JP6031180B1 - Game machine - Google Patents

Abstract

To provide a gaming machine capable of preventing an illegal profit from being generated when an illegal bypass route is constructed. A data relay board that is disposed on a communication path between a first control board and a second control board and stops transmission of communication data to the second control board when a communication stop condition is satisfied. The data relay board 3 converts the communication data transmitted from the first control board 1 into another communication data having a data format different from that of the communication data according to an encryption rule, Transmit to the second control board 2. According to such a configuration, when a bypass path for directly transmitting communication data from the first control board 1 to the second control board 2 is illegally constructed, the communication data via the bypass path and the data relay board 3 are Since the data format differs depending on the communication data, the fraudulent act can be prevented. [Selection] Figure 3

Description

  The present invention relates to technology for preventing fraud against gaming machines.

  A gaming machine such as a slot machine or a pachinko machine has a plurality of control boards in order to disperse the control burden, and transmits control data from one control board to another control board via a signal line. The control board that has received the control data performs predetermined control. Here, the control board that receives the control data is generally provided with a function of directly or indirectly controlling and executing the operation experienced by the player in accordance with the control data. Some perform the control involved in the. In order to obtain illegal profits by altering the programs and data stored in the storage device ROM or replacing the ROM for the control board on the receiving side involved in such player's profits There was a problem with cheating.

  As a configuration that can prevent the above-described fraud, for example, the configuration of Patent Document 1 has been proposed. The configuration of Patent Document 1 includes a fraud prevention board that relays communication data on a communication path between a transmission side control board and a reception side control board, and the fraud prevention board is provided on a reception side control board. When tampering or replacement is detected, data communication from the transmission-side control board to the reception-side control board is stopped. According to this configuration, if the ROM of the control board on the receiving side is altered or replaced, the control data transmitted from the control board on the transmitting side cannot be received by the control board on the receiving side. It is possible to prevent the acquisition of illegal profits caused by.

  A specific example in which the configuration of the above-described Patent Document 1 is applied to a slot machine will be described. The gate device stops transmitting control data from the main control board to the sub control board when an illegal act of tampering with or replacing the ROM of the sub control board is performed. To do. According to this configuration, it is possible to prevent an act of misusing the AT (assist time) function to obtain an illegal profit by altering or replacing the ROM of the sub control board.

JP 2005-287911 A

  By the way, in the conventional configuration of Patent Document 1, if the fraud is only alteration or replacement of the ROM of the control board on the receiving side, it can be prevented by stopping transmission by the fraud prevention board, but in addition to alteration or replacement of the ROM. If a bypass path capable of direct data communication is established between the transmission-side control board and the reception-side control board, even if transmission is stopped by the fraud prevention board, control data is transmitted via the bypass path. Therefore, it is not possible to prevent the generation of illegal profits. Therefore, even when such a bypass route is constructed, a configuration that can prevent the generation of unauthorized profits has been demanded.

  An object of the present invention is to provide a gaming machine capable of preventing an illegal profit from being generated when an illegal bypass route is constructed.

The present invention comprises data generation means for generating communication data including control data, a first control board for transmitting communication data generated by the data generation means, and a communication path for transmitting the communication data. In the gaming machine comprising the second control board connected to the first control board via the first control board and performing predetermined control based on the control data of the communication data transmitted from the first control board. The communication data provided in the path is relayed from the first control board to the second control board, and the communication data to the second control board is established when a predetermined communication stop condition is satisfied. A data relay board for stopping data transmission, wherein the data relay board transmits the communication data transmitted from the first control board in accordance with a predetermined encryption rule. Data conversion means for converting the communication data generated by the process into another communication data having a different data format, and transmitting the other communication data converted by the data conversion means to the second control board And the second control board is provided with means for decoding another communication data converted by the data conversion means.
In the present invention, as such a configuration, the first control board performs a process of encrypting original communication data in accordance with a predetermined first encryption rule by the data generation means, and the encrypted communication The data relay board transmits data to the data relay board, and the data relay board uses the data conversion means to decode the communication data sent from the first control board and the decoded communication data. Is encrypted according to a predetermined second encryption rule, which is different from the first encryption rule, and the encrypted communication data is transmitted to the second control board. The second control board proposes a gaming machine characterized in that it performs a second decoding process for decoding communication data sent from a data relay board. In addition, the first control board transmits data for original communication to a data relay board by a data generation means, and the data relay board communicates from the first control board by a data conversion means. Processing is performed in accordance with a predetermined encryption rule, and the encrypted communication data is transmitted to the second control board. The second control board is a data relay board. A gaming machine is proposed which performs a decryption process for decrypting communication data sent from a mobile phone.

