value of VSL decreases to the voltage at which Vcc can be generated after the power-off signal goes low. Since the watchdog timer circuit 386 operates using Vcc as a power supply, the count-up value is set to a value equal to or longer than the value corresponding to the operable period of the watchdog timer circuit 386. Therefore, generally, before the watchdog timer circuit 386 counts up and the return signal is output, the watchdog timer circuit 386 and other circuit components do not operate. Note that when the payout control CPU 371 is performing payout control, a clear pulse is periodically provided to the watchdog timer circuit 386. The output cycle of the clear pulse is shorter than the time until the watchdog timer circuit 386 counts up. Therefore, the payout control CP
When U 371 is performing normal game control, no pulse appears on the Q output of watchdog timer circuit 3876.

FIG. 70 shows a watchdog timer circuit 38.
6 is a flowchart showing a part of a main process of a payout control unit when the number 6 is provided. The processing illustrated in FIG. 70 is executed subsequent to the processing in steps S701 to S713 illustrated in FIG. In this case, the watchdog timer clearing process (step S760) is executed in the loop of the payout control process (steps S724 to S760). Therefore, the watchdog timer clear processing is performed by 2
Executed every ms.

In the watchdog timer clearing process (step S760), a process of outputting one pulse to an output port reaching the clear terminal of the watchdog timer circuit 386 is performed. Therefore, during the execution of the payout control process, a clear pulse is periodically given to the watchdog timer circuit 386, so that the watchdog timer circuit 386 does not count up.

When the supply voltage to the gaming machine is reduced and a power-off signal is output, a non-maskable interrupt process as shown in FIGS. 56 to 58 is started. During this process, no clear pulse is output to the watchdog timer circuit 386. Therefore, in the case where the power supply voltage is restored and the watchdog timer circuit 386 operates until counting up, a return signal is output.

As shown in FIG. 69, the payout control board 3
At 7, the return signal is output via the AND circuit 385,
It is input to the reset terminal of the payout control CPU 371.
Therefore, a system reset is applied to the payout control CPU 371. As a result, the payout control CPU 371 can escape from the standby state.

As described above, in the main board 31 and the payout control board 37, the watchdog timer circuits 162, 3
In the case where 86 is provided, the return signal can be generated by hardware. In addition, not only when the power supply voltage drops, but also for some reason, the CPU 5
6 or when the control of the payout control CPU 371 enters an infinite loop, it is possible to get out of the loop state.

The count-up value of the watchdog timer circuit 162 of the main board 31 is preferably larger than the count-up value of the watchdog timer circuit 386 of the payout control board 37. When the count-up value of the watchdog timer circuit 162 is larger, the return signal is supplied to the payout control unit before the game control unit. Therefore, the payout control means does not start up first and does not miss the payout control command from the game control means.

For example, a watchdog timer circuit 162 may be provided only on the main board 31 to supply a return signal from the watchdog timer circuit 162 to the CPU 56 and to the payout control board 37. With such a configuration, the overall circuit configuration scale can be reduced. In such a configuration, it is preferable to provide a delay circuit between the watchdog timer circuit 162 and the reset terminal of the CPU 56 so that the payout control means starts up first.

Further, the watchdog timer circuit 16
The return signal according to 2,386 may be input to an input port instead of being connected to the reset terminal of the CPU. In this case, the input port is monitored in the standby state in the power supply stop process, and when it is detected that the return signal is turned on, the process jumps to the beginning of the main process. Furthermore, watchdog timer circuits 162, 386
May be input to the CTC terminal of the CPU. In that case, the CTC interrupt is set in advance in response to the input of the return signal. In the standby state, interrupt permission is set. Then, when a CTC interrupt occurs, the process jumps to the beginning of the main process.

In each of the above embodiments, the power supply stop processing is executed in the payout control board 37 in accordance with the NMI.
And the power supply stop processing may be executed by the maskable interrupt processing. Alternatively, the power-off signal may be input to the input port, and the power supply stop processing may be executed according to the check result of the input port.

As described above, in each of the above embodiments,
When the game control means and the payout control means having the memory holding means (for example, a backup RAM) perform the power supply stop processing in response to the power-off signal and are in a standby state of waiting for a system reset, return in response to power recovery. When the signal is output, the game control means and the payout control means resume the operation from the beginning of the program. Alternatively, when a timeout occurs in the timer processing by software, the game control means and the payout control means resume the operation from the beginning of the program. At that time, the control state saved in the power supply stop time process is restored, so that the game is continued as if nothing had happened to the player.

