JP4431819B2 - Game machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gaming machine. In particular, the present invention relates to a gaming machine configured such that a control device starts a power failure process by a power failure signal output from a power failure detection circuit.
[0002]
[Prior art]
A gaming machine such as a pachinko machine includes a power supply circuit connected to an external AC power supply. The power circuit converts AC power input from an external power source into DC power, and supplies predetermined power to various devices provided in the gaming machine. For this reason, when the power supplied to the gaming machine from the external power source is interrupted due to a power failure or the like, the power supply from the power supply circuit to the various devices is interrupted, and the operations of the various devices are stopped.
In recent years, in this type of gaming machine, in order to be able to resume a game interrupted by a power failure or the like, a backup function is provided in some control devices (for example, a main control device) equipped in the gaming machine. It has become. A gaming machine provided with a backup function is provided with a power failure detection circuit for detecting a power failure. This power failure detection circuit outputs a power failure signal to the control device when the power supply voltage of the power supply circuit becomes lower than the set voltage. The control device that has received the power failure signal starts power failure processing and saves the game information stored in the RAM of the control device. At the time of power recovery, the control device resumes the processing interrupted by the power failure or the like based on the game information stored in the power failure processing.
As a gaming machine having a backup function, for example, the one described in Patent Document 1 is known.
[0003]
[Patent Document 1]
JP 2001-246056 A
[0004]
[Problems to be solved by the invention]
By the way, a large number of gaming machines and various electric facilities (for example, a large air-conditioning facility, a large lighting facility, etc.) are installed in the game store where the above-described gaming machine is installed. Therefore, the external power supply connected to the gaming machine fluctuates due to the influence of many other gaming machines and electrical equipment installed in the gaming store. This fluctuation of the external power supply also affects the power supply circuit of the gaming machine, causing only the power supply voltage when the power supply is turned on (the power supply voltage rises while oscillating). For this reason, after a power supply voltage exceeds a setting voltage and a control apparatus starts a normal process, a power supply voltage becomes below a setting voltage again, and a power failure signal may be output from a power failure detection circuit. When the power failure signal is output, each control device starts power failure processing again, so that the gaming machine may not be started normally.
[0005]
The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a gaming machine capable of starting up a gaming machine normally even when a disturbance occurs in the power supply voltage of a power supply circuit when the power supply is turned on. It is.
[0006]
The inventors of the present invention have made various studies in order to solve the above-described problem, and have found that the above-described problem can be solved by starting the processing of the control device after the power supply voltage of the power supply circuit is stabilized.
At this time, it was first considered to deal with hardware as a method for delaying the start of processing of the control device. However, the disturbance of the power supply voltage at the time of starting up the power varies depending on the game store, and also varies depending on the operation status of the electrical equipment installed in the game store. For example, the electric power used by the air conditioning equipment installed in an amusement store differs between summer and winter, and also changes depending on the operating status of the air conditioning equipment. For this reason, in order to cope with hardware, it is necessary to delay the processing start time of the control device for a long time with a margin. Therefore, depending on the game store, the processing of the control device will be delayed more than necessary.
[0007]
[Problems, means and effects for solving the problems]
Accordingly, a first gaming machine according to the present application created to solve the above problems includes a power supply circuit connected to an external power supply, a control device that operates with power supplied from the power supply circuit, and a power supply circuit. A power failure detection circuit that outputs a power failure signal to the control device when the power supply voltage is equal to or lower than a set voltage, and the control device is configured to start a power failure process upon receiving the power failure signal.
The control device includes (1) counting means for starting counting when the power supply voltage from the power supply circuit becomes equal to or higher than a preset voltage due to power-on or power-up, and the control device is reset. ) Means for starting normal processing when the numerical value counted by the counting means reaches the set value. (3) Initializing the count value of the counting means when a power failure signal is received while counting is being performed by the counting means. And a program for causing the control device to function.
In the above gaming machine, when the power supply voltage becomes equal to or higher than the set voltage due to power-on or the like, the control device is reset and counting by the counting means is started. Then, when the count value by the counting means reaches the set value, normal processing is started. That is, even if the control device is reset, normal processing is not started immediately, and normal processing is started after the set value is counted. Therefore, normal processing by the control device is started after the power supply voltage is stabilized.
Further, if the power supply voltage is disturbed and a power failure signal is output while counting is being performed, the counting by the counting means is initialized and counting is started again. For this reason, since only the set value is counted after the disturbance of the power supply voltage is settled, normal processing is started by the control device after the power supply voltage becomes more stable.
In addition, since the process of the control apparatus mentioned above is performed by software by a program, a setting value can be changed easily and individual correspondence for every game store is attained.
[0008]
Moreover, it is preferable that the said control apparatus is provided with the setting value change means to change the said setting value. In such a configuration, the set value is changed by the set value changing means, and an appropriate set value can be obtained.
The set value changing means can be configured by switches (for example, a dial switch) operated by a store clerk or the like of an amusement store. Or it can comprise as a means to change a setting value automatically by a control apparatus. When the set value is automatically changed, for example, the set value can be changed from a temporal change (for example, a voltage gradient) of the power supply voltage when the power is turned on.
Furthermore, it is preferable that the control device further includes means for storing and holding the set value when power supplied to the control device is interrupted.
In such a configuration, when the set value is changed by the set value changing means, the set value is retained even while the power is shut off. For this reason, when the power is turned on or the power is restored after the power is turned off, counting is performed with the changed set value.
In each of the above gaming machines, the control device is preferably a main control device. In such a configuration, when a power failure signal is received while the main control device is counting by the counting means, the count value by the counting means is initialized. Therefore, at least the main control device does not complete the processes (1) to (3) unless the power supply voltage is stabilized (that is, does not shift to the normal process). For this reason, the main control device further delays the start of normal processing by the time until the power supply voltage stabilizes in addition to the time determined by the counting means. Thus, for example, the main control device shifts to normal processing earlier than the lower control device, and the main control device does not start normal processing when the main control device outputs a command to the lower control device. It is possible to prevent the problem that the lower control device cannot receive the command from the control device.
[0009]
Further, the second gaming machine according to the present application created to solve the above problems includes a power supply circuit connected to an external power supply, a plurality of control devices that operate by power supplied from the power supply circuit, and a power supply circuit. And a power failure detection circuit that outputs a power failure signal to each control device when the power supply voltage is lower than a set voltage, and each control device is configured to start power failure processing upon receipt of the power failure signal.
Each control device includes (1) counting means for starting counting when the power supply voltage from the power supply circuit becomes equal to or higher than a preset voltage by power-on or power-up, and the control device is reset. (2) Counting Means for starting normal processing when the numerical value counted by the means reaches a set value; (3) means for initializing the count value of the counting means when a power failure signal is received while counting is being performed by the counting means. And a program for causing the control device to function as at least three means. And the said setting value is set individually for every control apparatus, It is characterized by the above-mentioned.
This gaming machine can achieve the same operational effects as those of the first gaming machine according to the present application described above. Furthermore, in this gaming machine, since the setting values are individually set for each control device, the control device can start normal processing in a desired order. For this reason, it becomes easy to synchronize between the control devices.
[0010]
In the second gaming machine, the plurality of control devices include a main control device that controls the entire gaming machine and a sub control device that operates according to a command from the main control device, and is set in the main control device. It is preferable that the set value set is larger than the set value set in the sub-control device.
In such a configuration, after the sub control device starts normal processing, the main control device starts normal processing. Therefore, it is possible to prevent the occurrence of a problem that the sub control device cannot receive a command from the main control device because the sub control device has not started normal processing.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
The gaming machines described in the above claims can be suitably implemented in the forms shown below.