  Here, as the data conversion means, the communication data before conversion transmitted from the first control board may be converted into other communication data so that all of the data is different from that before conversion. Alternatively, the data may be converted into another communication data so that only a part is different from that before the conversion. In addition, as a communication stop condition, it is preferable to detect fraud with respect to the second control board, but in addition, fraud detection related to communication originating from the first control board, detection of illegal radio waves, unauthorized opening of the front door, etc. It can also be set to detect various frauds.

  In such a configuration, the communication data transmitted from the first control board to the second control board is converted into a different data format by the data relay board, and thus transmitted from the first control board. The communication data and the communication data received by the second control board have different data formats. Therefore, if a bypass path that allows direct communication between the first control board and the second control board is illegally constructed, the second control board receives communication data that is different from the data format that should originally be received. For this reason, the second control board cannot cope with the decoding means and cannot acquire the control data. As described above, according to this configuration, even if an illegal act is attempted to acquire an illegal profit by the configuration of the bypass path, it is possible to prevent the generation of the profit because the control data of the communication data cannot be acquired. . That is, in this configuration, in the conventional configuration of Patent Document 1 described above, a bypass path that allows direct communication between the transmission-side control board (first control board) and the reception-side control board (second control board) is constructed. Can solve the problem of obtaining illegal profits.

It is a block diagram which shows the control circuit of the slot machine of a present Example. It is a chart which shows the content of the data for communication transmitted from the main control board 1 to the sub control board 2. 2 is a block diagram showing a control circuit related to communication between a main control board 1, a sub control board 2 and a data relay board 3. FIG.

An embodiment in which the present invention is applied to a slot machine will be described according to the following examples.
In the present embodiment, the first control board according to the present invention corresponds to the main control board 1, and the second control board according to the present invention corresponds to the sub control board 2. The data generation means according to the present invention is constituted by the main microcomputer 30 of the main control board 1. The data conversion means according to the present invention is constituted by the relay microcomputer 50 of the data relay board 3. The means for decoding the communication data according to the present invention is constituted by the sub microcomputer 40 of the sub control board 2.

FIG. 1 is a block diagram showing a control circuit of the slot machine of this embodiment.
The slot machine includes a main control board 1, a sub control board 2, and a data relay board 3. The main control board 1 and the data relay board 3 are connected by a signal line 16a for transmitting data, and the data relay board 3 and the sub control board 2 are connected by a signal line 16b. In this embodiment, communication data is transmitted in one direction from the main control board 1 to the sub control board 2 via the signal line 16a, the data relay board 3, and the signal line 16b. Here, the signal line 16a is connected to the transmission circuit 33 provided on the main control board 1 and the reception circuit 51a provided on the data relay board 3, respectively, and the signal line 16b is connected to the data relay board. 3 is connected to a transmission circuit 51b disposed on the sub-control board 2 and a reception circuit 41 disposed on the sub-control board 2. In the present embodiment, the signal path 16a and the signal line 16b via the data relay board 3 constitute a communication path according to the present invention.

  Furthermore, in this embodiment, the sub control board 2 and the data relay board 3 are connected by signal lines 17a and 17b, and bidirectional communication can be performed by these signal lines 17a and 17b. The signal line 17a is connected to a transmission circuit 61a disposed on the data relay board 3 and a reception circuit 46a disposed on the sub-control board 2, and the signal line 17b is arranged on the sub-control board 2. The transmission circuit 46b provided and the reception circuit 61b disposed on the data relay board 3 are respectively connected. The two-way communication path using the signal lines 17a and 17b is provided independently of the one-way communication path using the signal line 16b.

  The main control board 1 includes a main microcomputer 30 that performs control related to the progress of the game, and a transmission circuit 33. The main microcomputer 30 includes a CPU, a RAM, a ROM, and the like, and receives signals from a start switch, a stop switch, a bet switch, a max bet switch, and a settlement switch. The main microcomputer 30 outputs signals to a motor for driving the reel, a motor for driving the hopper unit, and the like. The main microcomputer 30 causes the CPU to generate an interrupt at a predetermined interval (1.8 milliseconds). The CPU executes a control process related to the progress of the game every time this interrupt occurs. For example, when the start switch is operated by the player, the main microcomputer 30 displays the symbols arranged on the reel in a variable manner by rotating the reel with a motor. When the stop switch is operated by the player during the symbol variation display, the main microcomputer 30 stops the reel rotation associated with the stop switch and stops the variation display of the reel. .

