JP2007229019A - Game machine and method of detecting fraudulent action in game machine, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect the replacement of a main board while suppressing increase in costs without adding a switch or the like. <P>SOLUTION: The number of times of setting change is transmitted from the main board to a sub board when power is interrupted, and it is stored as the number of times of the setting change into the sub board. The number of times of the setting change is transmitted from the main board to the sub board when the power is interrupted when the power is supplied (S13), it is compared with the stored number of times of the setting change when the power is interrupted, and when both do not match (NO in S26), the alarm of that effect is generated for prescribed time (S27-S29). Thus, whether or not the main board is replaced is detected when the power is supplied. When it is judged that the main board is detached, by reporting an error or stopping a game, fraudulent actions are suppressed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a gaming machine such as a slot machine, a fraud detection method in a gaming machine, and a program for causing a CPU to execute the method, and more particularly to a technique for preventing unauthorized replacement of a main board.

  Pachinko machines such as pachinko machines and slot machines that are installed and used in game halls such as pachinko parlors are given a certain value to game media such as pachinko balls and medals, and the game media acquired by playing games It can be exchanged for various prizes. The gaming machine is provided with various drive devices such as a lamp device and a sound generation device that are operated based on the supply of the game medium, and a control circuit device corresponding to control these drive devices inside the housing. Therefore, when the player plays a game, the game is filled with interest by appropriately operating them. Further, in recent years, a variable symbol display device such as a reel display device or a liquid crystal image display device that can display predetermined identification information (symbol) in a variable manner is built in and stopped after changing the identification information when a predetermined condition is satisfied. The mainstream is to operate the variable symbol display device so that it can be displayed. These devices are controlled by a control circuit device.

  A control circuit device disposed in a recent gaming machine is generally one in which a CPU (central processing unit) provided on a board performs electronic control according to a control program. The control program is stored as data in an IC chip mounted on a substrate such as a mask ROM (read only memory), and the CPU sequentially reads and executes the control program data from the IC chip according to the gaming state. Control is done by doing.

  The gaming machine installed in the game hall is managed so that the control program is not tampered with. The control circuit device (main board) is stored in a storage case, and the storage case is assembled to a predetermined member of the main body frame. Thus, consideration is given so that the ROM that stores the main board and the control program is not illegally replaced. Furthermore, a seal seal is stuck on the ROM so that it cannot be easily removed from the mounted substrate.

  However, even if the main board is housed in the case as described above or a seal seal is affixed to the ROM, unauthorized replacement of the main board and the ROM will never fail.

JP, 2004-358076, A This gazette aims at preventing illegal modification of a control program certainly, providing detection means (switch) which detects opening of a cover which stores a main board, and opening a cover It is disclosed that when it is detected, the fact is notified.

  In Patent Document 1, in order to detect and notify the opening of the cover, the cover is provided with a switch. Since it is necessary to open the cover before replacing the main board, according to Patent Document 1, although replacement of the main board can be reliably detected based on the output of the switch, the cost increases because the switch is provided. There was a problem to do.

  The present invention has been made in order to solve the above-mentioned problems, and it is not necessary to add parts such as a switch, and a gaming machine and a gaming machine that can detect and notify an unauthorized replacement of a main board while suppressing an increase in cost. An object of the present invention is to provide a method and a program for detecting fraudulent behavior in Japan.

The present invention relates to a game lottery process and a main board for changing a setting related to the lottery process, a sub board for receiving a command signal from the main board and performing an effect process, and the main board and the sub board are electrically connected. In a gaming machine provided with a wire harness to be connected
The main board stores a first storage unit that stores the number of setting changes indicating the number of times the setting change related to the lottery process is performed, and the first storage unit when the setting change related to the lottery process is performed And a first processing unit that reads the setting change number from the first storage unit and transmits it to the sub-board when the power is turned off and on.
The sub-board stores the setting change count received from the main board at the time of power-off in the second storage section as a setting change count at the time of power-off and is received from the main board at the time of power-on. A second processing unit that compares the number of setting changes with the number of setting changes at the time of power-off stored in the second storage unit and determines that an abnormality occurs when the two do not match. To do.

  It is preferable that the second processing unit generates an alarm and notifies an abnormality when the number of setting changes does not match the number of setting changes at power-off.