(Form 1) The gaming machine described in the claims is a pachinko machine. This pachinko machine is provided with a sub-control board as a higher-level control device and a display control board as a lower-level control device.
(Mode 2) In the gaming machine described in mode 1, the timing at which the sub control board outputs the clear signal is configured to be before the timing at which the display control board checks the state of the clear signal.
(Mode 3) In the gaming machine according to mode 2, the timing for shifting to the steady process after the power reset of the sub control board is delayed from the timing for shifting to the steady process after the power reset of the display control board. It is configured.
(Mode 4) In the gaming machine according to mode 1, a main control board is provided as a higher-level control device of the sub control board. The main control board has a backup function for storing information in the storage means (RAM) when the power is turned off, and resumes the processing suspended when the power is turned off using the information saved when the power is restored.
(Embodiment 5) In the gaming machine described in Embodiment 4, the timing at which the main control board is shifted to the steady process after the power reset of the main control board is delayed from the timing at which the shift to the steady process is performed after the other control boards are reset. It is configured.
[0012]
【Example】
Hereinafter, a pachinko machine according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a front view showing an appearance of a pachinko machine according to the present embodiment. As shown in FIG. 1, the pachinko machine is provided with an upper plate 93, a lower plate 21, a handle 20, a speaker 28, a lamp 34, and a game board 14. The upper plate 93 is a tray for receiving the prize balls, and the lower plate 21 is a tray for storing the prize balls when the upper plate 93 overflows with the prize balls. The handle 20 is a member that is operated when the player plays a pachinko game. The speaker 28 generates a sound effect or the like according to the gaming state, and the lamp 34 is lit according to the gaming state.
[0013]
The game board 14 is provided with a symbol display device 15 in the center thereof, and a first type starting port 25 and a big winning port 26 are provided below it.
The first type start port 25 is provided with a start port sensor 41. When the pachinko ball wins the first type starting port 25, the starting port sensor 41 detects the pachinko ball and the symbol display device 15 starts the symbol variation display. Further, when a pachinko ball wins the first type start opening 25, the prize ball is paid out to the upper plate 93.
The special winning opening 26 is provided with an open / close lid 27 and a solenoid 40 for opening and closing the open / close lid 27. The opening / closing lid 27 is opened for a predetermined time (in this embodiment, a period in which ten winning balls are detected with an upper limit of 30 seconds) when symbol variation described later stops at a predetermined symbol combination (hereinafter, the opening / closing lid 27 is The open state is called a big hit state). When the open / close lid 27 is opened, a pachinko ball can be awarded in the grand prize opening 26, and when the pachinko ball wins in the big prize opening 26, the prize ball is paid out to the upper plate 93. A V zone (not shown) is provided in the special winning opening 26, and a V zone sensor (not shown) is provided in the V zone. When the pachinko ball wins the V zone, the V zone sensor detects the pachinko ball, and based on this, the open / close lid 27 is opened a predetermined number of times (maximum 16 times).
[0014]
The symbol display device 15 has a symbol display 23 made of a liquid crystal display. The symbol display 23 has three special symbols: a left special symbol (hereinafter simply referred to as the left symbol) on the left side of the screen, a middle special symbol (hereinafter simply referred to as the middle symbol) in the center of the screen, and a right symbol on the right side of the screen. A special symbol (hereinafter simply referred to as the right symbol) is displayed. In the present embodiment, numerals 0 to 9 are used for the left symbol, the middle symbol, and the right symbol, and these symbols start to change when the pachinko ball wins the first type starting port 25 described above. The special symbol that has started to change stops changing in the order of the left symbol, the right symbol, and the middle symbol after a predetermined time has elapsed. When the combination of symbols at the time of the fluctuation stop becomes a predetermined combination (in the present embodiment, a doublet such as 7, 7, 7, etc.), the above-described open / close lid 27 of the special winning opening 26 is opened.
In the present embodiment, when the combination of symbols at the time of fluctuation stop becomes a big hit with an odd number of eyes (for example, 1 · 1 · 1, 3 · 3 · 3, etc.), a high probability state with a high probability of making a big hit ( So-called probabilistic state). In the high probability state, the probability of winning a big hit increases, and at the same time, a variation pattern with a short variation time is preferentially selected for the symbol variation displayed on the symbol display 23 (so-called time shortening state). Therefore, when a high probability state is entered, a lot of symbol variations are displayed on the symbol display 23 due to time reduction, and the probability that each symbol variation is a big hit is increased, so that the gaming state is advantageous to the player.
[0015]
Next, the configuration of the control system of the pachinko machine of the present embodiment will be described. FIG. 2 is a block diagram showing the configuration of the control system of the pachinko machine of the present embodiment. As shown in FIG. 2, the pachinko machine of this embodiment is provided with a main control board 62, a sub control board 70, a display control board 78, a payout control board 52, and a launch control board 88.
[0016]
The main control board 62 is a control device that comprehensively controls the pachinko game. The main control board 62 includes a main CPU 64 as processing execution means for performing overall control related to pachinko games. The main CPU 64 includes a ROM 66 and a RAM 68. The ROM 66 stores a game control program related to the entire pachinko game and preset data necessary for executing the game control program. The RAM 68 is a storage means that can be read and written as needed, and stores various data and input / output signals when the main CPU 64 executes the game control program.
In addition, the main control board 62 is provided with an input / output interface circuit (not shown) including an input / output port LSI, a transistor, various logic ICs, and the like. Detection signals output from various detectors (for example, the start port sensor 41) are input to the main CPU 64 via the input / output interface circuit. Further, the main CPU 64 performs control output to various driving devices (for example, the solenoid 40) via the input / output interface circuit. The main control board 62 is connected to the sub-control board 70 and the payout control board 52 and performs data communication with these control boards 70 and 52. The main control board 62 and the sub control board 70 are connected so that data communication (that is, command communication) is possible only in one direction from the main control board 62 to the sub control board 70. Similarly, the main control board 62 and the payout control board 52 are connected so that data communication can be performed only in one direction from the main control board 62 to the payout control board 52.
[0017]
The sub-control board 70 controls lamps such as lighting and blinking of the lamp 34 based on the command transmitted from the main control board 62, voice control for outputting sound effects from the speaker 28, and command transmitted from the main control board 62. This is a control device that transmits a command to the reception and display control board 78. The sub control board 70 is equipped with a sub CPU 72 as a process execution means. The sub CPU 72 is also provided with a ROM 74 and a RAM 76. The ROM 74 stores a control program for the sub CPU 72 to execute the various controls described above, and preset data necessary for executing these control programs. The RAM 76 is a storage means that can be read and written at any time, and stores various data and input / output signals when the sub CPU 72 executes the control program.
In addition to the main control board 62, the sub control board 70 is provided with an output interface circuit (not shown). The sub CPU 72 is connected to the lamp 34 and the speaker 28 via an output interface circuit. The sub control board 70 is connected to the main control board 62 and the display control board 78. Note that the sub control board 70 and the display control board 78 are connected so that data communication can be performed only in one direction from the sub control board 70 to the display control board 78.
When the sub CPU 72 receives a command from the main control board 62 and the received command is a command related to lamp control or voice control, the sub CPU 72 drives the lamp 34 in accordance with the command, and produces sound effects from the speaker 28. On the other hand, when the received command is not related to lamp control or voice control (that is, a command related to display control of the symbol display 23), this command is transmitted to the display control board 78 as it is.