  The ROM of the main microcomputer 30 stores a program for generating communication data to be transmitted, fixed data related to generation of communication data, and the like. In the RAM of the main microcomputer 30, a storage area is secured in advance as a transmission buffer 32 (see FIG. 3) for temporarily storing communication data to be transmitted. When the CPU of the main microcomputer 30 generates communication data when the interrupt occurs, the CPU 30 stores the generated communication data in the transmission buffer 32. The transmission buffer 32 can store a plurality of communication data. The main microcomputer 30 executes a process for transmitting the communication data stored in the transmission buffer 32 each time the interrupt occurs. Note that communication data transmitted from the main control board 1 to the sub control board 2 via the data relay board 3 is sent in only one direction, and is directed from the sub control board 2 or the data relay board 3 to the main control board 1. No communication data is sent.

  The data relay board 3 relays communication data sent from the main control board 1 to the sub control board 2 between the main control board 1 and the sub control board 2. The receiving circuit 51a is connected to the signal line 16a, and the transmitting circuit 51b is connected to the signal line 16b. The relay microcomputer 50 includes a CPU, a RAM, a ROM, and the like. The ROM of the relay microcomputer 50 stores a program for converting communication data transmitted from the main control board 1, fixed data related to this conversion, and the like. The RAM of the relay microcomputer 50 temporarily stores a reception buffer 52a for receiving communication data transmitted from the main control board 1 and communication data to be transmitted to the sub control board 2. A transmission buffer 52b is provided. The reception circuit 51a is connected to the transmission circuit 33 of the main control board 1 via the signal line 16a, and the communication data transmitted from the main control board 1 is transferred to the reception buffer 52a via the reception circuit 51a. Is done. The CPU of the relay microcomputer 50 generates an interrupt at a predetermined interval (1.2 milliseconds), and acquires the communication data stored in the reception buffer 52a every time this interrupt occurs. Further, the CPU of the relay microcomputer 50 executes processing for converting the acquired communication data into another communication data having a different data format, and stores the converted other communication data in the transmission buffer 52b. Then, processing for transmitting the communication data is executed. The process of converting communication data by the relay microcomputer 50 is a main part of the present invention, and details thereof will be described later.

  Further, the data relay board 3 includes a transmission circuit 61a and a reception circuit 61b for bidirectional communication with the sub-control board 2. The transmission circuit 61a and the reception circuit 61b are for transmitting and receiving data for fraud detection processing to be described later. The ROM of the relay microcomputer 50 also stores a fraud detection program and fixed data related to this fraud detection. The RAM of the relay microcomputer 50 receives the fraud detection transmission buffer (not shown) for temporarily storing the data to be transmitted from the transmission circuit 61a and the reception circuit 61b. A fraud detection reception buffer (not shown) for temporarily storing data is provided separately from the reception buffer 52a and the transmission buffer 52b used for the communication data described above. The relay microcomputer 50 transmits and receives fraud detection data using the transmission circuit 61a and the reception circuit 61b by executing the fraud detection process. The details of this fraud detection process will be described later.

  The sub-control board 2 includes a sub-microcomputer 40 that controls effects relating to games, and a receiving circuit 41 to which the signal line 16b is connected. The sub microcomputer 40 is composed of a CPU, RAM, ROM and the like. The ROM of the sub microcomputer 40 stores fixed data relating to a wide variety of effect patterns. The RAM of the sub microcomputer 40 is provided with a reception buffer 42 (see FIG. 3) for temporarily storing received communication data. The reception circuit 41 is connected to the transmission circuit 51b of the data relay board 3 via the signal line 16b, and the communication data transmitted from the data relay board 3 is transferred to the reception buffer 42 via the reception circuit 41. Is done. The CPU of the sub microcomputer 40 generates an interrupt at a predetermined interval (1.2 milliseconds), and acquires the communication data stored in the reception buffer 42 every time this interrupt occurs. Then, the CPU of the sub microcomputer 40 performs control according to the control data indicated by the acquired communication data. Specifically, sound is output from a speaker via an audio control circuit (not shown), or an image is output to a liquid crystal display via an image control circuit (not shown).