[0400] Further, the starting order control means provided on the power supply board includes all the electric components including the electric component control means having no memory holding means and the electric component control means having the memory holding means. Since the activation sequence is controlled by controlling the supply sequence of the reset signal for the control unit, the activation sequence control of all the electric component control units can be realized with a simple configuration. In each of the above embodiments, the electric component control means having no memory holding means are the display control means, the lamp control means and the voice control means, and the electric component control means having the memory holding means. The game control means and the payout control means.

Further, since the activation order control means activates the game control means last, there is no inconvenience that each electric component control means misses a control command from the game control means.

In each of the above embodiments, the case where the game control means and the payout control means perform the switch detection processing in response to the power-off signal has been exemplified. However, the display control means, the sound control means, and the lamp control means are described. Also, when the control state saving process is performed, in response to the power-off signal, stop driving the predetermined electrical component, after confirming the detection signal of the switch means related to the electrical component for a predetermined period, The control state saving process may be configured to be performed.

As described in each of the above embodiments, the contents of the number of lent balls are stored by the backup power supply of the power supply board 910 for a predetermined period even if the power of the gaming machine is turned off. When the power is restored, the payout control CPU 371 can continue the ball lending process based on the contents of the lending ball number storage. When such processing is performed, various signals (BRDY signal, BRQ signal, EXS signal, and PRDY signal) exchanged between the card unit 50 and the payout control board 37 via the input port 372b and the output port 372e. ) Will be described.

[0404] Fig. 71 shows an example of the state of each signal when a payout process for paying out the number of loaned balls to be paid out is executed based on the contents of the number of loaned balls when power supply is restored. It is a timing diagram shown. FIG. 71 also shows an example of the state of each signal until the supply of power is stopped.

As shown in FIG. 71, when the power of the pachinko gaming machine 1 is turned on, the payout control C
Since the PU 371 outputs the PRDY signal to the card unit 50, the PRDY signal is turned on. Next, when the card is accepted in the card unit 50, the ball lending switch is operated, and the ball lending switch signal is input,
Since the microcomputer for controlling the card unit outputs the BRDY signal to the payout control board 37, the BRDY signal is turned on. When a predetermined delay time has elapsed from this point, the microcomputer for controlling the card unit outputs a BRQ signal to the payout control board 37, so that the BRQ signal is turned on.

[0406] Then, the payout control C of the payout control board 37 is used.
When the PU 371 raises the EXS signal to the card unit 50 and detects the fall of the BRQ signal from the card unit 50, it drives the payout motor 289 and pays out a predetermined number of loaned balls to the player. When the payout is completed, the payout control CPU 371 sets the card unit 5
The EXS signal for 0 falls. However, if the power is cut off before the payout is completed, the gaming machine waits for the start of power supply in a state in which the contents of the number of lent balls are stored by the backup power supply of the power supply board 910 for a predetermined period.

When the supply of power is started in a state in which the contents of the number of stored lent balls are stored, the payout control CPU 371 outputs a PRDY signal to the card unit 50.
The RDY signal turns on. And the payout control CPU 3
The EXS 71 is a state in which the BRDY signal and the BRQ signal are not received,
Set up a signal and pay out the unpaid number of loaned balls. At this time, the card unit 50 temporarily enters an error state. When the payout process of the unpaid rental ball is being executed, each signal is activated or deactivated as described above.

[0408] In each of the above embodiments, the power supply monitoring circuit is provided on the power supply board 910. However, the power supply monitoring circuit may be provided on the electric component control boards such as the main board 31 and the payout control board 37. Good. When the electric component control board on which the power supply circuit is mounted is configured, the power supply monitoring circuit is not mounted on the power supply board.

The pachinko gaming machine 1 of each of the above embodiments
Is a first-type pachinko gaming machine in which a predetermined game value can be given to a player when a stop symbol of a special symbol variably displayed on the variable display portion 9 based on a winning start is a combination of a predetermined symbol. However, if there is a prize in a predetermined area of the electric accessory that is opened based on a winning start, a second-type pachinko gaming machine in which a predetermined gaming value can be given to a player, or a variable display based on a starting prize The present invention is applied to a third-type pachinko gaming machine in which a predetermined right is generated or continued when there is a prize for a predetermined electric accessory which is opened when a symbol to be stopped becomes a predetermined combination of symbols. it can.

[0410] Furthermore, the present invention is not limited to the pachinko game machine in which the game medium is a game ball, and the present invention can be applied to a slot machine or the like when an electric component for paying out the game medium is provided.

