JP4313004B2 - Game machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gaming machine including a control unit having a processing unit, a port unit, and a decoding unit.
[0002]
[Prior art]
Conventionally, a pachinko machine that is a type of gaming machine includes a plurality of control boards for controlling the pachinko machine. For example, as such a control board, a main control board that controls the game as a whole, a symbol control board that executes symbol control for the symbol display device, a lamp control board that executes lamp control for various lamps, and There is a voice control board that performs voice control on a speaker. Each of these control boards is provided with a variety of electronic components necessary for the control board to perform predetermined control on a single board. Specifically, a processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit inputs / outputs (outputs) various signals, and an address signal from the processing unit are decoded, Three parts roughly divided into a decoding unit that generates a signal are provided on one substrate.
[0003]
[Problems to be solved by the invention]
By the way, in the pachinko machine, based on the specification change or the like, a detection component that detects a control component controlled by a control signal from the processing unit or a detected object and outputs the detection result to the processing unit is added or There was a case to delete. For example, when an accessory having a movable body is added, it is necessary to connect an actuator (solenoid or the like), which is a control component for operating the movable body, to the control board. At this time, if there is no unused connection pin (connection terminal) for connecting the actuator to the port of the port portion, a port for connecting the actuator to the port portion has to be newly added. Further, along with the addition of the port, a selection circuit (configured by an OR circuit or the like) must be added to the decoding unit. On the other hand, when deleting the actuator, it is necessary to delete the port of the port portion and the select circuit of the decoding portion that are no longer necessary.
[0004]
When adding or deleting control components in this way, changes such as adding or deleting electronic components to the port unit or decoding unit occur, but adding or deleting electronic components to the processing unit, etc. Almost no change occurs. However, when the processing unit, the port unit, and the decoding unit are provided on a single substrate as in the prior art, it is very difficult to make a local change to such a control substrate. Will accompany. For this reason, a control board is newly designed in accordance with the specification change, and the control board itself is changed (replaced) to a new control board including a processing unit that does not need to be changed. Therefore, when the specification change occurs in the pachinko machine, the control board itself is exchanged, which increases the cost of the pachinko machine.
[0005]
On the other hand, when various detection sensors as detection components are added or deleted, the control board itself needs to be replaced in the same manner. For example, when adding a detection sensor, if there is an unused connection pin (connection terminal) for connecting the detection sensor to a port in the port section, a signal line from the detection sensor is newly added to the port. I had to. In addition, a signal line for connecting the port and the processing unit has to be newly added. On the other hand, when the detection sensor is deleted, it is necessary to delete the signal line connecting the unnecessary port and the detection sensor and the signal line connecting the port and the processing unit.
[0006]
When detecting parts are added or deleted in this way, changes such as addition or deletion of signal lines occur in the port section or processing section, but changes such as addition or deletion of signal lines occur in the decoding section. Almost never occurs. However, since a signal line is printed on the control board, in order to make a change such as addition or deletion of the signal line, it is necessary to newly design a control board according to the specification change. For this reason, the control board itself must be replaced with a new control board including the decoding unit that does not need to be changed. Therefore, when the specification change occurs in the pachinko machine, the control board itself is exchanged, which increases the cost of the pachinko machine.
[0007]
This invention was made paying attention to the problem which exists in such a prior art, and the objective is to provide the gaming machine which can suppress the cost increase regarding a gaming machine.
[0008]
[Means for Solving the Problems]
In order to solve the above problems, the invention according to claim 1 is a processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit inputs and outputs various signals, and the processing unit. A control unit having a decoding unit that decodes an address signal from the signal and generates a predetermined signal, and the control unit includes the processing unit Processing substrate with , Above Port part A port board provided with Decoding part Independent of the decoding board provided with Multiple boards The processing board is connected to the port board in a state in which a signal from the port board can be input, and the port board is in a state in which a signal from the decoding board can be input to the decoding board. The decoding substrate is connected to the processing substrate in a state in which a signal from the processing substrate can be input, and the processing substrate, the port substrate, and the decoding substrate are provided without using an unused connection terminal. By connecting the output side connector and the input side connector provided on each board with signal lines The processing unit, Above Port part and Above Decoding part On a board basis Independently separable That each board is housed in a single protective case and attached to the aircraft. The gist.
[0009]
The invention described in claim 2 A processing unit that executes predetermined arithmetic processing, an input port unit that is used when the processing unit inputs various signals, an output port unit that is used when the processing unit outputs various signals, and the processing unit A control unit having a decoding unit that decodes an address signal from the signal and generates a predetermined signal. The control unit includes a processing substrate provided with the processing unit and the input port unit, and the output port unit. A port substrate and a plurality of independent substrates comprising the decode substrate provided with the decode unit, wherein the decode substrate is connected to the processing substrate in a state in which a signal from the processing substrate can be input, and the port The substrate is connected to the decode substrate in a state in which a signal from the decode substrate can be input, and the processing substrate, the port substrate, and the decode substrate are connected to an unused connection end. The processing unit, the input port unit, the output port unit, and the decoding unit can be independently separated on a substrate basis by connecting the output side connector and the input side connector provided on each substrate with a signal line Connected in a state, and in that state, each board is housed in a single protective case and attached to the aircraft. The gist.
[0010]
The invention according to claim 3 A processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit inputs and outputs various signals, and a decoding unit that decodes an address signal from the processing unit and generates a predetermined signal The control means comprises a plurality of independent substrates including a processing substrate provided with the processing unit, a port substrate provided with the port unit, and a decoding substrate provided with the decoding unit, The processing board is connected to the port board in a state in which a signal from the port board can be input, and the port board is connected to the decoding board in a state in which a signal from the decoding board can be input, The decoding board is connected to the processing board in a state where a signal from the processing board can be input, and the processing board, the port board, and the decoding board are connected unused. Without providing a child, by connecting the output side connector and the input side connector provided on each substrate with a signal line, the processing unit, the port unit and the decoding unit are connected in a state that can be independently separated on a board basis, In that state, each board is housed in a single protective case and attached to the aircraft. The port section is provided with a plurality of ports, and each port is capable of performing at least one of input and output of the various signals. At least one of the control component controlled based on the control signal from the processing unit and the detection component that detects the detected object and outputs the detection result to the processing unit is connected, and Each port includes a common port to which at least one of control parts and detection parts common to the gaming machine model is connected, and at least among control parts and detection parts dedicated to the gaming machine model. Either port is classified as a dedicated port, and the port section The port board provided with the common port is divided into a first port board provided with the common port and a second port board provided with the dedicated port, and the common port and the dedicated port can be independently separated on a board basis. The decode unit includes a plurality of decode circuits and a plurality of select circuits, and each decode circuit and each select circuit are connected to a common circuit connected to the common port and to the dedicated port. The decoding board provided with the decoding unit is divided into a first decoding board provided with the common circuit and a second decoding board provided with the dedicated circuit, and the common circuit and the dedicated circuit are provided. That the circuit is in a state where it can be separated independently in units The gist.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
Hereinafter, a first embodiment in which the present invention is embodied in one type of pachinko gaming machine (hereinafter referred to as “pachinko machine”) will be described with reference to FIGS.