  The second processing unit stops the alarm when the alarm is continued longer than a predetermined time, and sets the number of setting changes received from the main board when the power is turned on as the setting change number of times when the power is turned off. You may make it memorize | store in the said 2nd memory | storage part. The alarm is not generated from the next time by updating the power-off setting change count of the second storage unit after notifying the alarm for a predetermined time (for example, 30 seconds or more). This is because it does not hinder regular maintenance work. In the case of fraud, it is difficult to withstand the alarm for a long time, so even if it is updated as described above, the effect of inhibiting fraud can be sufficiently maintained.

The present invention relates to a game lottery process and a main board for changing a setting related to the lottery process, a sub board for receiving a command signal from the main board and performing an effect process, and the main board and the sub board are electrically connected. A method of detecting fraud in a gaming machine having a wire harness that is connected to the machine,
In the main board, storing a setting change count indicating the number of times the setting change related to the lottery process is performed;
Increasing the stored number of setting changes when changing the setting related to the lottery process; and
Transmitting the setting change count from the main board to the sub-board when the power is turned off;
Transmitting the setting change count from the main board to the sub board when power is turned on;
In the sub-board, storing the setting change number received from the main board when the power is turned off as a setting change number when the power is turned off;
Comparing the number of setting changes received from the main board at power-on with the stored number of setting changes at power-off;
Determining that there is an abnormality when the number of setting changes does not match the number of setting changes at power-off.

The present invention is a program for causing a CPU (processing unit) to execute the above method.
The program according to the present invention is recorded on a recording medium, for example.
Examples of the medium include EPROM devices, flash memory devices, flexible disks, hard disks, magnetic tapes, magneto-optical disks, CDs (including CD-ROMs and Video-CDs), DVDs (DVD-Videos, DVD-ROMs, DVD-s). RAM), ROM cartridge, RAM memory cartridge with battery backup, flash memory cartridge, nonvolatile RAM cartridge, and the like.

  A medium is a medium in which information (mainly digital data, a program) is recorded by some physical means, and allows a processing device such as a computer or a dedicated processor to perform a predetermined function. is there.

  According to the present invention, the number of setting changes is transmitted from the main board to the sub board when the power is turned off, and this is stored as the number of setting changes when the power is turned off at the sub board. This is transmitted and compared with the stored power-off setting change count, and when both do not match, an alarm to that effect is generated. Thereby, it is possible to detect whether or not the main board has been replaced when the power is turned on. When it is determined that the main board has been replaced, an illegal action can be suppressed by notifying an error or stopping the game.

A gaming machine according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a front view of the slot machine with the door closed.

  In FIG. 1, reference numeral 100 denotes a slot machine. As shown in FIG. 1, the slot machine 100 is attached to a slot machine main body 120 and a front side of the slot machine main body 120 so as to be opened and closed by a hinge or the like. And a door 130. As shown in FIG. 1, a game display unit 131 is provided in the center of the front surface of the door 130, and a medal insertion slot 132 for a player to insert medals is provided at the lower right side of the game display unit 131. Further below the medal insertion slot 132, a reject button 133 is provided for forcibly discharging a clogged medal inserted from the medal insertion slot 132 to the outside of the slot machine 100.

  Further, a start switch 134 for starting a game is provided on the lower left side of the game display unit 131, and three stop switches 140 are provided corresponding to the three reels. At the center of the lower end of the door, a medal payout opening 135 is provided.

  FIG. 2 is a block diagram showing an electrical schematic structure of the slot machine 100. In this figure, the display about the power supply system is omitted. The slot machine 100 includes a main substrate 1 as a main processing device and a sub-substrate 2 that operates in response to a command from now on. Each of the main board 1 and the sub board 2 is housed inside the case so as to be inaccessible from the outside, and is sealed so that a trace remains when the boards are removed.

  The main board 1 is for performing an internal lottery in response to a player's operation, and processing such as reel rotation / stop and medal payout. The main board 1 includes a CPU that performs a control operation according to a preset program, a ROM that is a storage unit that stores the program, and a RAM that temporarily stores processing results and the like. In the ROM of the main board 1, for example, a plurality of lottery tables (not shown) respectively corresponding to the setting values 1 to 6 are stored, and the lottery tables corresponding to the setting values set by setting changes described later are used. A lottery process is performed.