[0411]

As described above, according to the present invention, the game machine is provided with variable data which can specify the number of unpaid unpaid games which have not been paid out of the number of paid out game media based on the lending request. The payout control means is capable of restarting the payout control of the game medium based on the data which can specify the unpaid number held by the storage content holding means when the power supply is restarted. When the monitoring unit detects that the state of the predetermined power supply has reached a predetermined state, a standby state is set after performing a power supply stop process related to saving the control state. Also, a return signal for returning from the standby state can be output to the payout control means when the power supply is not stopped after a predetermined period has elapsed after the power supply monitoring means has detected that the predetermined state has been reached. And a return signal output means. Therefore, even when the power supply is cut off, the number of unpaid rental game media can be backed up, and the appropriate control state can be saved. In addition, it is possible to return the electric component control means to the control execution state by the return signal, and as a result, even if an instantaneous interruption of the power supply which recovers in a very short time does not hinder the control. The effect can be obtained.

[0412] A game medium detecting means for detecting a game medium is provided, and the payout control means, when the power supply monitoring means detects that the state of the power supply has become a predetermined state, is determined. If the processing of inputting the detection signal from the detecting means is performed for a predetermined period, and the power supply stop processing related to the storage of the control state including the data that can specify the unpaid number is performed, the game medium to be detected is Can be detected, and the appropriate control state regarding the number of game media can be backed up and stored.

[0413] When the payout control means detects that the state of the power supply has reached a predetermined state by the power supply monitoring means, the payout control means stops driving the payout means, and thereafter the detection from the game medium detecting means. If it is assumed that the signal input process is to be executed, in a state where no new game medium is paid out by the rental game medium payout mechanism,
Since the game media can be detected, a more appropriate control state regarding the number of game media can be backed up and stored.

After the power supply monitoring means detects that the state of the power supply has reached a predetermined state, the payout control means and the game In the case where an auxiliary drive power supply unit capable of supplying power capable of driving the medium detection unit is provided, input processing of a detection signal from the game medium detection unit can be reliably completed. The detection process can be performed.

[0415] The payout control means can control the payout of the game medium according to the progress of the game.
If it is assumed that data that can specify the number of unpaid games that have not been paid out of the number of game media paid out according to the progress of the game include data that can be specified, only the number of unpaid game media paid out in response to a lending request In addition, the number of unpaid game media to be paid out in accordance with the progress of the game can be appropriately backed up and stored.

If the prize game medium detecting means and the lending game medium detecting means are separately provided as the game medium detecting means, the game medium to be paid out in response to the lending request is detected, and the game medium is detected in accordance with the progress of the game. It is possible to separately detect the game media to be paid out.

When the return signal is configured to be input to the reset signal input section of the electrical component control means, the configuration for returning the electrical component control means to the control execution state can be simplified. it can.

[0418] In the case where a plurality of electric component control means are provided and the return signal output means includes a start order control means for controlling a start order by making the output order of the return signal to each electric component control means different. Can easily realize the order of activation of the respective electric component control means.

[0419] The electric component control means includes game control means for controlling the progress of the game, and other electric component control means for controlling the electric components in response to a control signal from the game control means. If the game control means is to be started last, the electric component control means that receives the control signal from the game control means starts up at the time of startup, so the control signal from the game control means is There is no such thing as missing.

If the payout control means executes processing for prohibiting access to the variable data storage means in the processing at the time of power supply suspension, abnormalities that may occur as the power supply voltage decreases. It is possible to reliably prevent the destruction of the contents of the area (for example, RAM) in which the backup storage is stored due to the operation, and to surely protect the data stored in the RAM which is restored when the power is turned on thereafter. .

In the case where a power supply board for generating a voltage used in each electric component control board is provided separately from the electric component control board on which the electric component control means is mounted, and the return signal output means is mounted on the power supply board, The return signal output control can be collectively performed by the power supply board.

[Brief description of the drawings]

FIG. 1 is a front view of a pachinko gaming machine viewed from the front.

FIG. 2 is an explanatory view showing each substrate provided on the back surface of the pachinko gaming machine.

FIG. 3 is a rear view of the mechanical panel of the pachinko gaming machine as viewed from the rear.

FIG. 4 is a front view showing a configuration around an intermediate base unit installed on a mechanism plate.

FIG. 5 is an exploded perspective view showing a ball payout device.

FIG. 6 is a block diagram showing a circuit configuration of a game control board (main board).

FIG. 7 is a block diagram showing components related to a prize ball, such as components of a payout control board and a ball payout device.