  Further, the sub-control board 2 includes a receiving circuit 46a and a transmitting circuit 46b for transmitting / receiving data for fraud detection processing, and bidirectional communication with the data relay board 3 is performed by the receiving circuit 46a and the transmitting circuit 46b. . The signal line 17a is connected to the reception circuit 46a, and data for fraud detection processing is input from the transmission circuit 61a of the data relay board 3 through the signal line 17a. The transmission circuit 46b is connected to the signal line 17b, and outputs fraud detection data to the reception circuit 61b of the data relay board 3 via the signal line 17b. Further, in the RAM of the sub microcomputer 40, a fraud detection receiving buffer (not shown) for temporarily storing fraud detection processing data transmitted from the data relay board 3, and data A fraud detection transmission buffer (not shown) for temporarily storing fraud detection processing data to be transmitted to the relay board 3 is provided separately from the reception buffer 42 used for the communication data described above. ing.

FIG. 2A shows a data format of original data (hereinafter referred to as original communication data) of communication data generated by the main control board 1. In this embodiment, as will be described later, communication data obtained by encrypting original communication data is used for communication from the main control board 1 to the sub control board 2.
As shown in FIG. 2A, the original communication data is 7-byte data in which 7 pieces of 1-byte configuration data form one set. That is, the original communication data is meaningful by a plurality of configuration data. The configuration data includes base data for normally performing communication and control data indicating control information issued from the main control board 1. Specifically, as shown in FIG. 2B, the head configuration data “ST” is base data and stores a fixed value indicating the head of the original communication data. The second configuration data “LN” is the base data and stores the length (number of bytes) of the original communication data. The third to fifth configuration data “DATA1”, “DATA2”, and “DATA3” are control data, and store values corresponding to the gaming state and the type and content of the event. The sixth component data “CH” stores a checksum that is an error detection code. Specifically, the configuration data “CH” stores the lower 1 byte when “DATA1”, “DATA2”, and “DATA3” are added. The seventh configuration data “EN” is the base data and stores a fixed value indicating the end of the original communication data.

  FIG. 2C shows a specific example of the contents of the third to fifth control data “DATA1”, “DATA2”, and “DATA3”. As shown in FIG. 2C, the third control data “DATA1” stores values indicating a gaming state such as an internal winning state or a special state and various error states. The fourth control data “DATA2” stores a value indicating the type of event, and the value stored in the control data “DATA3” is configured to indicate the specific contents of the event. For example, the event of “internal winning” is transmitted when the role lottery process is executed, and the result information of the role lottery is specified by the value of “DATA3”. Further, the event of “stop right reel” is transmitted when the right reel stops, and the stop position of the right reel is specified by the value of “DATA3”. The same applies to the “middle reel” and “left reel” events. The “winning determination” event is transmitted when all reels are stopped, and the value of “DATA3” specifies the presence / absence of a winning and the type of winning.

  FIG. 3 is a block diagram showing a control circuit related to communication among the main control board 1, the data relay board 3, and the sub control board 2. As described above, the main control board 1 and the data relay board 3 are connected via the signal line 16a, and communication data transmitted by the main control board 1 is output from the transmission circuit 33 to the signal line 16a. The Here, the transmission circuit 33 is connected to the main microcomputer 30 via the data bus, and the communication data stored in the transmission buffer 32 of the main microcomputer 30 is transferred via this data bus. The transferred communication data is output to the signal line 16a without delay.

  The communication data output from the transmission circuit 33 of the main control board 1 is input to the reception circuit 51 a of the data relay board 3. The receiving circuit 51a is connected to the relay microcomputer 50 via a data bus, and transfers the received communication data to the reception buffer 52a of the relay microcomputer 50. The transmission circuit 51b provided on the data relay board 3 is connected to the relay microcomputer 50 via a data bus, and is stored in the transmission buffer 52b of the relay microcomputer 50 via this data bus. The transferred communication data is transferred, and the transferred communication data is output to the signal line 16b without delay.

  The communication data output from the transmission circuit 51b of the data relay board 3 is input to the reception circuit 41 of the sub control board 2. The receiving circuit 41 is connected to the sub microcomputer 40 via a data bus, and transfers the received communication data to the reception buffer 42 of the sub microcomputer 40 at regular intervals.