[0018]
The display control board 78 is a control device that receives a command transmitted from the sub-control board 70 and displays a game image (for example, symbol variation of a special symbol) on the symbol display 23. The display control board 78 is also equipped with a display CPU 80 and a VDP 86 (video display processor) as processing execution means. The display CPU 80 includes a ROM 82 and a RAM 84. The ROM 82 stores a control program for displaying a game image on the symbol display 23. The RAM 84 is a storage unit that can be read and written as needed, and stores various data and input / output signals when the display CPU 80 executes the control program. The symbol display 23 is connected to the VDP 86. The VDP 86 generates image data according to the control output of the display CPU 80, and performs processing for outputting the generated image data to the symbol display 23. In addition to the main control board 62, the display control board 78 is provided with an interface circuit (not shown). The display CPU 80 is connected to the sub control board 70 via an interface circuit.
[0019]
The payout control board 52 is a control device that controls the payout device 90 based on a command (prize ball command) transmitted from the main control board 62. The payout control board 52 includes a payout CPU 56 as processing execution means. The payout CPU 56 also includes a ROM 58 and a RAM 60. The ROM 58 stores a control program for paying out a prize ball based on a prize ball command from the main control board 70. The RAM 60 is a storage means that can be read and written as needed, and stores various data and input / output signals when the payout CPU 56 executes the control program. Further, the payout control board 52 and the launch control board 88 are connected to each other through an interface circuit provided on each board in the same manner as the main control board 62. The launch control board 88 is a control device that controls a launch motor of a launch device that launches a pachinko ball toward the game board 14.
[0020]
Power is supplied from the power supply board 50 to each of the control boards 52, 62, 70, 78, 88 and various devices (the symbol display 23, the speaker 28, the lamp 34, etc.) described above. The power supply board 50 is connected to an external AC power supply via a distribution board (specifically, a board for distributing an external AC power supply (AC24V) to a card unit connected to the gaming machine) equipped in the gaming machine. The electric power supplied from the external AC power source is converted into operating voltages (+ 5V, + 12V, + 34V) of each control board and various devices, and supplied to each control board and various devices. For example, the CPUs (payout CPU 56, main CPU 64, sub CPU 72, display CPU 80) of each control board 52, 62, 70, 78 are arranged in the order of payout CPU 56 → main CPU 64 → sub CPU 72 → display CPU 80 as shown in FIG. Electric power (+ 5V) is supplied.
[0021]
The power failure detection circuit 54 is provided on the payout control board 52. The power failure detection circuit 54 is a circuit that detects that the power supply from the external AC power source to the pachinko machine is cut off, and the power supply voltage (+ 34V) generated by the power supply board 50 is a set voltage (15V in this embodiment). ) Output a power failure signal (ON) when the voltage drops below. That is, when the power supply voltage is higher than the set voltage, the power failure signal is turned off, and when the power supply voltage is lowered below the set voltage, the power failure signal is turned on. The power failure signal output from the power failure detection circuit 54 is input to the CPUs (payout CPU 56, main CPU 64, sub CPU 72, display CPU 80) of the control boards 52, 62, 70, 78 described above. Specifically, a power failure signal is input to the main CPU 64 and the payout CPU 56 via the input port, while a power failure signal is input to the sub CPU 72 and the display CPU 80 via the INT terminal. Accordingly, the main CPU 64 and the payout CPU 56 monitor the power failure signal by polling, while the sub CPU 72 and the display CPU 80 start a power failure signal interrupt process (described later) when the power failure signal is input.
Further, the main CPU 64 and the payout CPU 56 have a backup function so that the information stored in the RAM 68 and the RAM 60 can be saved even while the power is cut off, and the process interrupted when the power is restored can be resumed. On the other hand, the sub CPU 72 and the display CPU 80 are not provided with a backup function.
The backup power supply includes an electric double layer capacitor (with a built-in resistor that suppresses inrush current) connected to the + 5V power source supplied from the power supply board 50, and an electric double layer capacitor that prevents backflow during backup. To Schottky diodes (the forward voltage is small) for switching to the supply path from the RAM to the RAMs 60 and 68.
[0022]
Next, processing performed by the CPUs 56, 64, 72, and 80 of the control boards 52, 62, 70, and 78 will be described with reference to the drawings. First, processing performed by the main CPU 64 of the main control board 62 will be described.
[0023]
(1) Main control board
When the power is reset, the main CPU 64 performs non-steady processing such as standby processing and power recovery processing, and when this non-steady processing ends, the main CPU 64 proceeds to steady processing. When the process shifts to a steady process, a timer interrupt process by a cycle time counter (hereinafter simply referred to as CTC) is performed periodically (every 4 ms in this embodiment) while repeatedly performing a predetermined process. First, the process at the time of power reset of the main CPU 64 will be described with reference to FIG. 3, and then the timer interrupt process of the main CPU 64 will be described with reference to FIG.
[0024]
(1-1) Processing at the time of power reset of the main CPU 64
FIG. 3 shows a flowchart of processing when the power of the main CPU 64 is reset. As shown in FIG. 3, when the power is reset, the main CPU 64 first performs an initialization process (S10), and sets a first set value in a standby time counter (S11). The standby time counter is a timer that defines a standby time from when the power of the main CPU 64 is reset to when the main CPU 64 shifts to normal processing (consisting of power recovery processing and steady processing). In this embodiment, the first set value in step S11 is 1200 ms, and this value is stored in the ROM 66 of the main CPU 64.
In step S12, the main CPU 64 determines whether or not the state of the power failure signal output from the power failure detection circuit 54 is OFF. When the state of the power failure signal is not OFF [NO in step S12], the process returns to step S11, and the first set value is set again in the standby time counter. Therefore, when the power supply voltage (+ 34V) becomes unstable when the power is turned on and the power failure signal is turned ON / OFF (as shown in FIG. 12), the power supply voltage is stable (the power failure signal is maintained OFF). Transition to normal processing is waited for a predetermined time (time defined by the first set value). On the other hand, when the state of the power failure signal is OFF [YES in Step S12], the value of the standby time counter is decremented by 1 (S13), and it is determined whether or not the value of the standby time counter becomes 0 (S14). . If the value of the standby time counter is 0 [YES in step S14], the process proceeds to step S15. If the value of the standby time counter is not 0 (NO in step S14), the process returns to step S12 and the standby time counter is counted down. continue.
[0025]
In step S15, it is determined whether or not the RAM clear switch is turned on. The RAM clear switch is a switch operated by a game shop clerk or the like, and is a switch for inputting whether or not to erase information stored in the RAM 68 of the main CPU 64 and information stored in the RAM 60 of the payout CPU 56 when the power is turned off. .
If the RAM clear switch is operated (YES in step S15), the information in the RAM 68 is cleared (S17). If the RAM clear switch is not operated (NO in step S15), the information stored in the RAM 68 is stored. It is determined whether or not it is normal (S16). Whether or not the information stored in the RAM 68 is normal is determined by whether or not the checksum value calculated by performing a predetermined calculation using the data in the RAM 68 is normal.
If the information in the RAM 68 is not normal [NO in step S16], the information in the RAM 68 is cleared (S17), and the process proceeds to step S18. On the other hand, if the information in the RAM 68 is normal [YES in step S16], the process proceeds to step S18. In step S18, initialization of interrupt processing is performed and interrupt processing is permitted. As a result, the main CPU 64 can perform timer interrupt processing, which will be described in detail later, and shift to steady processing. If the information stored in the RAM 68 is not cleared, the process proceeds to the steady process while the information stored when the power is turned off is held in the RAM 68, and the process interrupted when the power is turned off is resumed.