  The sub-board 2 is for receiving a command signal from the main board 1 and notifying the result of the internal lottery and performing various effects. The sub-board 2 includes a CPU that performs a control operation according to a preset program corresponding to the command signal, a ROM that is a storage unit that stores the program, and a RAM that temporarily stores processing results and the like.

  The flow of commands is only one from the main board 1 to the sub board 2, and conversely, no command or the like is issued from the sub board 2 to the main board 1.

  In FIG. 2, the main board 1 has changed the setting related to the lottery process, and the first storage unit 1 a that stores the number of setting changes indicating the number of times the setting change related to the internal lottery process has been performed. In some cases, the number of setting changes stored in the first storage unit 1a is increased, and the number of setting changes is read from the first storage unit 1a and transmitted to the sub-board 2 when the power is turned off and on. And a processing unit 1b. Specifically, the first storage unit 1a is a semiconductor memory (RAM), and the first processing unit 1b is specifically a CPU. Since the main board 1 is originally provided with a CPU and a RAM for performing processing relating to games and lottery processing, the first storage unit 1a and the first processing unit 1b may be shared with the CPU and RAM.

  Similarly, the sub-board 2 stores the second storage unit 2a and the setting change count received from the main board 1 when the power is turned off in the second storage unit 2a as the setting change count when the power is turned off. A second processing unit 2b that compares the number of setting changes received from the substrate 1 with the number of setting changes at the time of power-off stored in the second storage unit 2a, and determines that there is an abnormality when the two do not match. Prepare. As in the case of the main board 1, the second storage unit 2a and the second processing unit 2b may be shared with the CPU and RAM on the sub board 2.

  The slot machine basically pays out medals when symbols are arranged, but whether or not symbols are arranged depends on the result of a lottery by an internal computer. Also, various prizes such as a big bonus (BB), regular bonus (RB), and small role follow the result of the lottery by the internal computer. The lottery process can be set within a predetermined range (the probability of winning is increased or decreased), and the setting operation is performed by the store in the hall where the slot machine is installed. A normal slot machine is preliminarily provided with a plurality of lottery tables (for example, six) having different lottery probabilities such as BB, RB, and small roles. In the slot machine lottery, one of the plurality of lottery tables is set, and the winning / losing determination by lottery is made based on the set lottery table. Changing a setting relating to which of a plurality of lottery tables is used is referred to as a setting change (setting change). The value stored in the first storage unit 1a is the number of times such setting has been changed. A specific procedure for changing the setting will be described later.

  The main board 1 includes a start switch 134, a stop switch 140, a reel drive unit 70, a reel position detection circuit 71, a hopper drive unit 80, a medal detection unit 82 for counting the number of medals paid out from the hopper 81, and a setting key. A switch 90 and a setting switch 91 are connected. A peripheral substrate (local substrate) such as a liquid crystal control substrate 200, a speaker substrate 201, and an LED substrate 202 for controlling the liquid crystal display device 62 is connected to the sub substrate 2. Hereinafter, these peripheral boards / devices excluding the start switch 134 and the stop switch 140 will be described.

  The reel driving unit 70 is a circuit that drives a stepping motor (not shown) that rotates and drives three reels (not shown) that can be seen from the game display unit 131. Each stepping motor is subjected to 1-2 phase excitation by the reel driving unit 70 and rotates once when a driving signal having a predetermined number of pulses is supplied.

  The reel position detection circuit 71 receives an output pulse signal from a photosensor (not shown) provided in the vicinity of the reel for detecting the rotation position of the reel, detects the rotation position of each of the three reels, and detects the detection A signal is output. A photosensor (not shown) generates a reset pulse by detecting a shielding plate provided on each reel each time the reel rotates once. This reset pulse is given to the CPU of the main board 1 via the reel position detection circuit 71. In the RAM of the main board 1, a count value corresponding to the rotation position within one rotation range is stored for each reel. When the CPU receives a reset pulse, the count value formed in the RAM is stored. Clear to “0”. By this clearing process, the deviation generated between the movement display of each symbol and the rotation of each stepping motor is eliminated every rotation.

  The hopper drive unit 80 is a circuit that drives a motor of a hopper 81 that stores medals and pays out the number of medals corresponding to the designated winning.