FIG. 8 is a block diagram illustrating a circuit configuration example of a symbol control board.

FIG. 9 is a block diagram illustrating a circuit configuration example of a lamp control board.

FIG. 10 is a block diagram illustrating a circuit configuration example of an audio control board.

FIG. 11 is a block diagram illustrating a circuit configuration example of a launch control board.

FIG. 12 is a block diagram showing a DC voltage and the like supplied to each substrate from a power supply substrate.

FIG. 13 is a block diagram illustrating a configuration example of a power supply board.

FIG. 14 is a block diagram illustrating a configuration example of a reset management circuit.

FIG. 15 is a timing chart for explaining the operation of a counter which is an example of the timer means.

FIG. 16 is an explanatory diagram showing an example of bit assignment of an output port.

FIG. 17 is an explanatory diagram showing an example of bit assignment of an output port.

FIG. 18 is an explanatory diagram showing an example of bit assignment of an input port.

FIG. 19 is a flowchart illustrating a main process executed by a CPU on a main board.

FIG. 20 is an explanatory diagram showing an example of a relationship between a backup flag and whether or not to execute a game state restoration process.

FIG. 21 is a flowchart showing a 2 ms timer interrupt process.

FIG. 22 is an explanatory diagram showing an example of forming a switch timer in a RAM.

FIG. 23 is a flowchart illustrating an example of a switch process.

FIG. 24 is a flowchart illustrating an example of a switch check process.

FIG. 25 is a flowchart illustrating an example of a prize ball process.

FIG. 26 is a flowchart illustrating an example of a prize ball process.

FIG. 27 is a flowchart illustrating an example of a prize ball process.

FIG. 28 is a flowchart showing a switch-on check process.

FIG. 29 is a flowchart illustrating an example of a winning ball number subtraction process.

FIG. 30 is an explanatory diagram showing a configuration example of an input determination value table.

FIG. 31 is an explanatory diagram illustrating an example of a command form of a control command.

FIG. 32 is a timing chart showing a relationship between an 8-bit control signal and an INT signal which constitute a control command.

FIG. 33 is an explanatory diagram showing an example of the content of a payout control command.

FIG. 34 is an explanatory diagram showing a configuration example of a command transmission table.

FIG. 35 is a flowchart showing a non-maskable interrupt process in the game control means.

FIG. 36 is a flowchart showing a non-maskable interrupt process in the game control means.

FIG. 37 is a flowchart showing a non-maskable interrupt process in the game control means.

FIG. 38 is a timing chart showing an example of how a detection signal input process is executed.

FIG. 39 is an explanatory diagram illustrating an example of a gaming area of a third-type pachinko gaming machine.

FIG. 40 is a flowchart illustrating an example of a game state restoring process.

FIG. 41 is an explanatory diagram showing an example of bit assignment of an output port on a payout control board.

FIG. 42 is an explanatory diagram showing an example of bit assignment of input ports on a payout control board.

FIG. 43 is a flowchart showing a main process executed by the CPU in the payout control board.

FIG. 44 is a flowchart showing a 2 ms timer interrupt process.

FIG. 45 is an explanatory diagram showing one configuration example of a RAM in the payout control means.

FIG. 46 is an explanatory diagram showing a configuration example of a reception buffer.

FIG. 47 is a flowchart illustrating an example of a command receiving process of the payout control CPU.

FIG. 48 is a flowchart illustrating an example of a command analysis execution process.

FIG. 49 is a flowchart illustrating an example of a payout stop state setting process.

FIG. 50 is a flowchart illustrating an example of a switch process.

FIG. 51 is a flowchart illustrating an example of a ball lending control process.

FIG. 52 is a flowchart illustrating an example of a ball lending count switch check process.

FIG. 53 is a flowchart illustrating an example of a winning ball control process.

FIG. 54 is a flowchart illustrating an example of a winning ball control process.

FIG. 55 is a flowchart illustrating an example of a winning ball count switch check process.

FIG. 56 is a flowchart showing non-maskable interrupt processing in the payout control means.

FIG. 57 is a flowchart showing non-maskable interrupt processing in the payout control means.

FIG. 58 is a flowchart showing non-maskable interrupt processing in the payout control means.

FIG. 59 is a block diagram showing another circuit configuration of the game control board.

FIG. 60 is a flowchart showing another example of the power supply stop processing in the game control means.

FIG. 61 is a block diagram showing another configuration example of the power supply board.

FIG. 62 is a block diagram showing another configuration example of the reset management circuit.