[0012]
FIG. 1 schematically shows the surface side of a pachinko machine 10. A vertical rectangular middle frame 12 on which various machine components are set on the front side of an opening of an outer frame 11 that forms an outline of the machine body in the pachinko machine 10. Is assembled so as to be openable and detachable. Further, on the front side of the middle frame 12, a front frame 14 and a top ball tray 15 each having a glass frame for protecting the game board 13 disposed inside the machine in a see-through manner are assembled so as to be openable and closable in a laterally open state. ing. In addition, on the front side of the periphery of the front frame 14 and the game area 13 a of the game board 13, an electric lamp 16 that performs light emission decoration such as lighting (flashing) and extinguishing is provided. In addition, speakers 17 for outputting a predetermined sound (sound effect) are provided on both sides of the upper ball tray 15. Further, a lower ball tray 18, a launcher 19, and the like are attached to the lower part of the middle frame 12.
[0013]
In addition, a symbol display device 20 for performing a symbol combination game in which a plurality of types of symbols are displayed in a varying manner is disposed in the approximate center of the game area 13 a of the game board 13. The symbol display device 20 is provided with a visible display portion H composed of a liquid crystal screen, and a plurality of columns (for example, three columns) of symbols are displayed on the visible display portion H for each column. It has become. Therefore, the player can recognize the state of the big hit state, the reach state, or the off state from the combination of the symbols in each column displayed on the visible display portion H. And, as a result of the symbol combination game, when all the symbols in the row are a combination of symbols of the same type, a big hit state is given, and the player has a chance to acquire a large number of game balls (prize balls). Be able to.
[0014]
Further, below the symbol display device 20, a start winning opening 21 provided with a normal electric accessory 21a that is opened and closed by a first actuator A1 (shown in FIG. 3) made of a solenoid or the like is disposed. Behind the start winning opening 21, a start winning opening sensor S1 (shown in FIG. 3) for detecting a winning game ball is arranged. Also, below the start winning opening 21, a large winning opening 22 that is opened and closed by a second actuator A2 (shown in FIG. 3) made of a solenoid or the like is disposed. Behind the big winning opening 22 is a count sensor S2 (shown in FIG. 3) for detecting a winning game ball and counting the number of winning, and a specific passing count for detecting a specific winning (so-called V winning). A sensor S3 (shown in FIG. 3) is provided.
[0015]
Further, on both sides of the start winning opening 21 and the big winning opening 22, a first winning opening 23, a second winning opening 24, a third winning opening 25, and the like, in which a predetermined number of winning balls are paid out by winning a game ball, A fourth winning opening 26 is provided. Behind these first to fourth winning ports 23 to 26 are a first winning port sensor S4, a second winning port sensor S5, a third winning port sensor S6, and a fourth for detecting a winning game ball. A winning mouth sensor S7 (both shown in FIG. 3) is provided.
[0016]
On the other hand, FIG. 2 schematically shows the back side of the pachinko machine 10, and on the back side of the middle frame 12, a mechanism set board 28 having various ball passages and processing devices is detachably set. . A protective cover 29 is set on the mechanism set board 28 so as to be openable and closable at a position corresponding to the back side of the game board 13. In the protective cover 29, a symbol control board (hereinafter referred to as “symbol board”) 30 for executing symbol control for performing a symbol combination game in the symbol display device 20 is mounted. Further, a lamp control board (hereinafter referred to as “lamp board”) 31 for executing lamp control for controlling lighting (flashing) / extinguishing of the illumination lamp 16 is mounted in the protective cover 29. Also, a payout control board (hereinafter referred to as “payout board”) 32 for executing payout control for controlling the payout of game balls such as prize balls is mounted in the right region below the protective cover 29. . Further, a voice control board (hereinafter referred to as “voice board”) 33 that performs voice control for controlling voice output from the speaker 17 is mounted in the right region below the protective cover 29.
[0017]
A main control unit 34 is disposed in the left region below the protective cover 29 as a control means for controlling the pachinko machine 10 as a whole. The main controller 34 is formed by connecting a plurality of independent substrates (three substrates in the present embodiment) (processing substrate 38, port substrate 39, and decoding substrate 40). A plurality of substrates forming the main control unit 34 are mounted on the mechanism set board 28 in a state of being housed in a protective case (not shown). In addition, you may change suitably the form in which each board | substrate is accommodated in a protective case. For example, each substrate may be accommodated in a separate protective case, or each substrate may be accommodated in a single protective case. Moreover, when each board | substrate is accommodated in a single protective case, it shall be set as the state which laminated | stacked each board | substrate or the state which has arrange | positioned each board | substrate in the horizontal direction (lateral direction), for example.
[0018]
The main controller 34 receives winning signals N1 to N7 from the sensors S1 to S7 and the like, and a control command for instructing the substrates 30 to 33 and the first and second actuators A1 and A2 to perform predetermined control. And a process of outputting the control command as a control signal. This series of processing is performed by inputting a processing unit 35 that executes predetermined arithmetic processing, a port unit 36 used when the processing unit 35 inputs and outputs various signals, and an address signal from the processing unit 35, The decoding part 37 which produces | generates a signal is performed by taking each role (both are shown in FIG. 3). Therefore, the main control unit 34 of the present embodiment divides each of the units 35 to 37, which are roughly classified as described above, into separate substrates (the processing unit 35 is a processing substrate 38, the port unit 36 is a port substrate 39, and the decoding unit 37 is It is provided on the decode substrate 40) and is formed by a set of the substrates. Therefore, the main control unit 34 of the present embodiment is configured such that each of the units 35 to 37 can be independently separated (in this embodiment, divided into three) in units of the processing substrate 38, the port substrate 39, and the decoding substrate 40.
[0019]
Next, the connection aspect of the various components of the pachinko machine 10 of this embodiment and various boards is demonstrated based on FIG. In this embodiment, on each board, an input side connector (not shown) is provided on the side where the board inputs signals, and an output side connector (not shown) is provided on the side where signals are output. The boards are connected by connecting the output side connector of one board and the input side connector of the other board with a predetermined signal line. The board and the actuator are connected by connecting the output connector of the board and the actuator with a predetermined signal line. On the other hand, internal components such as various electronic components (CPU, RAM, etc.) on each board and various electronic components and an input side connector or output side connector on the board are signal lines printed on the board. It is connected. In the following description, in order to distinguish these signal lines, the signal lines printed on the substrate are referred to as “printed lines”.