  Further, the sub control board 2 and the data relay board 3 are connected via the signal lines 17a and 17b as described above. The data relay board 3 includes a transmission circuit 61a that outputs data via the signal line 17a and a reception circuit 61b that inputs data via the signal line 17b. The transmission circuit 61a and the reception circuit 61b are connected to each other. These are connected to the relay microcomputer 50 via the data bus. Here, when fraud detection data (command data described later) is transferred from the relay microcomputer 50 via the data bus, the transmission circuit 61a outputs the transferred command data to the signal line 17a. On the other hand, the receiving circuit 61b transfers fraud detection data (ROM data described later) received via the signal line 17b to the relay microcomputer 50 via the data bus.

  The sub-control board 2 includes a receiving circuit 46a for inputting data via the signal line 17a and a transmitting circuit 46b for outputting data to the signal line 17b. The receiving circuit 46a and the transmitting circuit 46b Each is connected to the sub microcomputer 40 via a bus. Here, the receiving circuit 46a transfers fraud detection data (command data described later) received via the signal line 17a to the sub microcomputer 40 via the data bus. On the other hand, when the fraud detection data (ROM data described later) is transferred from the sub microcomputer 40 via the data bus, the transmission circuit 46b outputs the transferred data to the signal line 17b.

  In addition, since the transmitter circuit and the receiver circuit described above can be applied to a commonly used configuration, detailed description thereof will be omitted.

Next, control processing in the game progress of the slot machine by the main control board 1 and the sub control board 2 will be described.
In the slot machine of this embodiment, as in a general configuration, after rotating the reel by operating the start switch to display the symbols in a variable manner, the reel is stopped by operating the stop switch to bring the symbols on the active line. The game is displayed repeatedly, and the process is executed repeatedly according to the combination of symbols stopped and displayed on the active line.

  As a series of control processes of the main control board 1 in one game, the reel is started in response to the operation of the start switch, and a combination lottery is executed to determine whether or not a plurality of types of combinations are won. Then, communication data including control data indicating the result of the role lottery is generated and transmitted to the sub control board 2 via the signal lines 16a and 16b. Next, in response to the operation of the stop switch, the rotating reel is stopped and communication data including control data indicating the stop position of the reel is generated, and the sub control board 2 is connected via the signal lines 16a and 16b. Send to. Further, when all the reels are stopped, it is determined whether or not the winning combination determined in the winning combination lottery is won. If winning is determined, processing corresponding to the winning combination is executed. Then, communication data including control data indicating the result of the winning determination is generated and transmitted to the sub-control board 2 via the signal lines 16a and 16b.

  On the other hand, when the sub control board 2 receives the communication data from the main control board 1, the sub control board 2 produces an effect according to the control data included in the received communication data. In other words, an effect pattern is selected according to the control data of the communication data, and based on the selected effect pattern, a required sound or light is generated by a speaker or an effect lamp, and a required image is displayed on the liquid crystal display. Control and execute. Further, in the sub control board 2 of the present embodiment, when communication data including control data of the role lottery result is received, AT lottery is executed according to the role lottery result. The AT lottery is a lottery for determining whether or not to enter the AT (assist time) state. When the sub control board 2 wins the AT lottery and enters the AT state, the sub control board 2 receives communication data including a result lottery result. In addition, control for displaying an effect image indicating the operation sequence of the stop switch on the liquid crystal display is executed. Further, the sub-control board 2 manages the period during which the AT state is maintained when the AT lottery is won.

  It should be noted that the control process executed for each game can be the same control process as that of the conventional slot machine, and the details thereof are omitted.

Next, fraud detection processing by the data relay board 3 will be described.
The fraud detection process of the present embodiment is a process for detecting fraud such as falsification or replacement of the ROM constituting the sub microcomputer 40 of the sub control board 2. In this fraud detection process, command data for requesting all data (hereinafter referred to as ROM data) stored in the ROM of the sub microcomputer 40 is transmitted to the sub control board 2 at a preset timing. Thereafter, when ROM data is received from the sub-control board 2, it is determined whether the received ROM data is correct or not.

  Specifically, in the data relay board 3, data having the same content as the ROM data stored in the ROM of the sub microcomputer 40 (hereinafter referred to as determination data) is stored in advance in the ROM of the relay microcomputer 50. ing. In the fraud detection process, when the preset timing is reached, command data for requesting ROM data is transmitted from the transmission circuit 61a. On the other hand, when the sub control board 2 receives the command data transmitted from the data relay board 3 by the receiving circuit 46a, the sub control board 2 copies all the data stored in the ROM of the sub microcomputer 40 according to the command data. The ROM data thus transmitted is transmitted from the transmission circuit 46b. When the data relay board 3 receives the ROM data from the sub-control board 2, the fraud detection process determines whether or not the received ROM data matches the determination data. If the result of this determination is a match, it is determined to be normal, and if it does not match, it is determined to be invalid. Further, when the fraud determination is made by the fraud detection process, the relay microcomputer 50 executes a transmission stop process. This transmission stop processing is processing for stopping transmission of communication data relayed between the main control board 1 and the sub control board 2 to the sub control board 2.