[0026]
When shifting to the steady process, it is first determined whether or not the power failure signal is ON (S19). If the power failure signal is not ON [NO in step S19], non-winning random number update processing is performed (S20). The non-winning random number means a random number other than a random number for determining whether or not the pachinko machine is a big hit or a probable change, and corresponds to, for example, a reach random number, a fluctuation pattern random number, or the like. When the counter value for determining the unreasonable random number is updated in step S20, the process returns to step S19, and the processing from step S19 is repeated.
[0027]
On the other hand, if the power failure signal is ON (YES in step S19), interrupt processing is prohibited (S21), then a checksum value is calculated and stored in the RAM 68 (S22), and the RAM 68 is accessed. It is prohibited (S23). As a result, the state of the RAM 68 when the power failure signal is turned on (that is, when the power is turned off) is saved. The RAM 68 is supplied with power from a backup power source (a capacitor or the like) even during power shutdown. For this reason, the information stored in the RAM 68 is retained even while the power is shut off. Then, the processing from step S10 is started again by power reset (so-called power-on reset) or time-up of the watchdog timer performed thereafter, and the processing performed at the time of power-off based on the information stored in the RAM 68 Is resumed.
Note that whether or not to proceed to the processing from step S21 described above (processing when power is cut off) is determined when the power failure signal is ON a plurality of times and when the power failure signal ON state continues a plurality of times. Alternatively, the process may be shifted from step S21.
[0028]
(1-2) Main CPU 62 timer interrupt processing
FIG. 4 shows a flowchart of timer interrupt processing of the main CPU 64 by CTC. This timer interrupt process is the same as the process in a conventionally known pachinko machine, and will be briefly described here.
As shown in FIG. 4, when the timer interrupt process is started, the main CPU 64 first prohibits the interrupt (S24a). Then, the register information is saved (S24b), and then a switch input process is performed (S25). The switch input process is a process of taking a detection signal from the start port sensor 41 or the like into the main CPU 64.
In step S26, a process for updating a winning random number such as a jackpot random number is performed, and then a process for generating a command (prize ball command or the like) to be transmitted to the payout control board 52 is performed (S27), and the special symbol is displayed in a variable manner. For example, a command for creating the drive data for driving the solenoid 40 is generated (S28). In step S29, a process of outputting the command and drive data created in step S27 and step S28 to the payout control board 52, the sub control board 70, and the solenoid 40 is performed (S29).
In step S30, the register saved in step S24 is restored, and then interrupt is permitted (S31). As a result, the main CPU 64 returns to the steady process (steps S19 to S20) in FIG.
[0029]
(2) Dispensing control board
Next, processing performed by the payout CPU 56 of the payout control board 52 will be described. The payout CPU 56 performs substantially the same processing as the main CPU 64. That is, when the power is reset, first, unsteady processing such as standby processing and power recovery processing is performed, and when this unsteady processing ends, the routine proceeds to steady processing. When shifting to the steady process, the timer interrupt process by CTC is periodically performed (every 1 ms unlike the main CPU 64) while repeatedly performing the predetermined process. First, the process at the time of power resetting of the payout CPU 56 will be described with reference to FIG. 5, and then the timer interrupt process of the payout CPU 56 will be described with reference to FIG.
[0030]
(2-1) Processing at the time of power reset of the payout CPU 56
FIG. 5 shows a flowchart of processing when the payout CPU 56 resets the power supply. As shown in FIG. 5, when the power supply is reset, the payout CPU 56 first performs an initialization process (S32), and sets a second set value in the standby time counter (S33). In this embodiment, the second set value in step S33 is 200 ms, which is shorter than the standby time of the main CPU 64. This second set value is preferably set based on the time obtained until the power supply voltage is stabilized (time until the power failure signal is not output when the power is restored) is experimentally obtained. In the present embodiment, the provisional value is set to 200 ms.
In step S34, the payout CPU 56 subtracts 1 from the value of the standby time counter (S34), and determines whether or not the value of the standby time counter has become 0 (S35). If the value of the standby time counter is 0 [YES in step S35], the process proceeds to step S36, and if the value of the standby time counter is not 0 (NO in step S35), the process returns to step S34 to count down the standby time counter. continue. Therefore, unlike the main CPU 64, the payout CPU 56 continues to count down the standby time counter even when the power supply voltage is unstable and the power failure signal is turned on and off.
If it progresses to step S36, it will be determined whether the power failure signal is set to ON (S36). If the power failure signal is ON (YES in step S36), the process waits until the power failure signal is turned OFF. If the power failure signal is not ON (NO in step S36), the process proceeds to step S37. That is, unlike the main CPU 64, the payout CPU 56 continues the countdown of the standby time counter even when the power supply voltage is unstable. Therefore, after the countdown of the standby time counter ends, the state of the power failure signal is confirmed and the power failure signal is turned off. To wait until.
Note that when the standby process in steps S33 to S35 is started, the watchdog timer is activated, and the watchdog timer is cleared by the payout CPU 56 during the standby process. On the other hand, during the power failure warning signal determination process in step S36, the payout CPU 56 does not clear the watchdog timer. Therefore, when the power failure warning signal is still output even after the standby process is completed, the payout CPU 56 is reset by the time-up of the watchdog timer. In this embodiment, since the time-up time of the watchdog timer is set to 200 ms, the total of 600 ms (waiting time 200 ms + time-up) is required to reset the payout CPU 56 again by the time-up and complete the power failure warning signal determination processing. Time 200 ms + standby time 200 ms). The standby time (that is, the second set value) of the present embodiment is set from the experimentally obtained time, but assuming such a case, the standby time of the main control board 62 has a margin. (1200 ms in this embodiment) is set.
[0031]
In step S37, it is determined whether or not the RAM clear switch has been operated (S37). If the RAM clear switch has been operated [YES in step S37], the information in the RAM 60 is cleared (S39) and the RAM is cleared. If the switch is not operated [NO in step S37], it is determined whether or not the information stored in the RAM 60 is normal (S38). The determination in step S38 is also performed in the same manner as the determination in step S16 of the main CPU 64.
If the information in the RAM 60 is not normal [NO in step S38], the information in the RAM 60 is cleared (S39), and the process proceeds to step S40. On the other hand, if the information in the RAM 68 is normal [YES in step S38], the process proceeds directly to step S40. In step S40, initialization of interrupt processing is performed and interrupt processing is permitted. Thereby, the payout CPU 56 shifts to a steady process. If the information in the RAM 60 is not cleared, the process suspended when the power is turned off is resumed as in the main CPU 64.
[0032]
When shifting to the steady process, it is first determined whether or not the power failure signal is ON (S41). If the power failure signal is not ON [NO in step S41], it is determined whether the timer interrupt generation flag is ON (S42). The timer interrupt generation flag is a flag that is turned ON when a timer interrupt process described later is performed. If the timer interrupt generation flag is not turned on [NO in step S42], the process returns to step S41 and repeats the processing from step S41. If the timer interrupt generation flag is turned on (YES in step S42), steps S43 and after Proceed to the process.
In step S43, first, the timer interrupt generation flag is turned OFF, and then the main process is performed (S44). In the main process of step S44, a process of receiving a command from the main CPU 64, a process of analyzing the received command, a process of controlling the payout device 90 based on the analysis result, and the like are performed. When the main process in step S44 ends, the process returns to step S41 again, and the processes from step S41 are repeated. Since the timer interrupt generation flag is turned off in step S43, the processes after step S43 are not performed unless the next timer interrupt process is performed.