[0020]
The processing substrate 38 (processing unit 35) and the port substrate 39 (port unit 36) are connected to each other in a state where signals (data) can be input and output. The port board 39 is connected to a pattern board 30, a lamp board 31, a payout board 32, an audio board 33, first and second actuators A1 and A2, and sensors S1 to S7. The decode substrate 40 (decode unit 37) is connected to the process substrate 38 (process unit 35) in a state where a signal (data) from the process substrate 38 (process unit 35) can be input. The port substrate 39 (port unit 36) is connected to the decode substrate 40 (decode unit 37) in a state where a signal (data) from the decode substrate 40 (decode unit 37) can be input.
[0021]
The processing unit 35 includes a CPU 41 that executes various arithmetic processes to control the entire pachinko machine 10, and a ROM 42 and a RAM 43 are connected to the CPU 41. The CPU 41 sequentially updates various random numbers such as jackpot determination random numbers and reach determination random numbers at predetermined intervals. The ROM 42 stores a control program for controlling the pachinko machine 10 and the like. The RAM 43 stores various information (such as various random values) that can be appropriately rewritten during the operation of the pachinko machine 10.
[0022]
The CPU 41 calculates various control commands for instructing predetermined control using the winning signals N1 to N7 output from the sensors S1 to S7 and the various random numbers described above. The CPU 41 is configured to output various control commands that have undergone arithmetic processing to the port unit 36 as control signals M1 to M5. Further, the CPU 41 is configured to output various control commands that have undergone arithmetic processing to the decoding unit 37 as an address signal AS and a write signal WS. In the present embodiment, the main part of the processing unit 35 is configured by various electronic components of the CPU 41, the ROM 42, and the RAM 43. The “main part” is an electronic component (or component member) necessary for executing a predetermined process.
[0023]
The port unit 36 includes output ports P1 to P5 as a plurality (in the present embodiment, five) ports and an input port P6 as a single port. Each of the ports P1 to P6 includes a plurality of input terminals and a plurality of output terminals. The payout board 32 is connected to the output terminal of the output port P1, and the symbol board 30 is connected to the output terminal of the output port P2. The lamp board 31 is connected to the output terminal of the output port P3, and the sound board 33 is connected to the output terminal of the output port P4. The first and second actuators A1 and A2 are connected to the output terminal of the output port P5 via the actuator circuit AC. The sensors S1 to S7 are connected to the input terminal of the input port P6 via a prize ball information input circuit SC.
[0024]
The CPU 41 of the processing unit 35 is connected to the input terminals of the output ports P1 to P5 and the output terminal of the input port P6. The CPU 41 and the output ports P1 to P5, the output ports P1 to P4 and the CPUs of the boards 30 to 33, and the output port P5 and the actuator circuit AC are connected via a plurality of signal lines. However, the signal lines are simplified in FIGS. Further, the CPU 41 and the input port P6, and the input port P6 and the prize ball information input circuit SC are connected via a plurality of signal lines, but the signal lines are simplified in FIGS. Yes.
[0025]
The output port P1 can output a control signal M1 for instructing the payout control output by the CPU 41 to the payout board 32. The output port P <b> 2 can output a control signal M <b> 2 instructing the symbol control output by the CPU 41 to the symbol substrate 30. The output port P3 can output a control signal M3 for instructing lamp control output from the CPU 41 to the lamp substrate 31. The output port P4 can output a control signal M4 for instructing voice control output by the CPU 41 to the voice board 33. The output port P5 can output a control signal M5 instructing the operation output by the CPU 41 to the first and second actuators A1 and A2. The input port P6 receives the winning signals N1 to N7 from the sensors S1 to S7, and the CPU 41 receives the winning signals N1 to N7 via the input port P6.
[0026]
In the present embodiment, the substrates 30 to 33, the actuator circuit AC, and the first and second actuators A1 and A2 are control components controlled based on various control signals M1 to M5 from the processing unit 35 (CPU 41). . In the present embodiment, the prize ball information input circuit SC and each of the sensors S1 to S7 detect a game ball as a detection target, and output winning signals N1 to N7 as detection results to the CPU 41 of the processing unit 35. Detection component Moreover, in this embodiment, the main part of the port part 36 is comprised by the various electronic components of the output ports P1-P5 and the input port P6.
[0027]
The decoding unit 37 includes a plurality (two in the present embodiment) of decoding circuits 44 and 45 and a plurality (five in the present embodiment) of select circuits 46-50. The select circuits 46 to 50 are composed of, for example, an OR circuit. The decode circuits 44 and 45 have a plurality of input terminals and a plurality of output terminals. Each of the select circuits 46 to 50 includes a plurality (two in this embodiment) of input terminals and a single output terminal.
[0028]
The CPU 41 of the processing unit 35 is connected to the input terminal of the decode circuit 44, and one input terminal of each select circuit 46 to 49 is connected to the output terminal of the decode circuit 44. Further, the CPU 41 of the processing unit 35 is connected to the input terminal of the decode circuit 45, and one input terminal of the select circuit 50 is connected to the output terminal of the decode circuit 45. The CPU 41 and each of the decode circuits 44 and 45 are connected via a plurality of signal lines, but the signal lines are simplified in FIGS. The CPU 41 of the processing unit 35 is connected to the other input terminal of each select circuit 46-50.
[0029]
Further, the input terminal of the output port P1 is connected to the output terminal of the select circuit 46, and the input terminal of the output port P2 is connected to the output terminal of the select circuit 47. Further, the input terminal of the output port P3 is connected to the output terminal of the select circuit 48, and the input terminal of the output port P4 is connected to the output terminal of the select circuit 49. The input terminal of the output port P5 is connected to the output terminal of the select circuit 50.
[0030]
The decode circuits 44 and 45 decode the address signal AS from the CPU 41 and output the decoding result to the select circuits 46 to 50. Among the select circuits 46 to 50, the select circuits 46 to 50 in which the signal indicating the decoding result and the signal level of the write signal WS match each other correspond to the output ports P1 to P5 corresponding to the select circuits 46 to 50. Select signals SL1 to SL5 (predetermined signals) are output. The select signals SL1 to SL5 are signals for selecting (specifying) the output ports P1 to P5. As described above, the decoding unit 37 decodes the address signal AS and outputs the select signals SL1 to SL5 only to the output ports P1 to P5 corresponding to the output destinations of the various control signals M1 to M5. In the present embodiment, the decoding circuit 44, 45 and the various electronic components of the selection circuits 46 to 50 constitute the main part of the decoding unit 37.