  The medal detection unit 82 is for counting the number of medals paid out from the hopper 81. The CPU of the main board 1 stops the driving by the hopper driving unit 80 when the medal count value actually paid out received from the medal detection unit 82 reaches the predetermined payout number data corresponding to the winning. Finish paying out. The hopper drive unit 80 and the medal detection unit 82 pay out a predetermined number of medals to the player based on a winning obtained as a result of the game.

  The setting key switch 90 is a switch for performing the setting change described above. The switch 90 is housed inside the housing and can be operated only by a hall attendant who has a key for opening the front door 130.

The liquid crystal control board 200 is a circuit for driving the liquid crystal display device 62 provided on the right side of the game display unit 131.
The speaker board 201 is a circuit for driving a loudspeaker (not shown).
The LED substrate 202 is a circuit for driving a display lamp and a back lamp (not shown).

  The liquid crystal display device 62, a speaker, a display lamp and the like (not shown) constitute an effect display device. This effect display device is for notifying a player of a prize or the like, or for teaching a user a specific small role during a certain game with some action during a so-called assist time (AT).

  The ROM of the main board 1 stores game processing procedures executed in the slot machine 100 as a sequence program, and stores a winning probability table, a symbol table, a winning symbol combination table, and the like. Has been. The winning probability table is divided so that random numbers extracted by a random number generation unit (not shown) are divided into respective winning modes, and random numbers extracted from a certain range of numerical values generated by the random number generating unit are assigned to each winning mode. The data to be partitioned into is stored. That is, the winning probability table has an area divided for each winning mode corresponding to the entire area of random numbers taken by a random number generator (not shown). For example, a range of 0 to a certain number is divided into a plurality, one division (area) is excluded, and the other division (area) is set as winning 1, winning 2,. The extracted random number data is compared with each winning probability area data segmented for each winning mode in all areas corresponding to the random number generated from the random number generator, and the winning mode to which the extracted random number data belongs Winning corresponding to is decided. For example, it is determined to which category (region) of the winning probability table the extracted random number value belongs, and if the category is, for example, a category of winning 1, it is determined as “winning 1”. Similarly, if the extracted random number value belongs to the category (area) of losing in the winning probability table, it is determined as “out”. For example, when the evaluation of the lottery process is out of place, the predetermined symbols are set not to be aligned (so-called kicking). (So-called pull-in). And if predetermined symbols are prepared, medals corresponding to winning symbols are paid out. Various winnings are generated under the probability according to the data setting of the winning probability table, and the symbol stop control is performed. For example, the operating hours of the day are not influenced by the skill of the player. The total medal payment rate is maintained almost constant.

  As described above, the slot machine has the sub board 2 in addition to the main board 1 and controls the effects such as sound, light, and image display. The main board 1 and the sub board 2 transmit data from the main board 1 to the sub board 2 through a communication line (wire harness) capable of performing only one-way communication. In the embodiment of the present invention, the number of setting changes in the main board 1 is sent to the sub-board 2 using this communication path, and it is determined whether the main board 1 has been replaced based on the number of setting changes.

  The first storage unit 1a of the main board 1 is a non-volatile memory or a volatile memory, and has a power source backup function (including a rechargeable battery). That is, the written contents can be held even during the power-off of the slot machine. The same applies to the second storage unit 2a of the sub-board 2.

  In the embodiment of the present invention, the number of setting changes from the initial operation is recorded in the first storage unit 1a on the main board 1. For example, the cumulative number of setting changes is recorded in the first storage unit 1a.

  When the power is cut off, the current setting change count is transmitted from the main board 1 to the sub board 2. In the sub-board 2, after receiving the setting change count and recording it in the second storage unit 2a, each element of the sub-board 2 including the second processing unit 2b shifts to the sleep state.

  At the next start-up, the setting change count is transmitted again from the main board 1 to the sub-board 2. In the sub-board 2, the received number of setting changes is compared with the number of setting changes recorded when the power is turned off. If a different value is detected, an alarm is generated using light or sound.

  If the main board 1 is exchanged illegally, the number of setting changes is likely to be different. This is because the setting change is not performed uniformly, and whether or not the setting change is performed, and even when it is performed, the timing varies depending on the slot machine.