[0033]
On the other hand, if the power failure signal is ON [YES in step S41], the driving of the payout motor of the payout device 90 is stopped (S45), and then interrupt processing is prohibited (S46). Then, a checksum value is calculated and stored in the RAM 60 (S47), and access to the RAM 60 is prohibited (S48). Thus, the state of the RAM 60 when the power failure signal is turned on (that is, when the power is turned off) is saved. Similarly to the RAM 68 of the main control board 62, the RAM 60 is supplied with power from a backup power supply (a capacitor or the like) even while the power is cut off. Therefore, the information stored in the RAM 60 is retained even while the power is cut off. Then, the process from step S32 is started again by power reset (so-called power-on reset) or time-up of the watchdog timer, and the process that was performed when the power was cut off based on the information stored in the RAM 60. Is resumed.
[0034]
(2-2) Timer interrupt processing of payout CPU 56
FIG. 6 shows a flowchart of timer interrupt processing of the payout CPU 56 by the CTC timer. As shown in FIG. 6, when the timer interrupt process is started, the payout CPU 56 first saves the register information (S49), then turns on the timer interrupt generation flag (S50), and saves it in step S49. The register is restored (S51). As a result, the payout CPU 64 returns to the steady process (steps S41 to S44) in FIG.
[0035]
(3) Sub control board
Next, processing performed by the sub CPU 72 of the sub control board 70 will be described. Similarly to the main CPU 64 and the payout CPU 56, when the power is reset, the sub CPU 72 first performs an unsteady process such as a standby process or a power recovery process. When the unsteady process ends, the sub CPU 72 shifts to a steady process. When the process shifts to the steady process, the interrupt process by the CTC is periodically executed while repeating the predetermined process. In addition, since the sub CPU 72 does not have a backup function, the processing when the power failure signal is turned on (processing when the power is turned off) is performed not by polling but by interruption due to the power failure signal so as to be able to respond as soon as possible. In the process when the power of the sub control board 70 is turned off (power failure process), the main control board 62 having a backup function and the payout control board 52 can execute each power failure process (process when the power is turned off) with a margin. As described above, in order to reduce the load capacity as much as possible, lamp turn-off processing and the like are performed together with register saving processing and the like. (In the main control board 62 and the payout control board 52, a power failure signal is detected by polling in order to avoid malfunction due to noise.) The processing at the time of power reset of the sub CPU 72 will be described below with reference to FIG. Referring to FIG. 8, the timer interrupt process of the sub CPU 72 will be described, and finally, the power failure signal interrupt process of the sub CPU 72 will be described with reference to FIG.
[0036]
(3-1) Processing at power reset of sub CPU 72
FIG. 7 shows a flowchart of processing when the power of the sub CPU 72 is reset. As shown in FIG. 7, when the power is reset, the sub CPU 72 first performs an initialization process (S52), sets a third set value in the standby time counter, and starts counting down the standby time counter (S53). . The third set value in step S53 is 200 ms, which is shorter than the standby time of the main CPU 64 and is the same as the standby time of the payout CPU 56.
In step S54, it is first determined whether or not the RAM 76 of the sub CPU 72 is normal. Whether the RAM 76 is normal is determined by calculating a checksum value.
If the RAM 76 is normal [YES in step S54], the information saved by the power interruption interruption process described later is restored (S55), and the clear signal output to the display control board 78 is turned OFF (S56). On the other hand, if the RAM 76 is not normal [NO in step S54], the RAM 76 is cleared (S57), and the clear signal output to the display control board 78 is turned ON (S58). This clear signal is a 1-bit status signal for instructing whether or not to clear the information in the RAM 84 of the display CPU 80. Further, steps S56 and S58 are performed immediately after the countdown of the standby time counter is started in step S53, so that the clear signal is set immediately after the power is reset.
[0037]
In step S59, it is determined whether or not the value of the standby time counter has become 0 (S59). If the value of the standby time counter becomes 0 [YES in step S59], the process proceeds to step S60. If the value of the standby time counter is not 0 [NO in step S59], the process waits until the value of the standby time counter becomes 0. .
In step S60, it is determined whether or not the power failure signal is ON (S60). If the power failure signal is ON (YES in step S60), the process waits until the power failure signal is turned OFF. If the power failure signal is not ON (NO in step S60), the process proceeds to step S61. Therefore, the sub CPU 72 confirms the state of the power failure signal after completion of the countdown of the standby time counter, as with the payout CPU 56, and proceeds to the next process if the power failure signal is OFF.
[0038]
In step S61, the fourth set value is set again in the standby time counter and the countdown of the standby time counter is started. Therefore, the sub CPU 72 waits longer than the display CPU 80 and the payout CPU 56, which will be described later, by counting down the standby time counter twice. In the present embodiment, the fourth set value in step S61 is set to 200 ms.
In step S62, it is determined whether or not the value of the standby time counter has become 0 (S62). If the value of the standby time counter is 0 (YES in step S62), the process proceeds to step S63 and proceeds to a steady process. If the value of the standby time counter is not 0 (NO in step S62), the value of the standby time counter is 0. Wait until
[0039]
When the process shifts to the steady process, it is first determined whether or not the timer interrupt generation flag is ON (S63). The timer interrupt generation flag is turned on by a timer interrupt process described later, and is turned off in the main process of step S66. If the timer interrupt generation flag is OFF [NO in step S63], the process waits until the timer interrupt generation flag is turned ON. If the timer interrupt generation flag is ON (YES in step S63), an operating signal from the display CPU 80 (described later). ) Is determined (S64). When the operating signal is not received (NO in step S64), the clear signal is turned ON (step S65b), and when the operating signal is received (YES in step S64), the clear signal is turned OFF (S65a). The process proceeds to the main process in step S66. That is, when the operating signal is output from the display CPU 80, it can be determined that the display CPU 80 has shifted to the steady process, and therefore the clear signal output from the sub CPU 72 is changed from ON to OFF. The sub CPU 72 waits for the process of step S64 until the timer interrupt generation flag is turned ON in step S63. As will be described later, in this embodiment, a timer interrupt process is performed using a 2 ms timer. When this timer interrupt process is performed eight times, the timer interrupt generation flag is turned ON, and the process proceeds to step S64. ing. In addition, sampling of the operating signal determined in step S64 is also performed in the timer interrupt process.
After shifting to the main processing in step S66, the sub CPU 72 performs lighting control of the lamp 34, sound control of the speaker 28, command transmission processing to the display control board 78, and the like based on the command transmitted from the main control board 62. If YES in step S54 (when the RAM 76 is normal), the RAM 76 has been restored to the state at the time of power failure signal reception, so that this main process is resumed from the state interrupted by the power failure signal reception. It becomes. Accordingly, the lighting / flashing of the lamp 34 and the generation of sound effects from the speaker 28 are continued. When the main process in step S66 ends, the process returns to step S63 again, and the processes from step S63 are repeated.
[0040]
(3-3) Timer interrupt processing of sub CPU 72
FIG. 8 shows a flowchart of the timer interrupt process of the sub CPU 72 by the CTC timer. As shown in FIG. 8, when the timer interrupt process is started, the sub CPU 72 first reads and stores the operating signal (that is, stores the status of the operating signal) (S91), and then the latest timer. It is determined whether or not the number of times the timer interrupt process has been executed since the interrupt generation flag is ON is 8 (S92). If the number of executions of the timer interrupt process is not eight (NO in S92), the timer interrupt process is terminated as it is. On the other hand, when the number of executions of the timer interrupt process is 8 [YES in S92], the timer interrupt generation flag is turned on (S93), and the timer interrupt process is terminated.