[0031]
Next, a control mode of the main control unit 34 configured as described above will be described.
The CPU 41 of the processing unit 35 calculates and processes a control command for instructing each of the substrates 30 to 33 and the first and second actuators A1 and A2 to perform predetermined control. Then, the CPU 41 outputs a control command for instructing predetermined control to the output ports P1 to P5 of the port unit 36 as control signals M1 to M5. Further, the CPU 41 computes a control command for designating output ports P1 to P5 used when outputting the control command as the control signals M1 to M5. Then, the CPU 41 outputs a control command for designating the output ports P1 to P5 to the respective decoding circuits 44 and 45 of the decoding unit 37 as the address signal AS.
[0032]
Each of the decode circuits 44 and 45 decodes the address signal AS and outputs a signal indicating the decode result to each of the select circuits 46-50. Each of the select circuits 46 to 50 having received the signal indicating the decoding result determines whether or not the signal level of the write signal WS output from the CPU 41 matches the signal level indicating the decoding result. The select circuits 46-50 having the same signal level output the select signals SL1-SL5 to the output ports P1-P5 connected to the select circuits 46-50. The output ports P1 to P5 to which the select signals SL1 to SL5 are input output the control signals M1 to M5 output from the CPU 41.
[0033]
Hereinafter, a mode in which the CPU 41 of the processing unit 35 instructs the payout control board 32 to perform payout control will be described as an example.
When the game ball launched into the game area 13a of the game board 13 by the operation of the launching device 19 wins the first winning port 23, the first winning port sensor S4 disposed in the first winning port 23 is A winning signal N4 is output. The winning signal N4 is input to the CPU 41 via the input port P6 of the port unit 36. The CPU 41 having received the winning signal N4 calculates a winning ball payout command indicating the number of winning balls to be given to the player in accordance with the winning of the game ball to the first winning port 23. Then, the CPU 41 outputs the calculated prize ball payout command to the port unit 36 as a control signal M1. This control signal M1 is output to each of the output ports P1 to P5 constituting the port unit 36.
[0034]
Further, the CPU 41 calculates a control command indicating an address of the payout control board 32 that is an output destination of the prize ball payout command, along with the calculation process of the prize ball payout command. A control command indicating the address of the payout control board 32 is output as an address signal AS to the decoding circuits 44 and 45 of the decoding unit 37. Each decode circuit 44, 45 decodes the address signal AS and outputs a signal indicating the decoding result to each select circuit 46-50. In the case of this example, in the select circuit 46, the signal indicating the decoding result and the signal level of the write signal WS match, and only the select circuit 46 outputs the select signal SL1 to the output port P1. As a result, the control signal M1 output from the CPU 41 is output only from the output port P1 to which the select signal SL1 is input. The payout control board 32 to which the control signal M1 is input executes payout control based on a prize ball payout command indicated by the control signal M1, and a predetermined number of game balls (or lower balls 18) are placed in the upper ball tray 15 (or the lower ball tray 18). Award).
[0035]
Next, in the pachinko machine 10 according to the present embodiment, for example, when a specification change (or model change) of the pachinko machine 10 needs to provide (add) an accessory having a movable body in the game area 13a, for example. Will be described with reference to FIG.
[0036]
In the case of adding an accessory having the movable body, a third actuator A3 (indicated by a two-dot chain line in FIG. 3) is required as a control component including a solenoid for operating the movable body. When the third actuator A3 is controlled by the main control unit 34, it is necessary to newly connect the third actuator A3 and the main control unit 34. At this time, if there is no unused connection pin (output terminal) in the output port P5 connected to the actuator circuit AC, it is necessary to add a new output port P7 (indicated by a two-dot chain line in FIG. 3). . When the output port P7 is added, it is necessary to newly connect the output port P7 to the decoding unit 37. At this time, it is necessary to add a new select circuit 51 (indicated by a two-dot chain line in FIG. 3) with the addition of the output port P7.
[0037]
Then, when it becomes necessary to newly add the output port P7 and the select circuit 51 described above with the addition of the accessory having a movable body, the main control unit 34 of the present embodiment is changed as follows.
[0038]
That is, a new decode board 40a designed by adding a select circuit 51 to the decode unit 37 is prepared. A print line (indicated by a two-dot chain line in FIG. 3) for connecting the select circuit 51 and the decode circuit 45 is added on the decode board 40a by the addition of the select circuit 51. ing. Further, a printed line (indicated by a two-dot chain line in FIG. 3) is added between the input side connector and the select circuit 51 on the decode board 40a. Further, a printed line (indicated by a two-dot chain line in FIG. 3) is added between the select circuit 51 and the output side connector on the decode board 40a.
[0039]
Also, a new port board 39a designed by adding the output port P7 to the port portion 36 is prepared. On the port board 39a, a printed line (indicated by a two-dot chain line in FIG. 3) is added between the input side connector and the output port P7. On the port board 39a, a printed line (indicated by a two-dot chain line in FIG. 3) is provided between the output side connector connected to the actuator circuit AC (to which the third actuator A3 is connected) and the output port P7. Have been added.
[0040]
Then, the decode board 40 is replaced with the decode board 40a, and the port board 39 is replaced with the port board 39a. On the other hand, the processing unit 35 corrects (or changes) the control program stored in the ROM 42 with the addition of the third actuator A3. However, since there is no change (addition) of a physical electronic component accompanying the addition of the third actuator A3, the processing unit 35 uses the processing substrate 38 after the control program stored in the ROM 42 is corrected. It is possible. Then, the processing substrate 38, the decode substrate 40a, and the port substrate 39a are connected by a signal line to form the main control unit 34. As a result, the CPU 41 of the processing board 38 and the newly added select circuit 51, and the select circuit 51 and the newly added output port P7 are connected. Thus, the main control unit 34 after the substrates 38, 40a, 39a are connected by the signal lines is in a controllable state as described above.
[0041]
Here, a mode in which the CPU 41 controls the third actuator A3 will be briefly described.
The CPU 41 computes a control command for instructing the operation of the third actuator A3, and outputs the control command as a control signal M5 to the output ports P1 to P5 and P7. In the present embodiment, when the third actuator A3 is controlled, the control signal M5 that instructs the operation of the first and second actuators A1 and A2 is used. Further, the CPU 41 outputs a control command for designating the output port P7 to each of the decode circuits 44 and 45 as an address signal AS. Each decode circuit 44, 45 decodes the address signal AS and outputs a signal indicating the decoding result to each select circuit 46-51. Then, the select circuit 51 in which the signal level of the signal indicating the decoding result and the write signal WS from the CPU 41 coincides outputs the select signal SL6 to the output port P7. The output port P7 to which the select signal SL6 is input outputs a control signal M5 output from the CPU 41 to the third actuator A3 via the actuator circuit AC. The third actuator A3 that receives the control signal M5 operates based on the control command indicated by the control signal M5.