FIG. 63 is a block diagram showing still another configuration example of the reset management circuit.

FIG. 64 is a flowchart showing another example of the power supply stop processing in the game control means.

FIG. 65 is a flowchart showing another example of the power supply stop time process in the payout control means.

FIG. 66 is a block diagram showing a portion of another configuration example of the game control means.

FIG. 67 is a flowchart showing another example of the main processing executed by the CPU on the main board.

FIG. 68 is a timing chart for explaining the operation of the software timer and the watchdog timer circuit.

FIG. 69 is a block diagram illustrating a part of another configuration example of the payout control unit.

FIG. 70 is a flowchart illustrating another example of the main process executed by the CPU in the payout control board.

FIG. 71 is a timing chart showing an example of the state of each signal when the payout process of the number of unpaid rental balls is performed.

[Explanation of symbols]

 31 game control board (main board) 37 payout control board 54 ROM 55 RAM 56 CPU 57 I / O port 162 watchdog timer circuit 371 payout control CPU 385 watchdog timer circuit 910, 910A power supply board 940, 940A reset management circuit 971 Counter (timer means)

 ──────────────────────────────────────────────────続 き Continued on the front page F-term (reference) 2C088 BA13 BA32 BA88 BB31 BC58 CA04 DA09

Claims (11)

[Claims] 1. A gaming machine in which a player can play a predetermined game, comprising: a payout control means for controlling a payout of a game medium; Payout means for paying out game media, fluctuation data storage means for storing fluctuation data generated when the payout control means performs control, and even if power supply to the gaming machine is stopped even immediately before the power supply is stopped. A storage content holding unit capable of holding a final storage content of the variation data storage unit; and a power supply monitoring unit for monitoring a state of a predetermined power supply used in the gaming machine, wherein the variation data is based on a lending request. The payout control means includes data capable of specifying the number of unpaid payouts of which the payout has not been completed among the number of payouts of game media, and the payout control means stores the number of unpaid payouts held by the storage content holding means when power supply is resumed. It is possible to restart the payout control of the game medium based on the data which can specify the power supply, and it is detected by the power supply monitoring means that the state of the predetermined power supply has become a predetermined state. In this case, the power supply monitoring unit is configured to be in a standby state after performing a power supply stoppage process related to the storage of the control state, A gaming machine comprising: a return signal output unit that can output a return signal for returning from the standby state to the payout control unit when supply is not stopped. 2. A game medium detecting means for detecting a game medium, wherein the payout control means, when the power supply monitoring means detects that the state of the power supply has reached a predetermined state, 2. A power supply stop process related to saving a control state including data that can specify the number of unpaid items after executing a process of inputting a detection signal from the game medium detecting unit for a predetermined period. The described gaming machine. 3. The dispensing control unit, after stopping the driving of the dispensing unit, when the power supply monitoring unit detects that the state of the power supply has reached a predetermined state,
3. The gaming machine according to claim 2, wherein input processing of a detection signal from the game medium detecting means is executed. 4. A payout control unit during execution of a process of inputting a detection signal from a game medium detection unit after the power supply monitoring unit detects that the state of the power supply has reached a predetermined state. 4. The gaming machine according to claim 2, further comprising an auxiliary driving power supply unit capable of supplying power capable of driving the game medium detecting unit. 5. The payout control means is capable of controlling the payout of game media according to the progress of the game, and the change data includes the completion of the payout of the payout number of the game media according to the progress of the game. The gaming machine according to claim 1, further comprising data that can specify an unpaid number that has not been paid. 6. The gaming machine according to claim 1, wherein a prize game medium detecting means and a lending game medium detecting means are separately provided as the game medium detecting means. 7. The gaming machine according to claim 1, wherein the return signal is inputted to a reset signal input section of the electric component control means. 8. A control system comprising: a plurality of electric component control means; and a return signal output means including a start order control means for controlling a start order by changing an output order of a return signal to each electric component control means. A gaming machine according to any one of claims 1 to 7. 9. An electric component control unit comprising: a game control unit for controlling the progress of a game; and another electric component control unit for controlling an electric component in accordance with a control signal from the game control unit. 9. The gaming machine according to claim 8, wherein the control means activates the game control means last. 10. The dispensing control unit executes a process of prohibiting access to the variable data storage unit in the process of stopping power supply.
The gaming machine described. 11. A power supply board for generating a voltage used in each electric component control board separately from the electric component control board on which the electric component control means is mounted, and a return signal output means is mounted on the power supply board. The gaming machine according to claim 1, wherein: