JP2004344525A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game machine capable of increasing the degree of freedom for specification change or the like and effectively utilizing a display controller. <P>SOLUTION: This game machine is provided with output terminals TE1-TE4 of a first group connected to first switching circuits 22a-22d and output terminals TE5-TE12 of a second group connected to second switching circuits 22e-22m on a display control board 20a. A display means is connected to the output terminals TE1-TE4 in a first connection form or a second connection form and the display means is connected to the output terminals TE5-TE12 by a third connection form or a fourth connection form. By a display control circuit 21, the switching circuits 22a-22m are controlled on the basis of the connection form of the output terminals TE1-TE12. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a gaming machine provided with display means.
[0002]
[Prior art]
A gaming machine, for example, a pachinko machine, is provided with a main control device, a display control device, display means, and the like. Generally, the main control device is configured as a main control board, and the display control device is configured as a display control board. As the display means, a light emitting element (LED, 7-segment display, etc.) is used. In the gaming machine, for example, an effect corresponding to the gaming state and notification to the player are made using the display means.
The main control device includes a main control circuit, a storage circuit, and the like. The main control circuit outputs a command signal to the display control device based on input signals such as a start signal and a winning signal, a control program stored in the storage circuit, and the like.
The display control device is provided with a switching circuit (drive circuit) for turning on / off the display means, a display control circuit, and the like. The display control circuit controls on / off of the switching circuit based on a command signal input from the main control device.
The display means is connected to a switching circuit of the display control device by a dynamic lighting circuit or a static lighting circuit.
[0003]
One example of a display control device provided in a conventional gaming machine is shown in FIGS. (See Patent Document 1)
A conventional display control device (display control board) includes a driving IC 100. The driving IC 100 includes a predetermined number of input terminals and output terminals P00 to P32. The input terminal is provided with a terminal SE to which a mode switching signal for switching between “dynamic lighting mode” and “static lighting mode” is input.
When the display unit is to be lit statically, as shown in FIG. 10, a power supply is connected to the terminal SE of the driving IC 100 (set to the “H” level state), and the driving IC 100 is set to the “static lighting mode”. Then, a static lighting circuit is connected to one of the output terminals P00 to P32, for example, the output terminals P00 to P07. In this case, the display control means outputs a display control signal for static lighting to the driving IC 100. As a result, the display means is statically lit by the static lighting circuit connected to the output terminals P00 to P07 of the driving IC 100.
When the display means is to be dynamically lit, as shown in FIG. 11, the terminal SE of the driving IC 100 is connected to GND (to the “L” level state), and the driving IC 100 is set to the “dynamic lighting mode”. I do. Then, the common terminal of the dynamic lighting circuit is connected to one of the output terminals P16 to P23, and the data terminal of the dynamic lighting circuit is connected to one of the output terminals P24 to P32. In this case, the display control unit outputs a display control signal for dynamic lighting to the driving IC 100. As a result, the display means is dynamically lit by the dynamic lighting circuit in which the common terminal is connected to one of the output terminals P16 to P23 of the driving IC 100 and the data terminal is connected to one of the output terminals P24 to P32.
[0004]
[Patent Document 1]
Japanese Patent No. 286717
[0005]
[Problems to be solved by the invention]
In a conventional gaming machine, when the driving IC 100 provided in the display control device is set to the “static lighting mode”, only the static lighting circuit can be connected to the output terminal of the driving IC 100. When the driving IC 100 is set to the “dynamic lighting mode”, only the dynamic lighting circuit can be connected to the output terminal of the driving IC 100. For this reason, the degree of freedom for changing the specifications of the display device is low.
Further, the driving IC 100 is provided with a considerable number of output terminals (33 in FIG. 10 and FIG. 11, P00 to P32) so as to be able to cope with a change in the specification of the gaming machine. However, when setting the driving IC 100 to the static lighting mode, there is a specification in which the static lighting circuit is not connected to all of the output terminals P00 to P32 of the driving IC 100. Alternatively, when the driving IC 100 is set to the dynamic lighting mode, there is a specification in which the dynamic lighting circuit is not connected to all of the output terminals P16 to P32 of the driving IC 100. Further, when the driving IC 100 is set to the dynamic lighting mode, at least the output terminals P00 to P15 of the driving IC 100 are not used. That is, in the conventional gaming machine, the driving IC (display control device) cannot be effectively used.
Therefore, an object of the present invention is to provide a gaming machine that can increase the degree of freedom with respect to specification changes and the like and can effectively use a display control device.
[0006]
[Means for Solving the Problems]
A first invention of the present invention for solving the above-mentioned problem is a gaming machine as set forth in claim 1.
In the gaming machine according to claim 1, as the output terminal of the display control board, an output terminal of a first group to which a first switching circuit is connected and a second terminal to which a second switching circuit is connected. A group of output terminals is provided, a display means is connected to each output terminal of the first group in a first connection mode or a second connection mode, and a third group is connected to each output terminal of the second group. The display means is connected in the connection mode of (4) or the fourth connection mode, and the display control means controls the first and second connections based on the connection mode of the output terminals of the first group and the connection mode of the output terminals of the second group. Control the switching circuit.
Thus, each output terminal of the display control board can be connected to the display means in any one of the first to fourth connection modes. Therefore, the same display control board, that is, the same display control device, can easily cope with a change in specifications such as the number of display units and the display mode. In this case, it is necessary to change the software of the display control device in accordance with a change in specifications, but there is no need to change the display control board (hardware), which is advantageous in terms of cost and the like. Here, in the gaming machine, the display control board or the like may be required to undergo a test at a test institution or the like. By making it possible to respond to various specification changes without changing the display control board (hardware), it is not necessary to take a test of the display control board by a test institution etc. every time the specification is changed, and the time required for the specification change is reduced. It can be greatly reduced. Further, since all output terminals are connected to, for example, a static lighting circuit or a dynamic lighting circuit, a switching circuit or the like provided on the display control board can be effectively used. Furthermore, since no vacant terminal is generated at the output terminal of the display control board, it is possible to prevent an illegal signal from being input to the vacant terminal.
[0007]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 shows a schematic configuration diagram of an embodiment in which the present invention is configured as a pachinko machine.