As is apparent from the above, the timer interrupt generation flag is turned ON every time the timer interrupt process is performed eight times. In this embodiment, the timer interrupt processing of the sub CPU 72 is performed every 2 ms, so that the timer interrupt generation flag is turned on (that is, steps S64 to S66 in FIG. 7) every 16 ms.
[0041]
(3-3) Power failure signal interrupt processing of the sub CPU 72
FIG. 9 shows a flowchart of processing (power failure signal interruption processing) when the sub CPU 72 receives a power failure signal. As shown in FIG. 9, when the power failure signal interrupt process is started, the sub CPU 72 first saves the register information in the RAM 76 (S67), and then performs a process of turning off the lamp 38 (S68). Next, it is determined whether or not the power failure signal is ON (S69).
If the power failure signal is OFF [NO in step S69], the information saved in step S67 is returned to the register of the RAM 76 (S70), and the power failure signal interrupt processing is terminated. On the other hand, if the power failure signal is ON [YES in step S69], the determination in step S69 is repeated until the power failure signal is turned OFF. Therefore, (1) when the power failure signal does not turn off (so-called when the power failure signal is kept on), the operation of the sub CPU 72 is stopped during the loop of step S69 by being below the operating voltage of the sub CPU 72. On the other hand, (2) when the power failure signal is turned off in a short time (that is, when the power failure signal is turned off before the operation of the sub CPU 72 is stopped), the process interrupted by the power failure signal reception is resumed. Is done.
(3) Even when the power failure signal is not turned OFF during the power failure interrupt process and the sub CPU 72 stops its operation, if the information in the RAM 76 at the time of power reset is normal after the power is restored within a short time after that, (In other words, YES in step S54 in FIG. 7), the process interrupted by the power failure signal is resumed. That is, when the power is restored after the sub CPU 72 stops operating and before the voltage applied to the RAM 76 becomes equal to or lower than the normal operating voltage of the RAM 76, the process interrupted by the power failure signal by the process at the time of power reset. Will be resumed.
[0042]
(4) Display control board
Next, processing performed by the display CPU 80 of the display control board 78 will be described. Similar to the sub CPU 72, when the power is reset, the display CPU 80 first performs unsteady processing such as standby processing and power recovery processing, and when this unsteady processing ends, the display CPU 80 shifts to steady processing. Further, the display CPU 80 does not perform the interrupt process by the CTC during the steady process, and further, neither the process when the power failure signal is turned on (the process when the power is turned off) nor the interrupt process due to the power failure signal is performed. Therefore, in the following description, only processing at the time of power reset of the display CPU 80 will be described.
The power failure signal input to the display control board 78 branches separately from the input path to the sub CPU 72, and is directly input to the ON / OFF circuit of the backlight drive source of the symbol display 23 (liquid crystal display). The backlight drive source is turned off. In this way, measures are taken to reduce the load at the time of a power failure (the display control board 78 performs a high-speed operation processing of complicated processing such as command reception, display control data output, and DMA transfer as described later. The backlight drive source is turned off directly by the
[0043]
(4-1) Processing at power reset of display CPU 80
FIG. 10 shows a flowchart of processing when the power of the display CPU 80 is reset. As shown in FIG. 10, when the power is reset, the display CPU 80 first performs initialization processing (S71), sets the fifth set value in the standby time counter, and starts the countdown of the standby time counter (S72). . In this embodiment, the fifth set value in step S72 is 200 ms, which is the same as the first standby time of the sub CPU 72.
When the count-down of the standby time counter is started, it is first determined whether or not the RAM 84 of the display CPU 80 is normal (S73). If the RAM 84 is normal (YES in step S73), the return process flag is turned on (S74). If the RAM 84 is not normal (NO in step S73), the return process flag is turned off (S75).
[0044]
When the abnormality determination of the RAM 84 is completed, it is determined whether or not the value of the standby time counter has become 0 (S76). If the value of the standby time counter becomes 0 [YES in step S76], the process proceeds to step S77. If the value of the standby time counter is not 0 [NO in step S76], the process waits until the value of the standby time counter becomes 0. .
When the standby process ends, it is determined whether or not the power failure signal is ON (S77). If the power failure signal is ON (YES in step S77), the process waits until the power failure signal is turned OFF. If the power failure signal is not ON (NO in step S77), the process proceeds to step S78. Therefore, unlike the sub CPU 72, the display CPU 80 does not perform the second countdown of the standby time counter, and shifts to normal processing at an earlier timing than the sub CPU 72.
[0045]
When the power failure signal is turned off, it is determined whether or not the return processing flag is turned off (S78). If the return process flag is OFF [YES in step S78], the process proceeds to step S81. If the return process flag is ON (NO in step S78), whether or not the clear signal from the sub CPU 72 is ON is further determined. Is determined (S79). If the clear signal is OFF (NO in step S79), the process proceeds directly to step S81. If the clear signal is ON (YES in step S79), the return processing flag is turned OFF (S80), and the process proceeds to step S81.
In step S81, it is determined whether or not the return processing flag is OFF (S81). If the return process flag is OFF (YES in step S81), the RAM 84 is cleared (S82). If the return process flag is ON (NO in step S81), the routine proceeds to the steady process in step S84 without clearing the RAM 84. .
Accordingly, the display CPU 80 is in a power outage only when the information in the RAM 84 is normal at the time of power reset and the clear signal from the sub CPU 72 is not received (that is, when the RAM 76 of the sub CPU 72 is normal). The processing interrupted by the above is resumed by using the information in the RAM 84 determined to be normal. Therefore, the image interrupted by the power failure is displayed on the symbol display 23 again.
[0046]
The steady process in step S84 will be described with reference to FIG. FIG. 11 shows a flowchart of the steady process in step S84. As shown in FIG. 11, the display CPU 80 first determines whether or not the VDP 86 is performing DMA transfer (S85). Specifically, the determination is made from the DMA transfer flag set based on the V blank signal output from the VDP 86. When the VDP 86 is performing DMA transfer, that is, when the DMA transfer flag is ON (YES in step S85), the process waits until the DMA transfer is completed, and when DMA transfer is completed, that is, the DMA transfer flag is set. If it is OFF [NO in step S85], the process proceeds to step S86. That is, the VDP 86 performs DMA transfer at every predetermined period (in this embodiment, every 16 ms). While the VDP 86 is performing DMA transfer, access to the VDP 86 and the like are prohibited, and the display CPU 80 waits until the DMA transfer of the VDP 86 is completed.
In step S86, the DMA transfer flag is once turned ON. Next, the display CPU 80 turns on the watch dog clear signal (S87). The watchdog clear signal is a signal for clearing a watchdog timer (not shown in FIG. 2) provided on the display control board 70.
Next, the display CPU 80 performs main processing (S88). In the main process, the display CPU 80 performs a process of outputting display control data to the VDP 86 based on the command received from the sub control board 70 in the interrupt process (not shown).
When the main processing ends, the checksum value of the RAM 84 is calculated (S89), and then the watchdog clear signal is turned OFF (S90). When the watchdog clear signal is turned OFF, the process returns to step S85 and waits until the DMA transfer of the next cycle is completed.
[0047]
Therefore, the steady process of the display CPU 80 is repeatedly performed at a predetermined cycle (16 ms in this embodiment), and the processes from step S86 to S90 are performed in the remaining period of the DMA transfer by the VDP 86.