[0042]
On the other hand, when the main control unit 34 is formed by the processing substrate 38, the port substrate 39a, and the decode substrate 40a, the main control unit 34 is changed as follows when deleting an accessory due to a specification change or the like. The
[0043]
In this case, the third actuator A3 becomes unnecessary, and the output port P7 and the select circuit 51 connected to the third actuator A3 become unnecessary. Since these unnecessary output ports P7 and connection terminals of the select circuit 51 remain as unused “vacant pins”, leaving such “empty pins” suppresses illegal acts on gaming machines. It cannot be said that it is preferable in terms of meaning. Therefore, in order not to leave “empty pins”, it is necessary to delete the output port P7 and the select circuit 51 that are no longer needed from the board.
[0044]
Therefore, when the main control unit 34 is changed, a new decode board 40 designed by deleting the select circuit 51 and the print line from the decode unit 37 is prepared. Also, a new port board 39 designed by deleting the output port P7 and the print line from the port unit 36 is prepared. Then, the decode board 40 a is replaced with the decode board 40, and the port board 39 a is exchanged with the port board 39. On the other hand, the processing unit 35 corrects (or changes) the control program stored in the ROM 42 with the deletion of the third actuator A3. However, the processing unit 35 can use the processing substrate 38 as it is because there is no change (deletion) of a physical electronic component accompanying the deletion of the third actuator A3. Then, by connecting the processing substrate 38, the decode substrate 40, and the port substrate 39 with signal lines to form the main control unit 34, the main control unit 34 becomes controllable as described above.
[0045]
As described above, when the third actuator A3 is added or deleted, changes such as addition or deletion of electronic components (output port P7 and select circuit 51) and printed lines are made to the port unit 36 and the decoding unit 37. Occurs. On the other hand, changes such as addition or deletion of electronic components and printed lines are not made to the processing unit 35. Therefore, by configuring the main control unit 34 so as to be independently separable, only the port board 39 (39a) and the decode board 40 (40a) in which physical changes occur are replaced, and the processing board 38 in which no physical changes occur. Can be used as is.
[0046]
Next, in the pachinko machine 10 of the present embodiment, for example, when a specification change (or model change) of the pachinko machine 10 requires a fifth winning opening to be provided (added) in the game area 13a, for example, FIG. 3 and FIG.
[0047]
In the case of adding the fifth prize opening, a fifth prize opening sensor S8 (indicated by a two-dot chain line in FIG. 3) is required as a detection component for detecting a game ball won in the fifth prize opening. In order to input the winning signal N8 output from the fifth winning mouth sensor S8 to the main controller 34, it is necessary to newly connect the fifth winning mouth sensor S8 and the main controller 34. At this time, if there is an unused connection pin (input terminal) in the input port P6, it is necessary to newly connect the input port P6 and the fifth winning mouth sensor S8 via the prize ball information input circuit SC. . Furthermore, with the addition of the fifth prize opening sensor S8, it is necessary to newly connect the input port P6 and the processing unit 35.
[0048]
By the way, the input port P6 and the prize ball information input circuit SC (each sensor S1 to S7) are connected via an input side connector CN provided on the port board 39 as shown in FIG. . On the port board 39, a printed line is provided between the first to seventh connection pins (input terminals) of the input port P6 to which the sensors S1 to S7 are connected and the input side connector CN. . On the other hand, the eighth connection pin (unused connection pin) that is the input terminal of the input port P6 is provided between the eighth connection pin and the input-side connector CN in order to suppress fraud as described above. No printed lines are provided. That is, the eighth connection pin is not left as an “empty pin”, and even if the fifth prize opening sensor S8 is connected to the input side connector CN via the prize ball information input circuit SC, the prize signal N8 is input. It is in a state that is not.
[0049]
Therefore, when it becomes necessary to newly connect the fifth prize port sensor S8 to the input port P6 and the CPU 41 with the addition of the fifth prize port sensor S8, the main control unit 34 of the present embodiment is as follows. Be changed.
[0050]
That is, a new port board 39b designed by adding a predetermined printed line is prepared. On the port board 39b, as shown in FIG. 4 (b), a printed line for connecting between the eighth connection pin of the input port P6 and the input side connector CN is added. . Further, a printed line (indicated by a two-dot chain line in FIG. 3) is added between the input port P6 and the output side connector on the port board 39b. In addition, a new processing board 38a designed by adding a predetermined printed line is prepared. A printed line (indicated by a two-dot chain line in FIG. 3) is added between the input side connector and the CPU 41 on the processing board 38a.
[0051]
Then, the port substrate 39 is replaced with the port substrate 39b, and the processing substrate 38 is replaced with the processing substrate 38a. Moreover, about the process part 35, the correction | amendment (or change) of the control program memorize | stored in ROM42 is performed with the addition of 5th prize opening sensor S8. However, since there is no physical change (addition) accompanying the addition of the fifth prize opening sensor S8, the decoding unit 37 can use the decoding board 40 as it is. Then, the processing substrate 38a, the decode substrate 40, and the port substrate 39b are connected by signal lines to form the main control unit 34. As a result, the CPU 41 and the newly added fifth winning mouth sensor S8 are connected via the input port P6. Thus, the main control unit 34 after the substrates 38a, 40, 39b are connected by the signal lines is in a controllable state as described above.
[0052]
On the other hand, when the main control unit 34 is formed by the processing substrate 38a, the port substrate 39b, and the decode substrate 40, the main control unit 34 is as follows when deleting the fifth winning a prize due to a specification change or the like. Be changed.
[0053]
In this case, the fifth winning mouth sensor S8 (see FIG. 3) is not necessary. Similarly to the above, in order to suppress fraud, similarly to the printed line between the input port P6 (eighth connection pin) and the input side connector CN on the port board 39b and between the input port P6 and the CPU 41. No need for printed lines. Furthermore, a printed line between the CPU 41 and the input port P6 on the processing board 38a is not necessary.
[0054]
Therefore, when the main control unit 34 is changed, a new port substrate 39 designed by deleting the unnecessary printed lines from the port unit 36 is prepared. In addition, a new processing board 38 designed by deleting the unnecessary printed lines from the processing unit 35 is prepared. Then, the port substrate 39 b is replaced with the port substrate 39 and the processing substrate 38 a is replaced with the processing substrate 38. Further, the processing unit 35 corrects (or changes) the control program stored in the ROM 42 in accordance with the deletion of the fifth winning mouth sensor S8. However, since there is no physical change (deletion) associated with the deletion of the fifth prize opening sensor S8, the decoding unit 37 can use the decoding board 40 as it is. Then, the processing board 38, the decoding board 40, and the port board 39 are connected by signal lines to form the main control section 34, so that the main control section 34 can be controlled as described above.