The pachinko machine shown in FIG. 1 includes a main controller 10 and a display controller 20. Although not particularly shown, the main control device 10 includes a prize ball control device that controls a prize ball device that pays out a prize ball corresponding to the winning opening when a pachinko ball wins the winning opening, or a special winning opening. And a sound control device that controls a speaker that outputs sound for performance. The operation of the pachinko machine is controlled by each control device.
[0008]
Main controller 10 is usually configured as main control board 10a.
The main control board 10a is provided with a main control circuit 11 including a CPU, a storage unit 12 including a RAM, a ROM, and the like, an input terminal, an output terminal (not shown), and the like. A starting signal output from a starting ball detector that detects that a pachinko ball has passed through a starting gate or a winning opening, a winning signal output from a winning detector that detects that a pachinko ball has won a winning opening, and the like. Is input to the main control circuit 11 via the input terminal.
The storage means 12 of the main control device 10 stores a hit determination random number program for generating a hit determination random number, a control program, and the like.
The main control circuit 11 outputs a command signal to the display control device 20 and the like from an output terminal based on a start signal, a winning signal, a control program stored in the storage means, and the like.
[0009]
The display control device 20 is generally configured as a display control board 20a.
The display control board 20a is provided with a display control circuit (display control means) 21 including a CPU, switching circuits 22a to 22m, input terminals, and output terminals TE1 to TE12. The switching circuits 22a to 22m are connected to the output terminals TE1 to TE12 by a wiring pattern or the like.
Further, a display substrate 30a is provided. The display substrate 30a is provided with input terminals TL1 to TL12 and lighting circuits (for example, static lighting circuits and dynamic lighting circuits) connected to the input terminals TL1 to TL12. Display means such as LEDs (display means for static lighting or display means for dynamic lighting) is connected to the static lighting circuit or the dynamic lighting circuit. The input terminals TL1 to TL12 of the display board 30a are connected to the output terminals TE1 to TE12 of the display control board 20a.
In the following, “static lighting circuit” and “dynamic lighting circuit” are used as meaning lighting circuits including display means. Of course, a “static lighting circuit” or a “dynamic lighting circuit” can be used to mean a lighting circuit that does not include a display unit.
The display control circuit 21 outputs a display control signal to the switching circuits 22a to 22m based on the command signal output from the main control device 10. On / off control of the switching circuits 22a to 22m is performed based on the display control signal output from the display control circuit 21, so that the output terminals TE1 to TE12 of the display control board 20a and the input terminals TL1 to TL12 of the display board 30a. The lighting circuit (static lighting circuit or dynamic lighting circuit) connected to is controlled, and each display means (static lighting display means or dynamic lighting display means) is turned on / off.
[0010]
Details of the display control device 20 and the display device 30 according to the present embodiment will be described with reference to FIGS.
FIGS. 2 to 9 illustrate a case where an LED (light emitting diode) is used as the display means and the display means is controlled in a display mode of static lighting or dynamic lighting.
The display control board 20a of the present embodiment is provided with first switching circuits 22a to 22d, second switching circuits 22e to 22m, output terminals TE1 to TE12, and a GND terminal E1. First switching circuits 22a to 22d are connected to the output terminals TE1 to TE4, and second switching circuits 22e to 22m are connected to the output terminals TE5 to TE12.
In the present embodiment, a PNP transistor (a switching element of the first conductivity type) is used as the first switching circuits 22a to 22d. The emitter terminals of the PNP transistors are connected to each other by a wiring pattern or the like, and are connected to the LED power supply A. The collector terminal of each PNP transistor is connected to output terminals TE1 to TE4 (output terminals of the first group) by a wiring pattern or the like.
As the second switching circuits 22e to 22m, NPN transistors (second conductivity type switching elements) are used. The emitter terminals of the respective NPN transistors are connected to each other by a wiring pattern or the like, and are connected to a GND (ground) terminal E1. The collector terminal of each NPN transistor is connected to output terminals TE5 to TE12 (output terminals of the second group) by a wiring pattern or the like.
[0011]
(1) When 7 LEDs × 3 blocks of LEDs are dynamically lit
First, as shown in FIGS. 2 and 3, the seven-segment displays 31, 32, and 33 (three blocks each consisting of seven LEDs) are dynamically lit, and the two LEDs 34 and 35 are lit statically. The case will be described.
On the display substrate 30a, a dynamic lighting circuit for lighting LEDs constituting the three 7-segment displays 31, 32, 33, two static lighting circuits for statically lighting the LEDs 34 and 35, input terminals TL1 to TL12, The GND terminal EL1 is provided.
The seven-segment display 31 includes seven LEDs 311 to 317, a common terminal COM31, and data terminals 311K to 317K. The anodes of the LEDs 311 to 317 are connected to the common terminal COM31, and the cathodes are connected to the data terminals 311K to 317K.
The seven-segment display 32 includes seven LEDs 321 to 327, a common terminal COM32, and data terminals 321K to 327K. The anodes of the LEDs 321 to 327 are connected to the common terminal COM32, and the cathodes are connected to the data terminals 321K to 327K.
The seven-segment display 33 includes seven LEDs 331 to 337, a common terminal COM33, and data terminals 331K to 337K. The anodes of the LEDs 331 to 337 are connected to the common terminal COM33, and the cathodes are connected to the data terminals 331K to 337K.
The common terminal COM31 of the 7-segment display 31 is connected to the input terminal TL2, the common terminal COM32 of the 7-segment display 32 is connected to the input terminal TL3, and the common terminal COM33 of the 7-segment display 33 is connected to the input terminal TL4. ing. The data terminals 311K, 321K, and 331K of the 7-segment displays 31 to 33 are connected to the input terminal TL5, the data terminals 312K, 322K, and 332K are connected to the input terminal TL6, and the data terminals 313K, 323K, and 333K are input terminals. TL7, the data terminals 314K, 324K, 334K are connected to the input terminal TL8, the data terminals 315K, 325K, 335K are connected to the input terminal TL9, and the data terminals 316K, 326K, 336K are connected to the input terminal TL10, The data terminals 317K, 327K, 337K are connected to the input terminal TL11.
In the present embodiment, by connecting the common terminals 31 to 33 to the input terminals TL2 to TL4, the input terminals TL2 to TL4 are connected to the “common side” of the dynamic lighting circuit. Further, by connecting the data terminals 311K to 317K, 321K to 327K, and 331K to 337K to the input terminals TL5 to TL11, the TL5 to TL11 are connected to the “data side” of the dynamic lighting circuit. The dynamic lighting circuit includes seven-segment displays 31, 32, and 33.
The anode of the LED 34 is connected to the input terminal TL1, and the cathode is connected to the GND terminal EL1.
The cathode of the LED 35 is connected to the input terminal TL12, and the anode is connected to the LED power supply B.
In the present embodiment, a static lighting circuit is configured by a circuit between the input terminal TL1 and the GND terminal or between the input terminal TL12 and the LED power supply B.
[0012]
Further, the GND terminal E1 of the display control board 20a is connected to the terminal EL1 of the display board 30a by wiring or the like. The output terminals TE1 to TE12 of the display control board 20a are connected to the input terminals TL1 to TL12 of the display board 30a by wiring and the like, respectively. For example, they are connected by a cable with a connector.
Thus, the collector of the first switching circuit 22a is connected to the anode side of the LED 34 via the output terminal TE1 of the display control board 20a and the input terminal TL1 of the display board 30a. That is, the output terminal TE1 is connected to the static lighting circuit having the LED 34 in the first connection mode.
The collector of the first switching circuit 22b is connected to the common terminal COM31 of the 7-segment display 31 via the output terminal TE2 of the display control board 20a and the input terminal TL2 of the display board 30a. Similarly, the first switching circuits 22c and 22d are connected to the common terminals COM32 and COM33 of the seven-segment displays 32 and 33, respectively. That is, the output terminals TE2 to TE4 are connected to the common terminals COM31 to COM33 of the seven-segment displays 31, 32, and 33 in the second connection mode.
The collector of the second switching circuit 22e is connected to the data terminal 311K of the seven-segment display 31, the data terminal 321K of the seven-segment display 32, via the output terminal TE5 of the display control board 20a and the input terminal TL5 of the display board 30a. It is connected to the data terminal 331K of the 7-segment display 33. Similarly, the second switching circuits 22f to 22k are similarly connected to the data sides of the seven-segment displays 32, 33, and 34, respectively. That is, the output terminals TE5 to TE12 are connected to the data terminals 311K to 317K, 321K to 327K, 331K to 337K of the 7-segment displays 31, 32, and 33 in the fourth connection mode.
The collector of the second switching circuit 22m is connected to the cathode of the LED 35 via the output terminal TE12 of the display control board 20a and the input terminal TL12 of the display board 30a. That is, the output terminal TE12 is connected to the static lighting circuit having the LED 35 in the third connection mode.
When LEDs (display means) are connected to the output terminals TE1 to TE12 of the display control board 20a as shown in FIG. 2, 21 LEDs (each LED of a 7-segment display × 3 sets) are used in a dynamic lighting circuit; The two LEDs can be turned on / off by a static lighting circuit.
[0013]
FIG. 2 illustrates the case where the static lighting circuit and the dynamic lighting circuit are provided on the same display substrate 30a. However, the static lighting circuit and the dynamic lighting circuit are provided on separate display substrates or the like. May be. Further, for example, the static lighting circuit connected to the output terminal TE1 and the static lighting circuit connected to the output terminal TE12 may be provided on separate display boards or the like.
Further, in the present embodiment, the static lighting circuit and the dynamic lighting circuit are provided on the display substrate, but may not be provided on the display substrate.
[0014]
In such a connected state, the display control circuit 21 controls on / off of the switching circuits 22a to 22m based on the connection mode of the output terminals TE1 to TE12. When the switching circuits 22a to 22m are turned on / off, the signals shown in FIG. 3A are output to the output terminals TE1 to TE12. Thereby, as shown in FIG. 3B, the LEDs 311 to 317, 321 to 327, and 331 to 337 constituting the 7-segment displays 31, 32, and 33 are dynamically turned on, and the LEDs 34 and 35 are statically turned on. Is done. In FIG. 3B, a black part indicates a lighting state, and a white part indicates a non-lighting state. Here, the vertical axis of the timing chart shown in FIG. 3A does not indicate the level of the voltage or the current, but indicates the transition of the state of “ON” or “OFF”.
As in the present embodiment, when the first switching circuits 22a to 22d connected to the first group of output terminals TE1 to TE4 are PNP transistors, the first group of output terminals TE1 to TE4. In a state where the output of TE4 is “ON”, the output terminals TE1 to TE4 of the first group are connected to the LED power supply A. In a state where the outputs of the output terminals TE1 to TE4 of the first group are “OFF”, the output terminals TE1 to TE4 of the first group are opened. When the second switching circuits 22e to 22m connected to the output terminals TE5 to TE12 of the second group are NPN transistors, the outputs of the output terminals TE5 to TE12 of the second group are turned on. ", The output terminals TE5 to TE12 of the second group are connected to GND. In a state where the outputs of the output terminals TE5 to TE12 of the second group are “OFF”, the output terminals TE5 to TE12 of the second group are opened.
[0015]
The output of the output terminal TE1 is controlled to be "off" at times t0 to t3 and "on" at times t3 to t9. That is, from time t3 to t9, the output of the output terminal TE1 is turned “on”, and a current flows from the output terminal TE1 → the input terminal TL1 → the LED34 → GND, so that the LED34 is “lit”. Note that the LED 34 is “off” between times t0 and t3.
The output of the output terminal TE12 is controlled to be "off" at times t0 to t6 and "on" at times t6 to t9. That is, from time t6 to t9, the output of the output terminal TE12 is turned “on”, a current flows from the LED power supply B → LED35 → input terminal TL12 → output terminal TE12, and the LED 35 is turned on. Note that the LED 35 is "off" between times t0 and t6.