Further, when the display CPU 80 performs the steady process once, the watch dog clear signal turned on in step S87 is turned off in step S90, so that the watch CPU clear signal (one pulse) is output from the display CPU 80. When the watchdog clear signal (one pulse) is output, the watchdog timer is reset. Therefore, as long as the display CPU 80 performs normal processing normally, the watchdog clear signal is output without interruption, and the display CPU 80 is not reset by the watchdog timer.
Note that the watchdog clear signal output from the display CPU 80 is input to an operating signal output circuit (in this embodiment, configured by a flip-flop) provided separately on the display control board 78. The in-operation signal output circuit counts the input watchdog clear signal, and turns on / off the output signal (that is, the in-operation signal) every time the watchdog clear signal is input. Therefore, the operation signal output from the display control board 78 to the sub-control board 70 is started when the display CPU 80 starts a steady process. Further, the in-operation signal that is output is turned on and off in accordance with the period of the steady process of the display CPU 80 (that is, the in-operation signal is output by one pulse each time the steady process is performed for two periods).
As described above, in this embodiment, a complicated program (program for creating an operating signal) is not required by creating an operating signal based on a clear signal for resetting the watchdog timer, It is possible to prevent the burden on the display CPU 80 that performs high-speed operation processing from increasing. Further, since the ON / OFF of the operating signal is switched in response to the clear signal, the operating signal cycle can be made substantially constant. For this reason, as long as the display CPU 80 performs control without any abnormality, the same result can be obtained for each determination of the operating signal sampling result by the sub CPU 72. Therefore, for example, when the system clock of the display CPU 80 is abnormal and an abnormality occurs in the program cycle, the operating signal is not output at the correct cycle, and the sub CPU 72 can detect such an abnormality.
[0048]
As is clear from the above, in the pachinko machine according to the present embodiment, the timing at which the control boards 52, 62, 70, and 78 (that is, the CPUs 56, 64, 72, and 80) are shifted to normal processing after the power is reset. These are determined by the set values set in the standby time counters of the control boards 52, 62, 70, 78. The relationship between the normal processing transition timings of the control boards 52, 62, 70 and 78 will be described with reference to the timing chart shown in FIG. FIG. 12 shows the waveform of the AC power supplied from the external power supply to the gaming machine when the power is turned on, the voltage waveform of the power supply voltage (+ 34V), the waveform of the power failure signal output from the power failure detection circuit, and each control board 52. , 62, 70, 78 are timing charts showing timings at which normal processing is started. Note that an error (about 0 to 180 ms) occurs in the timing of resetting the power supply of each of the control boards 52, 62, 70, and 78 due to variations in reset ICs provided on the respective control boards 52, 62, 70, and 78. However, in FIG. 12, it is assumed that the power supplies of the control boards 52, 62, 70, and 78 are simultaneously reset for the sake of simplicity.
[0049]
As shown in FIG. 12, when the power switch to the pachinko machine is turned on, power supply from the external power source AC to the pachinko machine is started ((1) in FIG. 12). When power supply from the external power supply AC is started, the power supply voltage DC of the pachinko machine gradually increases. Then, when the power supply voltage DC becomes the reset voltage of each control board 52, 62, 70, 78, the control board 52, 62, 70, 78 is reset to the power supply and starts the process at the time of power reset (first, standby processing). ((2) in FIG. 12).
The power supply voltage DC continues to rise after each control board 52, 62, 70, 78 is reset. At this time, the power supply voltage DC is affected by the external power supply AC and rises while fluctuating. When the power supply voltage DC exceeds the set voltage of the power failure detection circuit 54 (15 V in this embodiment), the power failure signal output from the power failure detection circuit 54 is OFF (HIGH level) ((3) in FIG. 12). . Note that the power failure signal output from the power failure detection circuit 54 is turned on and off as the power supply voltage DC fluctuates.
Then, when each control board 52, 62, 70, 78 finishes the standby process, the power supply voltage DC is also in a stable state, and each control board 52, 62, 70, 78 performs normal processing with the power supply voltage DC being stable. Transition. That is, the display control board 78 waits for a time T1 (200 ms) defined by the fifth set value and then shifts to normal processing, and the sub-control board 70 sets the time defined by the third set value and the fourth set value. After waiting for T2 (400 ms), the process proceeds to normal processing. The payout control board 52 waits for a time T3 (200 ms) defined by the second set value and then proceeds to normal processing. On the other hand, when the power failure signal is turned ON while the standby time counter is counting, the main control board 62 initializes (resets) the standby time counter, so that the first time after the power failure signal is maintained OFF. After waiting for a time T4 (1200 ms) defined by one set value, the routine proceeds to normal processing.
As is apparent from the above description, the timing at which the main control board 62 shifts to normal processing is configured to be later than the timing at which the other control boards 52, 70, 78 shift to normal processing. In addition, the timing at which the sub control board 70 shifts to the normal processing is configured to be later than the timing at which the display control board 78, which is a subordinate control device of the sub control board 70, shifts to the normal processing. Therefore, even if the power supply voltage DC becomes unstable when the power is turned on, the host controller shifts to normal processing later than the slave controller. For this reason, when a command is transmitted from the upper control device to the lower control device, the lower control device surely shifts to the normal processing.
[0050]
In the pachinko machine of this embodiment, the sub-control board 70 and the display control board 78 are not provided with a backup function, but the process interrupted by a power failure or the like is resumed under a predetermined condition. That is, if the information in the RAM 76 is normal when the power is turned on or when the power is restored, the sub-control board 70 resumes the interrupted process using the information. The display control board 78 also resumes the suspended processing using the information when the information in the RAM 84 is normal when the power is turned on or the power is restored and the sub-control board 70 resumes the suspended processing. . As a result, the continuation of the image (for example, symbol variation) interrupted by a power failure or the like is displayed on the symbol display 23.
Here, the display control board 78 needs to know whether or not the sub control board 70 restarts the interrupted process because subsequent processes differ depending on whether or not the sub control board 70 restarts the interrupted process. There is. Therefore, when the information stored in the RAM 76 is abnormal (when the interrupted process is not resumed), the sub control board 70 outputs a clear signal (1 bit status signal) to the display control board 78. Further, the clear signal output from the sub control board 70 needs to be turned off after the display control board 78 starts the steady process. For this reason, the display control board 78 outputs an operating signal to the sub-control board 70 when shifting to the steady process. Hereinafter, the relationship between the output timing of the clear signal output from the sub control board 70 and the in-operation signal output from the display control board 78 will be described.
[0051]
FIG. 13 is a timing chart showing the output timing of the clear signal output from the sub-control board 70 and the operating signal output from the display control board 78. In FIG. 13, the time from when the power of the sub control board 70 is reset ((1) in FIG. 13) to when the power of the display control board 78 is reset ((2) in FIG. 13) is represented by t4. The case where the power reset time of the display control board 78 is delayed from the power reset time of the sub control board 70 due to variations or the like is shown.
As described above, the sub control board 70 immediately determines whether the RAM 76 is abnormal when the power is reset, and turns the clear signal ON or OFF. For this reason, as shown in FIG. 13, the clear signal output from the sub-control board 70 is turned ON or OFF substantially simultaneously with the timing of resetting the power supply (timing (1)). That is, the clear signal is turned OFF when the RAM 76 is normal, and the clear signal is turned ON when the RAM 76 is abnormal. When the clear signal is turned ON or OFF, the sub-control board 70 performs the standby process twice using the standby time counter. Therefore, the timing at which the sub-control board 70 shifts to the normal processing is the timing (4) when the times t1 and t2 have elapsed since the power supply was reset.
[0052]
On the other hand, the display control board 78 is reset when the time t4 has elapsed since the sub control board 70 was reset (timing (2)), and then waits for the time t3 to start normal processing (▲ 3 ▼ timing).