  In the embodiment of the present invention, the setting change count is used as a secret password. The number of setting changes is unique for each slot machine, and it is difficult to know from the outside. For this reason, the number of setting changes is appropriate as a secret password. In a normal use state, the main board 1 and the sub board 2 have the same number of setting changes, and the consistency between the two is maintained, but when the main board 1 is replaced, The number of setting changes stored in the sub-board 2 becomes inconsistent. By detecting this and reporting an error, it can be easily known that the main board 1 has been replaced. In addition, the main board 1 may be replaced for repair or the like, but when a predetermined condition is satisfied (a condition that cannot be tolerated by a fraudulent person who keeps reporting errors for a long time), the error is reset. By adjusting the number of times of setting change of the sub-board 2 to that of the main board 1, normal use can be prevented.

FIG. 3 is a flowchart showing the overall processing of the slot machine according to the embodiment of the invention.
S1: Turn on the power switch of the slot machine. When changing the setting, the power switch of the slot machine is turned on while the setting key switch 90 is turned on. The setting key switch 90 is provided on a panel of a power source (not shown) (provided inside the door). Normally off. When the setting key switch is on, the current setting value is displayed on a display unit (not shown) (for example, provided below the symbol display window 13).

S2: If the setting key switch is on (YES in S2) when the power switch is on, the setting mode is entered, and the processes of S3 and S4 are performed. If it is off (NO in S2), the process proceeds to S5 and enters a normal gaming state.

S3: A setting change process is performed. Details of the setting change processing will be described later (see FIG. 4).

S4: After the setting change process, the number of setting changes in the first storage unit 1a is updated. For example, when the setting change count stored in the first storage unit 1a is M, the new setting change count is M + 1. In this case, M means the cumulative number of setting changes. The secret password is not limited to +1, but may be +2, +3,. What is necessary is just to determine in advance how the setting change count is calculated by the program of the main board 1 and the program of the sub board 2 so that both can be matched. Further, it may be a value that is uniquely calculated at the time of setting change based on a predetermined function from the initial value, and such value is also included in the number of setting changes according to the present invention. When the setting is changed, the number of times is also notified to the sub-board 2, so the number of setting changes in the second storage unit 2 a of the sub-board 2 is updated.

S5: A normal game process is performed.

Next, the internal setting process will be described with reference to FIG.
S31: Select an internal setting. The internal setting can be set, for example, in 1 to 6 stages. When the setting switch 91 is operated, the displayed set value changes.
S32: The start switch 134 is operated.
S33: The set value is determined by the operation of S32.
S34: The setting key switch 90 is turned off. Then, the set value is stored in the main board 1, and the set value display on the display disappears.

  Next, processing of the fraud detection method according to the embodiment of the invention will be described with reference to FIGS.

  FIG. 5 shows a processing flowchart when the power switch is turned off, and FIG. 6 shows a processing flowchart when the power switch is turned on. FIG. 7A shows a timing chart when the power switch is turned off, and FIG. 7B shows a timing chart when the power switch is turned on.

  In FIG. 7A, when the power switch is on, the power supply voltage is a specified value (period P1). When the power switch is turned off from on (time T1), the power supply voltage supplied to the sub-board 2 or the like does not drop immediately, and the power supply voltage becomes zero after a while after the power switch is turned off ( Time T2). During this period (period P2), the CPU or the like of the sub-board 2 can perform a predetermined process. Immediately after the power switch is turned from on to off (time T1), the power-off signal indicating that effect becomes effective, so that the CPU or the like can execute processing at the time of power-off upon the power-off signal. . Specifically, the process of FIG. 5 is performed in the period P2.

  That is, the first processing unit 1b of the main board 1 reads the number of setting changes from the first storage unit 1a, and sends the number of setting changes to the sub board 2 (S11). Thereafter, each function of the main board 1 including the first processing unit 1b enters a sleep mode (a state for automatically suppressing power consumption when not in use, a program is in a halt state) (S12). The sleep mode is maintained during the power-off period P3 in FIG. Even if the power is turned off, the contents of the first storage unit 1a are retained, and the written number of setting changes is not lost.