  As described above, the data relay board 3 stops transmission of communication data to the sub control board 2 when it detects fraud to the ROM of the sub control board 2 by the fraud detection process and the transmission stop process. This fraud can prevent profits from occurring. For example, even when the ROM of the sub control board 2 is tampered or replaced so that it is illegally set to the AT state, this unauthorized tampering or replacement can be detected, and transmission of communication data is stopped. It is possible to prevent a profit from being generated due to an illegal AT state. In this embodiment, it is set as a communication stop condition according to the present invention that the ROM data transmitted from the sub-control board 2 is determined to be incorrect.

Next, the main part of the present invention will be described.
The main microcomputer 30 of the main control board 1 stores in its ROM programs and data for generating communication data indicating the result of winning lottery and winning determination results, and communication data based on these programs and data. Execute the generation process to generate communication data. Here, in the communication data generation process, as described above, the original communication data in which the 7-byte data including the base data and the control data are arranged is generated, and the generated original communication data is encrypted. The communication data to be transmitted is generated. In the present embodiment, in the communication data generation process, the entire original communication data is encrypted. Then, the RSA encryption method is used for this encryption, and the original communication data is encrypted with a preset first encryption key.

  The relay microcomputer 50 of the data relay board 3 stores the program and data for decrypting the communication data transmitted from the main control board 1 and the program and data for encrypting the decrypted original communication data in the ROM. The first decryption process and the encryption process using these programs and data are executed. Here, in the first decryption process, the communication data transmitted from the main control board 1 is decrypted using the first encryption key, and the original communication data (7-byte data consisting of the base data and the control data). ) To get. In this first decryption process, the same first encryption key as the communication data generation process of the main microcomputer 30 is set in advance, and the encryption method (RSA encryption method) is set in advance. The communication data can be accurately decoded. On the other hand, in the encryption process, the original communication data acquired in the first decryption process is encrypted by the RSA encryption method with the preset second encryption key, and another communication data to be transmitted to the sub-control board 2 is obtained. Generate. Here, since the second encryption key is set so as to be different from the first encryption key used for encryption on the main control board 1, the main control data can be controlled even if the same original communication data is encrypted. Another communication data different from the communication data encrypted by the substrate 1 is generated. In the present embodiment, the entire original communication data is encrypted in the encryption process. In the present embodiment, the RSA encryption method using the second encryption key corresponds to the encryption rule of the present invention.

  The sub microcomputer 40 of the sub control board 2 stores a program and data for decoding communication data transmitted from the data relay board 3 in its ROM, and executes a second decoding process using these programs and data. To do. Here, in the second decryption process, the communication data transmitted from the data relay board 3 is decrypted using the second encryption key to obtain the original communication data. In this second decryption process, the same second encryption key as the encryption process of the relay microcomputer 50 is set in advance, and the encryption method (RSA encryption method) is set in advance. Data can be correctly decoded.

  In addition, since the encryption of the RSA encryption method in the communication data generation process and the encryption process described above, and the decryption in the first decryption process and the second decryption process, known encryption methods and decryption methods can be applied. Details thereof are omitted.

A series of transmission modes in which communication data is transmitted from the main control board 1 to the sub control board 2 through the data relay board 3 will be described.
The CPU of the main microcomputer 30 executes communication data generation processing in association with the execution of the role lottery or winning determination for each game, and the communication data obtained by encrypting the original communication data with the first encryption key. Generate. Then, the generated communication data is transferred to the transmission circuit 33. The transmission circuit 33 transmits the transferred communication data to the data relay board 3 via the signal line 16a.

  The communication data transmitted from the main control board 1 is input to the receiving circuit 51a of the data relay board 3 connected to the signal line 16a. The reception circuit 51a transfers the received communication data to the reception buffer 52a of the relay microcomputer 50. When the communication microcomputer 50 receives the communication data from the receiving circuit 51a, the CPU of the relay microcomputer 50 executes the first decryption process, decrypts the communication data with the first encryption key, and acquires the original communication data. Further, when the original communication data is acquired by the first decryption process, the encryption process is executed to generate another communication data obtained by encrypting the decrypted original communication data with the second encryption key. Then, the other communication data generated by the encryption process is transferred to the transmission circuit 51b. The transmission circuit 51b transmits the transferred other communication data to the sub-control board 2 via the signal line 16b.