[0016]
The outputs of the output terminals TE2 to TE4 are connected to the common side of a dynamic lighting circuit that dynamically lights the seven-segment displays 31, 32, and 33. Then, the output of the output terminal TE2 is turned “on” between times t0 and t1, the output of the output terminal TE3 is turned “on” between times t1 and t2, and the output of the output terminal TE4 is turned “on” between times t2 and t3. . This is repeated as one cycle.
The outputs of the output terminals TE5 to TE11 are connected to the data side of a dynamic lighting circuit that dynamically lights the seven-segment displays 31, 32, and 33. Then, the output of the output terminal TE5 is “off” between times t0 and t1, and “on” between times t1 and t2 and between times t2 and t3. This is repeated as one cycle. The output of the output terminal TE6 is "OFF" between times t0 and t3. This is repeated as one cycle. The output of the output terminal TE7 is “off” between times t0 and t1, “on” between times t1 and t2, and “off” between times t2 and t3. This is repeated as one cycle. The output of the output terminal TE8 is "off" between times t0 and t1, "on" between times t1 and t2, and "on" between times t2 and t3. This is repeated as one cycle. The output of the output terminal TE9 is “on” between times t0 and t1, “off” between times t1 and t2, and “on” between times t2 and t3. This is repeated as one cycle. The output of the output terminal TE10 is "ON" during the time t0 to t3. This is repeated as one cycle. The output of the output terminal TE11 is "off" between times t0 and t1, "on" between times t1 and t2, and "on" between times t2 and t3. This is repeated as one cycle.
[0017]
Thus, in the 7-segment display 31, when the output of the output terminal TE2 is "ON", the LEDs 311 to 317 corresponding to the outputs of the output terminals TE5 to TE11 are turned on. For example, between times t0 and t1, the output of the output terminal TE2 is “ON”, the outputs of the output terminals TE9 and TE10 are “ON”, and the outputs of the output terminals TE5, TE6, TE7, TE8 and TE11 are “OFF”. . As a result, during the period from time t0 to t1, a current flows from the output terminal TE2 to the input terminal TL2, the LED 315 of the 7-segment display 31, the input terminal TL9, and the output terminal TE9, and the LED 315 is turned on. Further, current flows from the output terminal TE2 to the input terminal TL2, the LED 316 of the 7-segment display 31, the input terminal TL10, and the output terminal TE10, and the LED 316 is turned on. That is, “1” is displayed on the 7-segment display 31 between times t0 and t1.
In the 7-segment display 32, when the output of the output terminal TE3 is "ON", the LEDs 321 to 327 corresponding to the outputs of the output terminals TE5 to TE11 are turned on. For example, between times t1 and t2, the output of the output terminal TE3 is “ON”, the outputs of the output terminals TE5, TE7, TE8, TE10, TE11 are “ON”, and the outputs of the output terminals TE6 and TE9 are “OFF”. . Thus, between times t1 and t2, current flows from the output terminal TE3 to the input terminal TL3, the LED 321 of the 7-segment display 32, the input terminal TL5, and the output terminal TE5, and the LED 321 is turned on. Further, current flows from the output terminal TE3 to the input terminal TL3, the LED 323 of the 7-segment display 32, the input terminal TL7, and the output terminal TE7, and the LED 323 is turned on. Further, a current flows from the output terminal TE3 to the input terminal TL3, the LED 324 of the 7-segment display 32, the input terminal TL8, and the output terminal TE8, and the LED 324 is turned on. Further, current flows from the output terminal TE3 to the input terminal TL3, the LED 326 of the 7-segment display 32, the input terminal TL10, and the output terminal TE10, and the LED 326 is turned on. Further, current flows from the output terminal TE3 to the input terminal TL3, the LED 327 of the 7-segment display 32, the input terminal TL11, and the output terminal TE11, and the LED 327 is turned on. That is, between the times t1 and t2, “2” is displayed on the 7-segment display 32.
In the 7-segment display 33, when the output of the output terminal TE4 is "ON", the LEDs 331 to 337 corresponding to the outputs of the output terminals TE5 to TE11 are turned on. For example, between times t2 and t3, the output of the output terminal TE4 is “ON”, the outputs of the output terminals TE5, TE8, TE9, TE10, and TE11 are “ON”, and the outputs of the output terminals TE6 and TE7 are “OFF”. . Thus, between time t2 and time t3, current flows from the output terminal TE4 to the input terminal TL4, the LED 331 of the 7-segment display 33, the input terminal TL5, and the output terminal TE5, and the LED 331 is turned on. Further, current flows from the output terminal TE4 to the input terminal TL4, the LED 334 of the 7-segment display 33, the input terminal TL8, and the output terminal TE8, and the LED 334 is turned on. Further, current flows from the output terminal TE4 to the input terminal TL4, the LED 335 of the 7-segment display 33, the input terminal TL9, and the output terminal TE9, and the LED 335 is turned on. Further, a current flows from the output terminal TE4 to the input terminal TL4, the LED 336 of the 7-segment display 33, the input terminal TL10, and the output terminal TE10, and the LED 336 is turned on. Further, current flows from the output terminal TE4 to the input terminal TL4, the LED 337 of the 7-segment display 33, the input terminal TL11, and the output terminal TE11, and the LED 337 is turned on. That is, between time t2 and t3, “3” is displayed on the seven-segment display 33.
The on / off control between times t0 and t3 is continuously repeated as one cycle. One cycle is, for example, about several milliseconds. Therefore, the seven-segment displays 31, 32, and 33 appear to display "1", "2", and "3" continuously.
When changing the display contents of the 7-segment displays 31, 32, and 33, the outputs of the output terminals TE5 to TE11, that is, the outputs to the data side of the dynamic lighting circuit are changed to outputs corresponding to the display to be changed. You just need to switch.
[0018]
In the timing chart shown in FIG. 3A, there is a timing chart in which a delay time is provided when the output of each output terminal is turned on. For example, the output of the output terminal TE9 is "on" at times t0 to t1, but is "on" after a predetermined time has elapsed from time t0. This delay time is for avoiding the influence of simultaneous conduction of the LEDs provided in different seven-segment displays, and may be omitted when it is not necessary to consider the influence of simultaneous conduction.
Further, the second switching circuit may be connected to the output terminals of the first group, and the first switching circuit may be connected to the output terminals of the second group. For example, a PNP transistor may be connected to the data side of the dynamic lighting circuit, and an NPN transistor may be connected to the common side of the dynamic lighting circuit and the static lighting circuit.
[0019]
(2) When 7 LEDs × 4 blocks of LEDs are dynamically lit
Next, as shown in FIGS. 4 and 5, the 7-segment displays 31, 32, 33, and 36 (four blocks each consisting of seven LEDs) are dynamically lit, and one LED 35 is statically lit. The following describes a case in which this is performed.
The configuration of the display control board 20a is the same as that shown in FIGS.
The configuration of the display substrate 30a differs from the display substrate shown in FIGS. 2 and 3 in the following points. That is, as shown in FIGS. 4 and 5, when four sets of seven-segment displays are used, for example, the output terminals of the first group connected to the static lighting circuit are added to the seven-segment displays. 36 common side. In the present embodiment, the output terminal TE1 of the first group to which the static lighting circuit is connected in the display substrate shown in FIGS. 2 and 3 is connected to the common side of the additional 7-segment display 36. . The data terminal of the 7-segment display 36 to be added is connected to the output terminals TE5 to TE12 of the second group to which the data terminals of the other 7-segment displays 31 to 33 are connected.
[0020]
The display substrate 30a is provided with four 7-segment displays 31, 32, 33, and 36, an LED 35, input terminals TL1 to TL12, and a GND terminal EL1.
The configuration of the 7-segment displays 31 to 33 and the LED 35 and the connection with the output terminal are the same as those shown in FIGS.
The seven-segment display 36 includes seven LEDs 361 to 367, a common terminal COM36, and data terminals 361K to 367K. The anodes of the LEDs 361 to 367 are connected to the common terminal COM36, and the cathodes are connected to the data terminals 361K to 367K. The common terminal COM36 of the seven-segment display 36 is connected to the input terminal TL1. The data terminal 361K of the 7-segment display 36 is connected to the input terminal TL5, the data terminal 362K is connected to the input terminal TL6, the data terminal 363K is connected to the input terminal TL7, and the data terminal 364K is connected to the input terminal TL8. The data terminal 365K is connected to the input terminal TL9, the data terminal 366K is connected to the input terminal TL10, and the data terminal 367K is connected to the input terminal TL11.
[0021]
Further, the GND terminal E1 of the display control board 20a is connected to the terminal EL1 of the display board 30a by wiring or the like. The output terminals TE1 to TE12 of the display control board 20a are connected to the input terminals TL1 to TL12 of the display board 30a by wiring and the like, respectively. For example, they are connected by a cable with a connector.
Thereby, the collector of the first switching circuit 22a is connected to the common terminal COM36 of the 7-segment display 36 via the output terminal TE1 of the display control board 20a and the input terminal TL1 of the display board 30a. That is, the output terminal TE1 is connected to the common terminal COM36 (common terminal of the dynamic lighting circuit) of the 7-segment display 36 in the second connection mode.
When a display means is connected to the output terminals TE1 to TE12 of the display control board 20a as shown in FIG. 4, 28 LEDs (each LED of a 7-segment display × 4 sets) of a dynamic lighting circuit and a static lighting circuit Control of turning on / off one LED.
[0022]
In such a connected state, the display control circuit 21 controls on / off of the switching circuits 22a to 22m based on the connection mode of the output terminals TE1 to TE12. Outputs of the output terminals TE1 to TE12 by turning on / off the switching circuits 22a to 22m are shown in FIG. As a result, as shown in FIG. 5D, the LEDs 311-317, 321-327, 331-337, 361-368 constituting the 7-segment displays 31, 32, 33, 36 are dynamically turned on, and the LED 35 is turned on. Are statically controlled.
[0023]
The output of the output terminal TE12 is controlled to be "off" at times t0 to t6 and "on" at times t6 to t9. That is, during the period from time t6 to time t9, the output of the output terminal TE12 is turned “ON”, and a current flows from the LED power supply B → LED35 → input terminal TL12 → output terminal TE12, and the LED 35 is turned on. Note that the LED 35 is "off" between times t0 and t6.
[0024]
Outputs of the output terminals TE1 to TE4 are connected to a common terminal of a dynamic lighting circuit that dynamically lights the seven-segment displays 31, 32, 33, and 36. Then, the output of the output terminal TE2 is turned on between times t0 and t1, the output of the output terminal TE3 is turned on between times t1 and t2, and the output of the output terminal TE4 is turned on between times t2 and t2 '. , The output of the output terminal TE1 is turned “on” between times t2 ′ and t3. This is repeated as one cycle.
Outputs of the output terminals TE5 to TE11 are connected to data terminals of a dynamic lighting circuit that dynamically lights the seven-segment displays 31, 32, and 33. The output of the output terminal TE5 is "off" between times t0 and t1, "on" between times t1 and t2 and between times t2 and t2 ', and "off" between times t2' and t3. This is repeated as one cycle. The output of the output terminal TE6 is "off" between times t0 and t2 'and "on" between times t2' and t3. This is repeated as one cycle. The output of the output terminal TE7 is “off” between times t0 and t1, “on” between times t1 and t2, and “off” between times t2 and t3. This is repeated as one cycle. The output of the output terminal TE8 is “off” between times t0 and t1, “on” between times t1 and t2 ′, and “on” between times t2 ′ and t3. This is repeated as one cycle. The output of the output terminal TE9 is “on” between times t0 and t1, “off” between times t1 and t2, and “on” between times t2 and t3. This is repeated as one cycle. The output of the output terminal TE10 is "on" during the time t0 to t3. This is repeated as one cycle. The output of the output terminal TE11 is "off" between times t0 and t1, "on" between times t1 and t2, and "on" between times t2 and t3. This is repeated as one cycle.
[0025]
As a result, “1” is displayed on the 7-segment display 31 at times t0 to t1 as in the case shown in FIG. 3, and “2” is displayed on the 7-segment display 32 at times t1 to t2. "3" is displayed at time t2 to t2 '.
In the 7-segment display 36, when the output of the output terminal TE1 is "ON", the LEDs 361 to 167 corresponding to the outputs of the output terminals TE5 to TE11 are turned on. For example, between times t2 ′ and t3, the output of the output terminal TE1 is “ON” (the output voltage is at “H” level), and the output of the output terminals TE6, 9, 10, and 11 is “ON” (the output voltage is “L”). "Level", the outputs of the output terminals TE5, 7, 8 are "off". As a result, during the period from time t2 ′ to t3, current flows from the output terminal TE1 → the input terminal TL1 → the LED 362 of the 7-segment display 36 → the input terminal TL6 → the output terminal TE6, and the LED 362 is turned on. Further, a current flows from the output terminal TE1 to the input terminal TL1 to the LED 365 of the 7-segment display 36 to the input terminal TL9 to the output terminal TE9, and the LED 365 is turned on. Further, current flows from the output terminal TE1 to the input terminal TL1 to the LED 366 of the 7-segment display 36 to the input terminal TL10 to the output terminal TE10, and the LED 366 is turned on. Also, current flows from the output terminal TE1 to the input terminal TL1 to the LED 367 of the 7-segment display 36 to the input terminal TL11 to the output terminal TE11, and the LED 367 is turned on. That is, “4” is displayed on the 7-segment display 36 between times t2 ′ and t3.
The on / off control between times t0 and t3 is continuously repeated as one cycle. One cycle is, for example, about several milliseconds. Therefore, the seven-segment displays 31, 32, 33, and 36 appear to display "1", "2", "3", and "4" continuously.
[0026]
(3) Dynamic lighting of 7 x 2 block LEDs
Next, as shown in FIGS. 6 and 7, the 7-segment displays 31 and 32 (two blocks each consisting of seven LEDs) are dynamically lit, and the three LEDs 34, 35 and 37 are statically lit. The following describes a case in which this is performed.
The configuration of the display control board 20a is the same as that shown in FIGS.
The configuration of the display substrate 30a differs from the display substrate shown in FIGS. 2 and 3 in the following points. That is, as shown in FIGS. 6 and 7, when two sets of 7-segment displays are used, for example, the output terminals of the first group connected to the common side of the dynamic lighting circuit are replaced with static lighting circuits. Connect to In the present embodiment, a static lighting circuit is connected to the output terminal TE2 of the first group connected to the common side of the dynamic lighting circuit in the display substrate shown in FIGS.
[0027]
On the display substrate 30a, two 7-segment displays 31, 32, LEDs 34, 35, 37, input terminals TL1 to TL12, and a GND terminal EL1 are provided.
The configuration of the 7-segment displays 31, 32 and the LEDs 34, 35 and the connection with the output terminals are the same as those shown in FIGS.
The anode of the LED 37 is connected to the input terminal TL2, and the cathode is connected to the GND terminal EL1.
[0028]
Further, the GND terminal E1 of the display control board 20a is connected to the terminal EL1 of the display board 30a by wiring or the like. The output terminals TE1 to TE12 of the display control board 20a are connected to the input terminals TL1 to TL12 of the display board 30a by wiring and the like, respectively. For example, they are connected by a cable with a connector.
Thus, the collector of the first switching circuit 22b is connected to the anode side of the LED 37 via the output terminal TE2 of the display control board 20a and the input terminal TL2 of the display board 30a. That is, the output terminal TE2 is connected to the static lighting circuit having the LED 37 in the first connection mode.
When display means is connected to the output terminals TE1 to TE12 of the display control board 20a as shown in FIG. 6, 14 LEDs (each LED of a 7-segment display × 2) in a dynamic lighting circuit and a static lighting circuit Can control the turning on / off of the three LEDs.
[0029]
In such a connected state, the display control circuit 21 controls on / off of the switching circuits 22a to 22m based on the connection mode of the output terminals TE1 to TE12. By turning on / off the switching circuits 22a to 22m, the outputs of the output terminals TE1 to TE12 become as shown in FIG. Thus, as shown in FIG. 7F, the LEDs 311 to 317 and 321 to 327 constituting the 7-segment displays 31 and 32 are dynamically turned on and the LEDs 34, 35 and 37 are statically turned on.
The output of the output terminal TE2 is "off" at times t0 to t9. Thus, the LED 37 is turned off at times t0 to t9.
[0030]
The outputs of the output terminals TE3 and TE4 are connected to the common side of a dynamic lighting circuit that dynamically lights the seven-segment displays 31 and 32. Then, the output of the output terminal TE3 is turned on between times t0 and t1, and the output of the output terminal TE4 is turned on between times t1 and t3. This is repeated as one cycle.
Outputs of the output terminals TE5 to TE11 are connected to data terminals of a dynamic lighting circuit that dynamically lights the seven-segment displays 31 and 32. Then, the output of the output terminal TE5 is “off” between times t0 and t1, and “on” between times t1 and t3. This is repeated as one cycle. The output of the output terminal TE6 is turned off between times t0 and t3. This is repeated as one cycle.
The output of the output terminal TE7 is “off” between times t0 and t1, and “on” between times t1 and t3. This is repeated as one cycle. The output of the output terminal TE8 is “off” between times t0 and t1, and “on” between times t1 and t3. This is repeated as one cycle. The output of the output terminal TE9 is “on” between times t0 and t1, and “off” between times t1 and t3. This is repeated as one cycle. The output of the output terminal TE10 is "on" during the time t0 to t3. This is repeated as one cycle. The output of the output terminal TE11 is "off" between times t0 and t1, and "on" between times t1 and t3. This is repeated as one cycle.
[0031]
As shown in FIG. 3, “1” is displayed on the seven-segment displays 31 and 32 at times t0 to t1, and “2” is displayed on the seven-segment display 32 at times t1 to t3. The on / off control between times t0 and t3 is continuously repeated as one cycle. One cycle is, for example, about several milliseconds. Therefore, it appears that the seven-segment displays 31 and 32 continuously display “1” and “2”.
[0032]
(4) When dynamically illuminating 6 x 3 block LEDs
Next, as shown in FIGS. 8 and 9, a case will be described in which six LEDs are used as one block, three blocks are dynamically lit, and three LEDs are statically lit.
The configuration of the display control board 20a is the same as that shown in FIGS.
The configuration of the display control board 20a is the same as that shown in FIGS.
The configuration of the display substrate 30a differs from the display substrate shown in FIGS. 2 and 3 in the following points. That is, as shown in FIGS. 8 and 9, when three blocks are dynamically lighted with six LEDs as one block, for example, the output terminals of the second group connected to the dynamic lighting circuit are Connect to static lighting circuit.
[0033]
On the display substrate 30a, LEDs 34, 35, 38, 411 to 416, 421 to 426, 431 to 436, input terminals TL1 to TL12, and a GND terminal EL1 are provided.
Each anode side of the LEDs 411 to 416 of the first block is connected to the input terminal TL2. Each anode side of the LEDs 421 to 426 of the second block is connected to the input terminal TL3. Each anode side of the LEDs 431 to 436 of the third block is connected to the input terminal TL4. Thus, the common side of the dynamic lighting circuit having the LEDs 411 to 416, 421 to 426, and 431 to 436 of the first, second, and third blocks is connected to the input terminals TL2 to TL4.
The cathode side of the LEDs 411, 421, 431 is connected to the input terminal TL5. The cathode side of the LEDs 412, 422, 432 is connected to the input terminal TL6. The cathode side of the LEDs 413, 423, 433 is connected to the input terminal TL7. The cathode side of the LEDs 414, 424, 434 is connected to the input terminal TL8. The cathode side of the LEDs 415, 425, 435 is connected to the input terminal TL9. The cathode side of the LEDs 416, 426, 436 is connected to the input terminal TL10. Thereby, the data side of the dynamic lighting circuit having the LEDs 411 to 416, 421 to 426, and 431 to 436 of the first, second, and third blocks is connected to the input terminals TL5 to TL10.
The anode side of the LED 34 is connected to the input terminal TL1. The cathode side is connected to GND.
The cathode sides of the LEDs 35 and 38 are connected to the input terminals TL12 and TL11. The anode side is connected to the LED power supply B.
[0034]
Further, the GND terminal E1 of the display control board 20a is connected to the GND terminal EL1 of the display board 30a by wiring or the like. The output terminals TE1 to TE12 of the display control board 20a are connected to the input terminals TL1 to TL12 of the display board 30a by wiring and the like, respectively. For example, they are connected by a cable with a connector.
Thus, the collector of the first switching circuit 22a is connected to the anode side of the LED 34 via the output terminal TE1 of the display control device 20 and the input terminal TL1 of the display substrate 30a. That is, the output terminal TE1 is connected to the static lighting circuit that statically lights the LED 34 in the first connection mode.
The collector of the first switching circuit 22b is connected to the anode side of the LEDs 411 to 416 via the output terminal TE2 of the display control board 20a and the input terminal TL2 of the display board 30a. Similarly, the first switching circuits 22c and 22d are similarly connected to the anodes of the LEDs 421 to 426 and the LEDs 431 to 436, respectively. That is, the output terminals TE2 to TE4 are connected to the common terminal of the dynamic lighting circuit having the LEDs 411 to 416, the LEDs 421 to 426, and the LEDs 431 to 436 in the second connection mode.
The collector of the second switching circuit 22e is connected to the cathode side of the LEDs 411, 421, 431 via the output terminal TE5 of the display control board 20a and the input terminal TL5 of the display board 30a. Similarly, each of the second switching circuits 22f to 22j is connected to the cathode side of the corresponding LED. That is, the output terminals TE5 to TE10 are connected to the data terminals of the dynamic lighting circuit having the LEDs 411 to 416, the LEDs 421 to 426, and the LEDs 431 to 436 in the fourth connection mode.
The collector of the second switching circuit 22k is connected to the cathode side of the LED 38 via the output terminal TE11 of the display control board 20a and the input terminal TL11 of the display board 30a. That is, the output terminal TE11 is connected to the static lighting circuit having the LED 38 in the third connection mode.
The collector of the second switching circuit 22m is connected to the cathode side of the LED 35 via the output terminal TE12 of the display control board 20a and the input terminal TL12 of the display board 30a. That is, the output terminal TE12 is connected to the static lighting circuit having the LED 35 in the third connection mode.
When display means are connected to the output terminals TE1 to TE12 of the display control board 20a as shown in FIG. 8, 18 (6 × 3 blocks) display means in the dynamic lighting circuit and three display means in the static lighting circuit are used. The display means can be turned on / off.
[0035]
In such a connected state, the display control circuit 21 controls on / off of the switching circuits 22a to 22m based on the connection mode of the output terminals TE1 to TE12. When the switching circuits 22a to 22m are turned on / off, the signals shown in FIG. 9G are output to the output terminals TE1 to TE12. As a result, as shown in FIG. 9H, the LEDs 411 to 416, 421 to 426, and 431 to 436 of the first, second, and third blocks are dynamically turned on, and the LEDs 34, 35, and 38 are statically turned on. Controlled.
The outputs of the output terminals TE1 to TE10 and TE12 are the same as the outputs shown in FIG.
The output of the output terminal TE11 is controlled to be “off” between times t0 and t6 and “on” between times t6 and t9. That is, between times t6 and t9, the output of the output terminal TE11 is turned “on”, and a current flows from the LED power supply B → the LED38 → the input terminal TL11 → the output terminal TE11, so that the LED 38 is turned on. Note that the LED 38 is "off" between times t0 and t6.
A current flows through the LED 38 connected to the output terminal TE11 (via the wiring pattern and the input terminal TL11). Thus, the LED 38 is turned off at times t0 to t6 and turned on at times t6 to t9.
[0036]
In the LEDs 411 to 416 of the first block, when the output of the output terminal TE2 is “ON”, the LEDs 411 to 416 corresponding to the outputs of the output terminals TE5 to TE10 are turned on. For example, between times t0 and t1, the output of the output terminal TE2 is “on” (the output voltage is at the “H” level), the outputs of the output terminals TE5, 6, 7, and 8 are “off”, and the output terminals TE9 and The output light-on / light-off control signal is “on” (output voltage is “L” level). As a result, a current flows from the output terminal TE2 to the input terminal TE2, the LED 415, the input terminal TL9, and the output terminal TE9 between times t0 and t1, and the LED 415 is turned on. Further, current flows from the output terminal TE2 → the input terminal TE2 → the LED 416 → the input terminal TL10 → the output terminal TE10, and the LED 416 is turned on.