[0055]
As described above, when the fifth prize opening sensor S8 is added or deleted, the port unit 36 or the processing unit 35 is changed such as adding or deleting a print line. On the other hand, the decoding unit 37 is not changed such as adding or deleting a print line. Therefore, the decode board 40 in which only the port board 39 (39b) and the processing board 38 (38a) that are physically changed by replacing the main control unit 34 so as to be independently separable is exchanged and no physical change occurs. It can be used as it is.
[0056]
Therefore, according to the present embodiment, the following effects can be obtained.
(1) The main control unit 34 is provided with a processing unit 35 divided into a processing substrate 38, a port unit 36 divided into a port substrate 39, and a decoding unit 37 divided into a decoding substrate 40. ˜37 can be independently separated. Therefore, when the specification of the pachinko machine 10 is changed, the board that needs to be changed can be replaced, and the board that does not need to be changed can be used as it is. That is, unlike the conventional case, there is no need to change (replace) the control board itself to a new control board. Therefore, the cost increase regarding the pachinko machine 10 can be suppressed.
[0057]
(2) Further, even when a failure occurs in the main control unit 34, it is only necessary to check the failure for each of the substrates 38 to 40, and the main control unit 34 is formed of one substrate as in the prior art. As compared with the case, it becomes easier to identify the failure location. Therefore, it can contribute to improvement of maintainability. Further, since only the failed board needs to be replaced, other non-failed boards can be used continuously. Therefore, it can contribute to suppression of the cost increase regarding the pachinko machine 10 also from this point.
[0058]
(3) In recent times, effective use of resources has been widely screamed, and it is considered that reusable parts can be reused in game machines such as the pachinko machine 10. Therefore, the main control unit 34 is configured to be independently separable in units of each board 38 to 40, thereby ensuring the versatility of each board 38 to 40 and providing the pachinko machine 10 that can be suitably used for reuse. be able to. Therefore, it can contribute to suppression of the cost increase regarding the pachinko machine 10 also from this point.
[0059]
(4) In the pachinko machine 10, the processing content (control content) executed by the main control unit 34 is substantially common regardless of the model. On the other hand, the sub-control means side such as the symbol board 30, the lamp board 31, and the voice board 33 that executes specific control in response to an instruction from the main control unit 34 performs processing contents (control) Content) is diverse, and various electronic components provided on the substrate also depend on the processing content. For this reason, when the specification is changed, the main control unit 34 can be used continuously if a part of the change is made. On the other hand, it is often more efficient to replace the entire sub-control means than to make a change. . Therefore, by configuring such a highly versatile main control unit 34 so as to be independently separable in units of each board 38 to 40, it is possible to contribute to the suppression of the cost increase related to the pachinko machine 10.
[0060]
(5) In the main control unit 34, a series of processing is executed by the processing unit 35, the port unit 36, and the decoding unit 37 having their respective roles. When changing specifications, it is necessary to add or delete electronic components, printed lines, etc. in units of this processing. Therefore, by making the main control unit 34 separable in units of processing, it is possible to clearly differentiate between a substrate that can be used continuously and a substrate that needs to be replaced when the specification is changed. Therefore, it can contribute to suppression of the cost increase regarding the pachinko machine 10 also from this point.
[0061]
(Second Embodiment)
Hereinafter, a second embodiment in which the present invention is embodied in a pachinko gaming machine (hereinafter referred to as a “pachinko machine”), which is one type thereof, will be described with reference to FIGS. 1, 2, and 5. In the embodiments described below, the same components (or the same contents) as those of the embodiments already described are denoted by the same reference numerals, and the redundant description thereof is omitted or simplified.
[0062]
The pachinko machine 10 of the present embodiment is configured such that each of the ports P1 to P6 is provided separately on a plurality (two in this embodiment) of substrates, and the port portion 36 can be independently separated in units of the substrates. ing. That is, the main control unit 34 is formed by connecting four substrates, that is, a processing substrate 38, a first port substrate 62, a second port substrate 63, and a decoding substrate 40, which are independent of each other, by signal lines or the like. . Therefore, in this embodiment, the main control unit 34 is a unit of the processing board 38, the first port board 62, the second port board 63, and the decoding board 40, and the processing unit 35, the port part 36, and the decoding part 37. Are independently separable (in this embodiment, four divisions).
[0063]
Hereinafter, the first port board 62 and the second port board 63 will be described in detail.
The first port board 62 is provided with a first port portion 60. The first port unit 60 of the present embodiment is provided with a common port to which a common control board is connected (or regardless of the model) for the model of the pachinko machine 10. Specifically, the first port portion 60 has an output port P1 to which the payout board 32 is connected, an output port P2 to which the design board 30 is connected, an output port P3 to which the lamp board 31 is connected, and an audio board. An output port P4 to which 33 is connected is provided. “Common” indicates that it is indispensable for controlling the game regardless of the model of the pachinko machine 10. As a specific example, since the pachinko machine 10 is provided with a symbol display device 20 for performing a symbol combination game, control is performed regardless of the type (for example, liquid crystal type, mechanical type) of the symbol display device 20. The design substrate 30 to be performed is indispensable. Therefore, for example, the control board may have the same or different board configuration (processing contents, electronic components, wiring, etc.).
[0064]
On the other hand, the second port board 63 is provided with a second port portion 61. The second port portion 61 of the present embodiment is provided with a dedicated port to which a dedicated sensor, actuator, or the like is connected to the model of the pachinko machine 10 (or regardless of the model). Specifically, the second port portion 61 is provided with an output port P5 to which the actuator circuit AC is connected and an input port P6 to which the prize ball information input circuit SC is connected. In the actuator circuit AC and the prize ball information input circuit SC, as described above, there is a high possibility that an actuator, a sensor, or the like is added or deleted in accordance with the specification change. “Dedicated” indicates that the model of the pachinko machine 10 is indispensable only in the model when controlling the game. To give a specific example, an actuator for operating the movable body for presentation arranged on the game board 13 is indispensable only in a model that performs a movable presentation, and is unnecessary in a model that does not perform a movable presentation. It becomes.
[0065]
Therefore, in the pachinko machine 10 of the present embodiment, the main control unit 34 is changed as follows in accordance with the specification change of the pachinko machine 10.