  When the process S11 by the main board 1 is executed, the sub board 2 receives the number of setting changes (S21). The received setting change count is stored in the second storage unit 2a (S22). Since the number of setting changes is information when the power is turned off, the second processing unit 2b stores this in the second storage unit 2a as the number of setting changes when the power is turned off. As described above, since the setting change is performed in the power-on state, unless the main board 1 is replaced, the number of setting changes between the main board 1 and the sub board 2 before the next power-on is changed. Absent. Thereafter, each function of the sub-board 2 including the second processing unit 2b enters the sleep mode (S23). The sleep mode is maintained during the power-off period P3 in FIG. Even if the power is turned off, the contents of the second storage unit 2a are retained, and the written number of setting changes is not lost.

  Next, as shown in FIG. 7B, when the power switch is turned on (time T3), the power supply voltage rises and quickly reaches the specified value. At that time, a reset signal is usually generated, and the CPU or the like starts an initial operation in the subsequent period P4. 6 is performed as one of the initial operations.

  That is, the first processing unit 1b of the main board 1 reads the number of setting changes from the first storage unit 1a, and sends the number of setting changes to the sub board 2 (S13).

  When the process S13 by the main board 1 is executed, the sub board 2 receives the number of setting changes (S24). The second processing unit 2b reads the number of setting changes at power-off from the second storage unit 2a (S25). Then, the received setting change count is compared with the read power change setting change count (S26). If they match, there is no problem, but if they do not match (NO in S26), it is considered that the main board 1 has been replaced, so an alarm is generated and a notification is given (S27). For example, an error signal is generated and sent to a hall computer (not shown) that manages the slot machine, and a signal is sent to the speaker board 201 to cause the speaker to sound and give an acoustic alarm. Further, a signal is sent to the liquid crystal display substrate 200 to display an error occurrence message on the liquid crystal display device 62, and a signal is sent to the LED substrate 202 to blink the arch lamp 136 and the like. Such alarms are so prominent that the hall attendants will immediately know.

  The alarm generation / notification in S27 continues until a predetermined time elapses (S28). Thereafter, the alarm is stopped, and the setting change count at power-off of the second storage unit 2a is replaced with the received setting change count (S29). After detecting the removal of the main board 1, a warning is generated for a certain time. As long as the process of S29 is not executed, the alarm continues to be generated even if the power of the slot machine is turned off again and returned. By the processing of S27 to S29, the contents of the second storage unit 2a cannot be updated by powering off the slot machine. This makes it easier to detect fraud.

Note that after the alarm is generated in S27, the alarm may not be canceled unless a predetermined operation such as an operation of a reset switch (not shown) is performed separately. The reset switch is provided inside the locked slot machine housing, and can be operated only by hall personnel.
In S27, an alarm may be generated and the game may not be executed, and the game may not be executed unless a predetermined time elapses or a predetermined operation such as a reset switch operation is performed. .

  According to the embodiment of the present invention, the number of setting changes is transmitted from the main board to the sub board when the power is turned off, and this is stored as the number of setting changes when the power is turned off in the sub board. The number of setting changes is transmitted to the sub-board, and this is compared with the stored number of setting changes at power-off, and if both do not match, an alarm to that effect is generated. Thereby, it is possible to detect whether or not the main board has been replaced when the power is turned on. When it is determined that the main board has been replaced, an illegal action can be suppressed by notifying an error or stopping the game.

  Settings are changed many times, and the number of times is usually not recorded. The number of setting changes is unique to each slot machine, and it is difficult to know from the outside. Therefore, the setting change frequency can be used as a secret password that no one knows, and the security of the apparatus / method according to the embodiment of the invention using this is very high.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the invention described in the claims, and these are also included in the scope of the present invention. Needless to say.
For example, in the embodiment of the present invention, the number of setting changes is transmitted from the main board 1 to the sub board 2 when the power is cut off. However, when the number of setting changes is updated (S4 in FIG. 3), from the main board 1 to the sub board 2 The setting change count may be transmitted, and the setting change count at power-off may be stored in the second storage unit 2a of the sub-board 2.
Also, the number of setting changes is transmitted from the main board 1 to the sub-board 2 both when the power is turned off and when the setting change count is updated (S4 in FIG. 3), and the setting at the time of power-off is set to the second storage unit 2a of the sub-board 2. The number of changes may be stored. By increasing the opportunity to transmit the number of setting changes, the number of setting changes can be reliably stored in the second storage unit 2a of the sub-board 2. Even if the setting change number transmitted when the power is turned off cannot be correctly received by the sub-board 2, there is no problem as long as it can be correctly received when the setting change number is updated.