  The communication data transmitted from the data relay board 3 is input to the receiving circuit 41 of the sub control board 2 connected to the signal line 16b. The reception circuit 41 transfers the received communication data to the reception buffer 42 of the sub microcomputer 40. When the communication data is input from the receiving circuit 41, the CPU of the sub microcomputer 40 executes the second decryption process, decrypts the communication data with the second encryption key, and acquires the original communication data. Then, the sub microcomputer 40 executes predetermined control according to the acquired control data of the original communication data.

  As described above, in this embodiment, the communication data transmitted from the main control board 1 to the data relay board 3 and the communication data transmitted from the data relay board 3 to the sub control board 2 are encrypted with mutually different encryption keys. Thus, communication data having different data formats before and after the data relay board 3 are used.

  On the other hand, as described above, when the ROM of the sub control board 2 is illegally tampered or replaced, the data relay board 3 transmits the communication data to the sub control board 2 through the fraud detection process and the transmission stop process. To stop. Here, in the present embodiment, when the transmission stop process is determined to be illegal by the fraud detection process, when the communication data transmitted from the main control board 1 is received, the first decryption process and the encryption process are performed. And do not run. Thereby, the communication data to be transmitted to the sub control board 2 is not generated, and the transmission of the communication data to the sub control board 2 is stopped.

Such fraud detection by the data relay board 3 and stop of transmission of communication data are known from the above-mentioned Patent Document 1. Therefore, in order to allow unauthorized persons to gain unauthorized profits by altering or replacing the ROM of the sub-control board 2, a bypass path that allows direct communication between the main control board 1 and the sub-control board 2 is further constructed. The fraud detection and the transmission stop may be disabled.
The configuration of the present embodiment can prevent the generation of illegal profits associated with this even when such a bypass route is illegally constructed. More specifically, when an illegal bypass route is constructed, communication data received by the sub-control board 2 via this bypass route is encrypted with the first encryption key by the communication data generation process of the main microcomputer 30. Therefore, it cannot be decoded by the second decoding process of the sub microcomputer 40. This is because the second decryption process is performed using a second encryption key different from the first encryption key. As described above, the sub-control board 2 cannot decode the communication data received via the bypass path, and therefore cannot acquire the original communication data and executes control using the control data included in the original communication data. Can not. As a specific example, even if the ROM of the sub-control board 2 is illegally altered or replaced and an illegal bypass path that bypasses the data relay board 3 is formed in order to illegally enter the AT state. In the configuration of the example, since control data (such as a role lottery result) transmitted from the main control board 1 cannot be acquired, the sub-control board 2 cannot execute control for notifying the operation order of the stop switch. Thereby, generation | occurrence | production of the profit by making into AT state illegally can be prevented reliably.

In this invention, it is not limited to the Example mentioned above, About the structure other than the above-mentioned Example, it can change and implement suitably within the range of the meaning of this invention.
For example, in the above-described embodiment, both the communication data transmitted from the main control board and the communication data transmitted from the data relay board are encrypted, but only one of them is encrypted. You can also Specifically, the main control board transmits the original communication data to the data relay board as communication data, and the data relay board encrypts the original communication data and sub-controls the encrypted communication data. You may make it transmit to a board | substrate.

  In the above-described embodiment, the RSA encryption method is used to encrypt the original communication data. However, the present invention is not limited to this, and other encryption methods can be applied. For example, an AES encryption method, a DES encryption method, or the like can be used. Furthermore, in the above-described embodiment, the same encryption method is used for encryption on the main control board and encryption on the data relay board. However, the present invention is not limited to this, and different encryption methods may be used. it can. Here, when different encryption methods are used, mutually different encryption keys may be set, or the same encryption key may be set.

  In the above-described embodiment, the communication data is generated by encrypting the entire original communication data with the encryption key using the main control board and the data relay board. However, the present invention is not limited to this. The communication data may be generated by encrypting at least one of the constituent data of the original communication data with the encryption key. For example, only the control data of the original communication data is encrypted with the encryption key. Furthermore, different control data may be encrypted with an encryption key between the main control board and the data relay board.