When adding an accessory having a movable body to the game area 13a, it is necessary to add an output port P7 and a select circuit 51 as described above. Therefore, in the present embodiment, a new second port board 63a designed by adding the decode board 40a and the output port P7 is prepared. Then, the decode board 40 is replaced with the decode board 40a, and the second port board 63 is replaced with the second port board 63a. As a result, it is possible to use the processing substrate 38 and the first port substrate 62 without any physical electronic component change (or addition). On the other hand, when the accessory is deleted, similarly, it is possible to use the processing substrate 38 and the first port substrate 62 without any physical electronic component change (deletion).
[0066]
Further, when adding the fifth prize opening sensor S8, it is necessary to connect the fifth prize opening sensor S8 and the input port P6, and the input port P6 and the CPU 41 as described above. Therefore, in the present embodiment, a processing board 38a and a new second port board 63a designed by adding a predetermined printed line are prepared. Then, the processing substrate 38 is replaced with the processing substrate 38a, and the second port substrate 63 is replaced with the second port substrate 63a. As a result, it is possible to use the decode board 40 and the first port board 62 that do not require additional printed lines as they are. On the other hand, when the fifth winning award port sensor S8 is deleted, the decode board 40 and the first port board 62 that do not need to delete the printed line can be used as they are.
[0067]
Therefore, according to the present embodiment, in addition to the same effects as the effects (1) to (5) of the first embodiment, the following effects can be obtained.
(6) The port portion 36 is configured to be independently separable in units of the first port board 62 provided with a common port and the second port board 63 provided with a dedicated port. For this reason, by classifying the ports P1 to P6 of the port unit 36 into ports that can be used in common with the model of the pachinko machine 10 and ports that are used exclusively, the ratio that needs to be changed when the specification is changed is high. A portion (first port substrate 62) that can be continuously used in the port portion 36 can be created. Therefore, the cost increase regarding the pachinko machine 10 can be further suppressed.
[0068]
In addition, you may change each said embodiment as follows.
In each of the above embodiments, the processing unit 35, the port unit 36, and the decoding unit 37 of the main control unit 34 are provided on a plurality of substrates so as to be independently separable, but the processing units and ports of the substrates 30 to 33 are provided. The decoder and the decoder may be provided on a plurality of substrates so that they can be independently separated.
[0069]
In each of the embodiments, the main control unit 34 provides the processing unit 35 on a single substrate, while providing the port unit 36 and the decoding unit 37 on a single substrate, and the substrate unit (two substrates). In the above, each of the parts 35 to 37 may be configured to be independently separable (two divisions). That is, as illustrated in FIG. 6, the processing unit 35 may be provided on the processing substrate 38, and the port unit 36 and the decoding unit 37 may be provided on the control substrate 70. In addition, FIG. 6 is a schematic diagram illustrating connection modes of various components and various substrates of the pachinko machine 10. Even with such a configuration, the same effects as the effects (1) to (4) of the first embodiment can be obtained. Furthermore, for example, when the third actuator A3 is added or deleted by changing the specifications of the pachinko machine 10, only one control board 70 needs to be changed, and workability can be improved.
[0070]
In each of the above embodiments, the configuration of the port unit 36 may be configured with only the output ports P1 to P5. That is, the input port P6 may be omitted. In this case, the CPU 41 is configured such that the winning signals N1 to N7 are directly input via the winning ball information input circuit SC on the assumption that the CPU 41 has a function as an input port. Alternatively, the input port P6 may be provided in the processing unit 35 of the processing substrate 38.
[0071]
In each of the above embodiments, only the configuration of the main part that controls the processing of each unit 35 to 37, 60, 61 is provided on each substrate 38-40, 62, 63, but each substrate 38-40, 62, 63 is provided. In addition to the main parts of the respective parts 35 to 37, 60, 61, other structures (electronic parts) may be provided. In other words, the main control unit 34 may be formed so as to be independently separable in main part units (= substrate units on which main parts are provided) of the respective parts 35 to 37, 60, 61.
[0072]
In each of the above embodiments, the configuration for independently separating the main control unit 34 may be arbitrarily changed. For example, in each of the embodiments described above, the decoding unit 37 is further composed of a first decoding board on which the decoding circuit 44 and the selection circuits 46 to 49 are provided, and a second decoding board on which the decoding circuit 45 and the selection circuit 50 are provided. May be divided. In the second embodiment, the port portion 36 may be divided into three or four substrates.
[0073]
In each of the above embodiments, each port P1 to P6 performs only one of the input and output of various signals (control signals M1 to M5, winning signals N1 to N7). Instead of P1 to P6, an input / output port for inputting and outputting various signals may be used.
[0074]
In each of the above embodiments, the substrates are connected to each other by a predetermined signal line via the input side connector or the output side connector, but the connectors on each substrate may be directly connected.
[0075]
In each of the above embodiments, the configuration of main parts in the processing unit 35, the port unit 36, and the decoding unit 37 may be arbitrarily changed. For example, you may comprise the main part of the process part 35 by providing several ROM and RAM.
[0076]
-In the said 2nd Embodiment, you may change arbitrarily the kind of port provided in the 1st port part 60 and the 2nd port part 61. FIG. For example, the output port P5 to which the first and second actuators A1 and A2 are connected is provided in the first port portion 60, while the output port P7 to which the third actuator A3 is connected is provided in the second port portion 61. May be.
[0077]
Next, a technical idea that can be grasped from the embodiment and another example will be added below.
(A) A processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit outputs various signals, and a decoding unit that decodes an address signal from the processing unit and generates a predetermined signal The control unit includes the processing unit, the port unit, and the decoding unit divided into a plurality of substrates, and the processing unit, the port unit, and the decoding unit can be independently separated in units of the substrates. A gaming machine configured to be.
[0078]
(B) The port portion is provided with a plurality of output ports, and the port portion is provided with the output ports divided into a plurality of substrates, and the output ports can be independently separated in units of the substrates. The gaming machine according to the technical idea (b) configured to be.
[0079]
(C) The port unit is provided with a plurality of output ports, and each output port is connected to a control component controlled based on a control signal from the processing unit. The output ports are classified into a common port to which a common control component is connected to a gaming machine model and a dedicated port to which a dedicated control component is connected to a gaming machine model. In the technical idea (a) or (b), the common port and the dedicated port are provided separately on separate boards, and the common port and the dedicated port can be independently separated in units of the board. The gaming machine described.
[0080]
(D) The control means is configured such that the processing unit, the port unit, and the decoding unit are provided separately on different substrates, and the processing unit, the port unit, and the decoding unit can be independently separated in units of the substrate. The gaming machine according to claim 1 or the technical idea (A).
[0081]
(E) In the control means, the processing unit is provided on a single substrate, the port unit and the decoding unit are provided on a single substrate, and the processing unit, the port unit, and the decoding unit are provided for each substrate. The gaming machine according to claim 1 or the technical idea (b) configured to be independently separable.