Here, the time t4 is an error caused by variations in the reset IC and the like, and 0 to 180 ms is assumed in this embodiment. Therefore, even when the power reset of the display control board 78 is delayed the most (t4 = 180 ms), the timing at which the display control board 78 starts the normal process is 380 ms after the sub control board 70 is reset. For this reason, the display control board 78 shifts to the normal process at a timing earlier than the timing at which the sub control board 70 shifts to the normal process.
[0053]
When the display control board 78 shifts to the normal processing, first, the state of the clear signal from the sub control board 70 is confirmed (step S79 in FIG. 10), and it is determined whether or not the information in the RAM 84 is cleared. Since the sub control board 70 turns the clear signal ON or OFF immediately after resetting the power supply, the clear signal from the sub control board 70 is sent before the timing when the display control board 78 confirms the state of the clear signal (timing (3)). Processing to turn on or off is performed.
Further, when the display control board 78 shifts to normal processing and repeats steady processing, a watchdog clear signal (one pulse) is output every cycle. When the watchdog clear signal is output, an operating signal is output to the sub-control board 70 in conjunction with the watchdog clear signal. That is, while the watchdog clear signal is output by two pulses, the operating signal is output by only one pulse.
When the sub-control board 70 shifts to the normal processing, the operating signal output from the display control board 78 is sampled at a predetermined time interval (2 ms), and it is confirmed whether or not the operating signal is input for one pulse. To do. Then, when it is confirmed that the in-operation signal is input for one pulse, the clear signal is switched from ON to OFF.
[0054]
As is apparent from the above description, in the pachinko machine of this embodiment, by providing standby time for each control board 52, 62, 70, 78, each control board 52, 62, 70, 78 can start normal processing. For this reason, even if the power supply voltage is disturbed, the pachinko machine can be started up normally.
Further, the standby time of each control board 52, 62, 70, 78 can be easily changed by the set value set in the standby time counter of each control board 52, 62, 70, 78. Therefore, by changing the set values of the control boards 52, 62, 70, 78, it is possible to adjust the standby time optimal for each gaming store.
[0055]
The preferred embodiments of the present invention have been described in detail above. However, the present invention is not limited to the above-described examples, and is implemented in various modifications and improvements based on the knowledge of those skilled in the art. be able to. For example, it can also be implemented in the form shown below.
[0056]
(1) In the above-described embodiment, the setting value of each control board cannot be changed. However, the present invention is not limited to such a form, and the setting value of the control device can be changed. For example, a dial type switch may be provided on the back side of the gaming machine and the set value may be changed by operating this switch. Moreover, the minimum value and the maximum value are set in advance as the set value, and may be freely changed within the range of the minimum value and the maximum value. When there are a plurality of control devices, the minimum value and the maximum value can be set differently for each control device.
Or you may make it equip a control apparatus with the program which changes a setting value automatically. For example, by monitoring the power failure signal, a time until the power supply voltage is stabilized after the power reset is measured, and a program for automatically changing the set value based on the measured time is incorporated in the control device in advance. In this case, the set value is decreased when the measured time is shorter than the set standby time, and the set value is increased when the measured time is longer than the set standby time. Therefore, the set value is automatically adjusted according to the measurement time, and is changed to an optimum standby time for each gaming store. The time measurement described above may be performed from the time when the set value is exceeded (that is, the first set value is set to the minimum value, and the set value increases according to the measurement result).
In the case where a means for changing the set value is provided, the information is stored at the time of a power failure, such as a storage medium that can retain information even when the power is shut off (for example, the RAM 68 of the main control board 62 of this embodiment). It is preferable to provide a RAM or a non-volatile storage medium (EEPROM or the like) and store the set value in the storage medium. According to such a configuration, even if the power is turned off due to the end of business at an amusement store or the like, the changed set value can be held until the next business start.
In the method of automatically changing the set value described above, when the time is measured from the time when the set value is exceeded, the time until the power supply voltage is stabilized does not exceed the set value ( That is, when time is not measured, a predetermined value may be subtracted from the set value. If the subtracted value is inappropriate (that is, if it is too large), the above-described increase processing (processing for adding the measured time to the set value) is performed at the time of subsequent power-on or the like. Will be optimized.
[0057]
(2) In the above-described embodiment, the standby time counter is initialized when only the main control board receives a power failure signal. However, the present invention is not limited to such a form, and other control boards may also be used. The standby time counter may be initialized when a power failure signal is received. According to such a configuration, the startup sequence of each control board can be strictly controlled.
[0058]
(3) The above-described embodiment is an example in which the present invention is applied to a pachinko machine. However, the present invention is not limited to a pachinko machine, but various game machines (for example, an arrange ball, a sparrow ball machine, a slot machine, etc.) Can be applied to. In particular, the present invention functions effectively in a gaming machine in which the power supply voltage of the power supply circuit is disturbed when the power supply is turned on.
[0059]
In addition, the technical elements described in the present specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology illustrated in the present specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.
[Brief description of the drawings]
FIG. 1 is a front view of a pachinko machine according to the present embodiment.
FIG. 2 is a block diagram showing a configuration of a control system of the pachinko machine shown in FIG.
FIG. 3 is a flowchart showing processing at the time of resetting the power supply of the main control board.
FIG. 4 is a flowchart showing timer interrupt processing of the main control board.
FIG. 5 is a flowchart showing processing at the time of power resetting of the payout control board
FIG. 6 is a flowchart showing a timer interrupt process of the payout control board.
FIG. 7 is a flowchart showing processing at the time of power reset of the sub control board.
FIG. 8 is a flowchart showing timer interrupt processing of the sub-control board.
FIG. 9 is a flowchart showing power failure signal interrupt processing of the sub control board.
FIG. 10 is a flowchart showing processing at the time of power reset of the display control board.
FIG. 11 is a flowchart showing steady processing of a display control board.
FIG. 12 shows the waveform of the AC power supplied to the gaming machine at power-on, the voltage waveform of the + 34V power supply voltage, the waveform of the power failure signal output from the power failure detection circuit, and the normal processing start timing of each control board. Timing chart shown
FIG. 13 is a timing chart showing output timings of a clear signal output from the sub control board and an operating signal output from the display control board.
[Explanation of symbols]
14. Game board
15 .. Symbol display device
23 .. Symbol display
25. Start prize opening
26 .. Grand prize opening
50 ... Power supply board
52 .. Dispensing control board
54 .. Power failure detection circuit
62 .. Main control board
70 .. Sub control board
78 .. Display control board

Claims (1)

A power supply circuit connected to an external power supply, a control device that operates with power supplied from the power supply circuit, and a power failure signal is output to the control device when the power supply voltage from the power supply circuit falls below a first preset voltage. A power failure detection circuit, wherein the control device is configured to start a power failure process upon receiving a power failure signal,
(1) Counting means for starting counting when the power supply voltage from the power supply circuit becomes equal to or higher than a second preset voltage set in advance by power-on or power-up, and the control device is reset ( 2) Means for starting normal processing when the numerical value counted by the counting means reaches the set value. (3) If a power failure signal is received while counting is being performed by the counting means, the power failure processing is not performed. A means for initializing the count value of the count means, and (4) a program for causing the control device to function as a means for executing a power failure process upon receipt of a power failure signal after starting normal processing,
The second set voltage is set to a voltage lower than the first set voltage,
A gaming machine, wherein a power failure process is not executed even if a power failure signal is received after the control device is reset by power-on or power-recovery while the control device counts.

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