It is a front view of a gaming machine (slot machine). 1 is a block diagram of a gaming machine according to an embodiment of the invention. It is a process flowchart at the time of power activation of the gaming machine according to the embodiment of the present invention. It is an internal setting process flowchart which concerns on embodiment of invention. It is a fraud determination process flowchart which concerns on embodiment of invention (at the time of a power failure). It is a fraud determination process flowchart which concerns on embodiment of this invention (at the time of power activation). It is a timing chart for demonstrating operation | movement of embodiment of invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main board | substrate 1a 1st memory | storage part 1b 1st process part 2 Sub board | substrate 2a 2nd memory | storage part 2b 2nd process part 62 Liquid crystal display device 70 Reel drive part 71 Reel position detection circuit 80 Hopper drive part 81 Hopper 82 Medal detection part 90 Setting key switch 91 Setting switch 100 Slot machine 120 Slot machine main body 130 Door 131 Game display section 132 Medal insertion slot 133 Reject button 134 Start switch 135 Discharge port 136 Arch lamp 140 Stop switch 200 LCD control board 201 Speaker board 202 LED board

Claims (6)

A main board that performs a lottery process related to a game and a setting change related to the lottery process, a sub board that receives a command signal from the main board and performs an effect process, and electrically connects the main board and the sub board In a gaming machine comprising a wire harness,
The main board stores a first storage unit that stores the number of setting changes indicating the number of times the setting change related to the lottery process is performed, and the first storage unit when the setting change related to the lottery process is performed And a first processing unit that reads the setting change number from the first storage unit and transmits it to the sub-board when the power is turned off and on.
The sub-board stores the setting change count received from the main board at the time of power-off in the second storage section as a setting change count at the time of power-off and is received from the main board at the time of power-on. A second processing unit that compares the number of setting changes with the number of setting changes at the time of power-off stored in the second storage unit and determines that an abnormality occurs when the two do not match. To play.   2. The gaming machine according to claim 1, wherein when the number of setting changes does not match the number of setting changes when the power is turned off, the second processing unit issues an alarm to notify the abnormality.   The second processing unit stops the alarm when the alarm is continued longer than a predetermined time, and sets the number of setting changes received from the main board when the power is turned on as the setting change number of times when the power is turned off. The gaming machine according to claim 2, wherein the gaming machine is stored in the second storage unit. A main board that performs a lottery process related to a game and a setting change related to the lottery process, a sub board that receives a command signal from the main board and performs an effect process, and electrically connects the main board and the sub board A method for detecting fraud in a gaming machine comprising a wire harness,
In the main board, storing a setting change count indicating the number of times the setting change related to the lottery process is performed;
Increasing the stored number of setting changes when changing the setting related to the lottery process; and
Transmitting the setting change count from the main board to the sub-board when the power is turned off;
Transmitting the setting change count from the main board to the sub board when power is turned on;
In the sub-board, storing the setting change number received from the main board when the power is turned off as a setting change number when the power is turned off;
Comparing the number of setting changes received from the main board at power-on with the stored number of setting changes at power-off;
And a step of determining an abnormality when the number of setting changes does not match the number of setting changes at power-off. A main board that performs a lottery process related to a game and a setting change related to the lottery process, a sub board that receives a command signal from the main board and performs an effect process, and electrically connects the main board and the sub board In a gaming machine including a wire harness, a step of storing a setting change count indicating a number of times the setting change related to the lottery process is performed in a first processing unit provided on the main board;
Increasing the stored number of setting changes when changing the setting related to the lottery process; and
Transmitting the setting change count from the main board to the sub-board when the power is turned off;
Transmitting the setting change count from the main board to the sub-board when power is turned on. A main board that performs a lottery process related to a game and a setting change related to the lottery process, a sub board that receives a command signal from the main board and performs an effect process, and electrically connects the main board and the sub board In a gaming machine including a wire harness, the second processing unit provided on the sub-board,
Storing the number of setting changes indicating the number of times the setting change related to the lottery process received from the main board at the time of power-off as a power-off setting change number;
Comparing the number of setting changes received from the main board at power-on with the stored number of setting changes at power-off;
And a step of determining an abnormality when the number of setting changes does not match the number of setting changes at power-off.

Images