  In the above-described embodiment, the communication data is generated by encrypting with the encryption key. However, the present invention is not limited to this, and the communication data may be generated according to other encryption rules. For example, communication data may be generated by changing the order of a plurality of control data constituting original communication data, or camouflage dummy data is added as configuration data to original communication data. By doing so, the communication data may be generated. Further, the order change of the control data, the addition of dummy data, and encryption of the encryption key may be combined, or any one of them may be used on the main control board and the other may be used on the data relay board.

  In the above-described embodiment, the fraud detection by the data relay board is intended for the alteration or replacement of the ROM of the sub-control board. However, the invention is not limited to this, and other fraudulent acts are detected. May be. For example, when illegal data is transmitted to the data relay board, the illegality may be detected. In this case, the data relay board stores in advance all the data that may be transmitted from the main control board, and if it receives data different from the stored data, it detects it as illegal. In addition, detection of unauthorized radio waves, unauthorized opening of the front door, and the like may be detected. Further, in the above-described embodiment, when fraud is detected in the data relay board, transmission of communication data to the sub-control board is stopped. Thus, the occurrence of fraud may be notified by a liquid crystal display or a speaker. Alternatively, when fraud is detected, the occurrence of fraud may be notified to another control board of the sub control board.

  In the above-described embodiment, the AT lottery is executed on the sub-control board. However, as another configuration, the AT lottery may be executed on the main control board. Even in such a configuration, it is possible to illegally enter the AT state by altering or replacing the ROM of the sub-control board, so that the same operational effects as in the present embodiment can be obtained.

  In the above-described embodiment, the data relay board is disposed on the communication path between the main control board 1 and the sub control board 2, but the present invention is not limited to this, and the transmission side control board (not shown) that transmits communication data ( As long as the data relay board is disposed in the communication path between the first control board) and the receiving control board (second control board) that receives the communication data, the same effects as the present embodiment are achieved. Play. For example, the main control board may be a transmission-side control board, the payout control board for executing payout control of gaming media such as coins may be a reception-side control board, and the data relay board of the present invention may be disposed between them. . Even in the case of this configuration, according to the present invention, it is possible to prevent profits from being obtained by illegally performing the game medium payout control by the payout control board as in the above-described embodiment. Alternatively, the main control board may be a transmission-side control board, the management control board for managing game history such as the number of balls to be played may be a reception-side control board, and the data relay board of the present invention may be disposed between them. .

  In the above-described embodiment, the present invention is applied to a slot machine, but the present invention can be similarly applied to a gaming machine such as a pachinko machine.

1 Main control board (first control board)
2 Sub-control board (second control board)
3 Data relay board

Claims (2)

A first control board comprising data generation means for generating communication data including control data, and transmitting the communication data generated by the data generation means;
A second control board that is connected to the first control board via a communication path for transmitting the communication data and performs predetermined control based on the control data of the communication data transmitted from the first control board In a gaming machine equipped with
Wherein provided on the communication path, the with the first control relaying the communication data sent from the substrate to the second control board, due to a predetermined communication stop condition is satisfied Then the second control Incorrect detection A data relay board for stopping transmission of the communication data to the board,
The first control board performs a process of encrypting the original communication data according to a predetermined first encryption rule by the data generation means, and transmits the encrypted communication data to the data relay board. Is what
The data relay board uses a data conversion means to decrypt the communication data sent from the first control board, and the decrypted communication data is different from the first encryption rule, It performs processing to encrypt in accordance with the defined second encryption rule, and transmits the encrypted communication data to the second control board,
The gaming machine, wherein the second control board performs a second decoding process for decoding communication data sent from the data relay board. A first control board comprising data generation means for generating communication data including control data, and transmitting the communication data generated by the data generation means;
A second control board that is connected to the first control board via a communication path for transmitting the communication data and performs predetermined control based on the control data of the communication data transmitted from the first control board In a gaming machine equipped with
Wherein provided on the communication path, the with the first control relaying the communication data sent from the substrate to the second control board, due to a predetermined communication stop condition is satisfied Then the second control Incorrect detection A data relay board for stopping transmission of the communication data to the board,
The first control board transmits data for original communication to the data relay board by the data generation means,
The data relay board performs processing for encrypting the communication data sent from the first control board according to a predetermined encryption rule by the data conversion means, and the encrypted communication data Two to be sent to the control board,
The gaming machine, wherein the second control board performs a decoding process for decoding communication data sent from the data relay board.

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