[0082]
(F) The control means is a main control unit that controls the game in an integrated manner, and any one of the technical ideas (a), (b), and (c). The gaming machine described.
[0083]
(G) A processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit inputs and outputs various signals, and a decoder that decodes an address signal from the processing unit and generates a predetermined signal The control means includes a processing unit, a port unit, and a decoding unit in which main parts constituting the processing unit, the port unit, and the decoding unit are divided into a plurality of substrates. A gaming machine configured such that main parts constituting the unit can be independently separated.
[0084]
(H) A processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit outputs various signals, and a decoding unit that decodes an address signal from the processing unit and generates a predetermined signal The control means includes the processing unit, the port unit, and the decoding unit, the main parts constituting the processing unit, the port unit, and the decoding unit are divided into a plurality of substrates, and the processing unit, the port unit, and the decoding unit in units of the substrate. A gaming machine configured such that main parts constituting the can be separated independently.
[0085]
【The invention's effect】
According to the present invention, an increase in cost related to a gaming machine can be suppressed.
[Brief description of the drawings]
FIG. 1 is a front view showing a machine front side of a pachinko machine.
FIG. 2 is a rear view showing the back side of the pachinko machine.
FIG. 3 is a block diagram showing a specific configuration of a main control unit in the first embodiment.
Similarly, (a) is an enlarged view of a main part showing the connection mode between the input port and each sensor before the addition of the fifth prize opening sensor, and (b) is an input after the addition of the fifth prize opening sensor. The principal part enlarged view which shows the connection aspect of a port and each sensor.
FIG. 5 is a block diagram showing a specific configuration of a main control unit in the second embodiment.
FIG. 6 is a schematic diagram showing a configuration of a main control unit in another example.
[Explanation of symbols]
A1 ... first actuator as control component, A2 ... second actuator as control component, AC ... actuator circuit as control component, AS ... address signal, M1-M5 ... control signal as signal, N1-N7 ... signal ( Winning signals as detection results), P1 to P4: output ports as common ports (ports), P5: output ports as dedicated ports (ports), P6: input ports as dedicated ports (ports), S1: detection components S2 ... Count sensor as detection component, S3 ... Specific passage count sensor as detection component, S4 to S7 ... First to fourth winning port sensors as detection component, SC ... as detection component Prize ball information input circuit, SL1 to SL6 ... select signal as a predetermined signal, 10 ... pachinko game as a gaming machine 30 ... Symbol control board as a control part, 31 ... Lamp control board as a control part, 32 ... Dispensing control board as a control part, 33 ... Voice control board as a control part, 34 ... Main control unit as a control means 35 ... Processing unit, 36 ... Port unit, 37 ... Decoding unit, 38 ... Processing substrate as substrate, 39 ... Port substrate as substrate, 40 ... Decoding substrate as substrate, 62 ... First port substrate as substrate , 63 ... a second port board as a board, 70 ... a control board as a board.

Claims (3)

A processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit inputs and outputs various signals, and a decoding unit that decodes an address signal from the processing unit and generates a predetermined signal Comprising control means having
Wherein said control means includes a processing substrate provided with the processing unit, and the port substrate provided with said port portion, a plurality of substrates independent consisting decoding substrate provided with the decoding unit,
The processing board is connected to the port board in a state in which a signal from the port board can be input, and the port board is connected to the decoding board in a state in which a signal from the decoding board can be input, The decoding substrate is connected to the processing substrate in a state where a signal from the processing substrate can be input,
The processing substrate, the port circuit packs and the decoding substrate, without providing the connecting terminals unused, the processing unit by connecting the output side connector and the input-side connector provided in each substrate signal line, said port portion A gaming machine comprising: the decoding units connected in a state of being independently separable in units of boards , each board being housed in a single protective case in that state, and mounted on a machine body . A processing unit that executes predetermined arithmetic processing, an input port unit that is used when the processing unit inputs various signals, an output port unit that is used when the processing unit outputs various signals, and the processing unit A control unit having a decoding unit that decodes an address signal from and generates a predetermined signal,
The control means comprises a plurality of independent substrates including a processing substrate provided with the processing unit and the input port unit, a port substrate provided with the output port unit, and a decoding substrate provided with the decoding unit,
The decoding board is connected to the processing board in a state where a signal from the processing board can be input, and the port board is connected to the decoding board in a state where a signal from the decoding board can be input,
By connecting the output side connector and the input side connector provided on each substrate with signal lines without providing unused connection terminals, the processing unit, the input port, and the processing board, the port board, and the decode board are provided. And the output port unit and the decoding unit are connected in a state that can be independently separated in units of boards, and each board is accommodated in a single protective case and mounted on the machine body. . A processing unit that executes predetermined arithmetic processing, a port unit that is used when the processing unit inputs and outputs various signals, and a decoding unit that decodes an address signal from the processing unit and generates a predetermined signal Comprising control means having
The control means includes a plurality of independent substrates including a processing substrate provided with the processing unit, a port substrate provided with the port unit, and a decoding substrate provided with the decoding unit,
The processing board is connected to the port board in a state in which a signal from the port board can be input, and the port board is connected to the decoding board in a state in which a signal from the decoding board can be input, The decoding substrate is connected to the processing substrate in a state where a signal from the processing substrate can be input,
The processing board, the port board, and the decoding board can be connected to each other by connecting the output side connector and the input side connector provided on each board with signal lines without providing unused connection terminals. And the decoding unit is connected in a state that can be independently separated in units of substrates, each substrate is accommodated in a single protective case in that state, and is attached to the body,
The port section is provided with a plurality of ports, and each port can perform at least one of input and output of the various signals.
Each port is connected to at least one of a control component controlled based on a control signal from the processing unit and a detection component that detects a detection target and outputs the detection result to the processing unit. In addition, each port has a common port to which at least one of a control component and a detection component common to the gaming machine model is connected, and a dedicated control for the gaming machine model. It is classified as a dedicated port to which at least one of components and detection components is connected,
The port board provided with the port portion is divided into a first port board provided with the common port and a second port board provided with the dedicated port, and the common port and the dedicated port are independently separated on a board basis. Make it possible and
The decode unit includes a plurality of decode circuits and a plurality of select circuits, and each decode circuit and each select circuit are connected to the common port and a dedicated port connected to the dedicated port. Classified into circuits,
The decoding board provided with the decoding unit is divided into a first decoding board provided with the common circuit and a second decoding board provided with the dedicated circuit, and the common circuit and the dedicated circuit are independently separated on a board basis. A gaming machine characterized by being in a possible state .

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