In the LEDs 421 to 426 of the second block, when the output of the output terminal TE3 is “ON”, the LEDs 421 to 426 corresponding to the outputs of the output terminals TE5 to TE10 are turned on. For example, between times t1 and t2, the output of the output terminal TE3 is “ON” (the output voltage is at “H” level), and the output of the output terminals TE5, 7, 8, and 10 is “ON” (the output voltage is “L”). Level) and the outputs of the output terminals TE6 and TE9 are "OFF". Thus, between times t1 and t2, current flows from the output terminal TE3 to the input terminal TE3, the LED 421, the input terminal TL5, and the output terminal TE5, and the LED 421 is turned on. Further, current flows from the output terminal TE3 → the input terminal TE3 → the LED 423 → the input terminal TL7 → the output terminal TE7, and the LED 423 is turned on. Further, current flows from the output terminal TE3 → the input terminal TE3 → the LED 424 → the input terminal TL8 → the output terminal TE8, and the LED 424 is turned on. Further, current flows from the output terminal TE3 → the input terminal TE3 → the LED 426 → the input terminal TL10 → the output terminal TE10, and the LED 426 is turned on.
In the LEDs 431 to 436 of the third block, when the output of the output terminal TE4 is “ON”, the LEDs 431 to 436 corresponding to the outputs of the output terminals TE5 to TE10 are turned on. For example, between times t2 and t3, the output of the output terminal TE4 is "ON", the outputs of the output terminals TE5, 8, 9, 10 are "ON", and the outputs of the output terminals TE6, 7 are "OFF". Thus, between time t2 and t3, current flows from the output terminal TE4 to the input terminal TE4, the LED 431, the input terminal TL5, and the output terminal TE5, and the LED 431 is turned on. Further, a current flows from the output terminal TE4 to the input terminal TE4, the LED 434, the input terminal TL8, and the output terminal TE8, and the LED 434 is turned on. Further, current flows from the output terminal TE4 → the input terminal TE4 → the LED 435 → the input terminal TL9 → the output terminal TE9, and the LED 435 is turned on. Further, current flows from the output terminal TE4 to the input terminal TE4, the LED 436, the input terminal TL10, and the output terminal TE10, and the LED 436 is turned on.
The on / off control between times t0 and t3 is continuously repeated as one cycle. One cycle is, for example, about several milliseconds. Therefore, the LEDs 415, 416, 421, 423, 424, 426, 431, 434, 435, and 436 appear to be continuously lit.
[0037]
As described above, in the gaming machine of the present embodiment, for example, in the first connection mode, the static lighting circuit is used in response to a specification change that increases the number of blocks of the display means constituted by the same number of display means. Can be handled by connecting the output terminals of the first group connected to the common lighting circuit to the common side of the dynamic lighting circuit in the second connection mode.
Further, for a specification change that reduces the number of blocks of the display means constituted by the same number of display means, for example, the first group connected to the common side of the dynamic lighting circuit in the second connection mode Is connected to the static lighting circuit in the first connection mode.
Further, in response to a specification change that increases the number of display units constituting a block used in the dynamic lighting circuit (for example, seven to eight), for example, the static connection circuit is changed to the third connection mode. This can be dealt with by connecting the output terminals of the connected second group to the data side of the dynamic lighting circuit in the fourth connection mode.
In addition, for a specification change that reduces the number of display means constituting a block used for dynamic lighting (for example, seven to six), for example, the data of the dynamic lighting circuit may be changed in the fourth connection mode. This can be handled by connecting the output terminals of the second group connected to the side to the static lighting circuit in the third connection mode.
Further, when increasing or decreasing the number of display means constituting a block used for dynamic lighting and increasing or decreasing the number of blocks, it is possible to cope with this by combining the above-mentioned methods.
Therefore, the degree of freedom for changing the specifications is increased.
Thus, the same display control board, that is, the same display control device can easily cope with a change in specifications such as the number of display units and the display mode. In this case, it is necessary to change the software of the display control device in accordance with a change in specifications, but there is no need to change the display control board (hardware), which is advantageous in terms of cost and the like. Here, in the gaming machine, the display control board or the like may be required to undergo a test at a test institution or the like. By making it possible to respond to various specification changes without changing the display control board (hardware), it is not necessary to take a test of the display control board by a test institution etc. every time the specification is changed, and the time required for the specification change is reduced. It can be greatly reduced.
Furthermore, since a dynamic lighting circuit or a static lighting circuit is connected to the output terminal of the display control board, it is possible to prevent the occurrence of an empty terminal. As a result, it is also possible to prevent an incorrect signal from being input from a vacant terminal.
[0038]
The present invention is not limited to the configuration described in the embodiment, and various changes, additions, and deletions are possible.
Further, the present invention can be used for various game machines (slot machines, etc.) other than pachinko machines.
Further, the display means is not limited to the LED.
Further, the switching circuit may be constituted by a single switching element such as a transistor or an FET, or may be constituted by a plurality of elements including the switching element.
Further, the “output terminal of the first group” is, for example, an output terminal in which the switching element (directly controlling the output state of the output terminal) in the preceding stage of the output terminal is a PNP transistor (first switching circuit). It is. In this case, the “first connection mode” and the “second connection mode” mean a mode in which one (cathode side) is connected to the other of the display means (LED or the like) connected to GND, provided in a dynamic lighting circuit. Connected to one side (for example, the common side) of the display means. The “output terminal of the second group” is, for example, an output terminal in which the switching element at the preceding stage of the output terminal is an NPN transistor (second switching circuit). In this case, the “third connection mode” and the “fourth connection mode” mean a mode in which one side (for example, the anode side) is connected to the other of the display means (LED or the like) connected to the power supply, dynamic lighting. This is one of the modes of connection to the other side (for example, the data side) of the display means provided in the circuit.
Further, the “output terminal of the first group” may be an output terminal connected to the NPN transistor, and the “output terminal of the second group” may be an output terminal connected to the PNP transistor. .
Further, in the present embodiment, the case where the static lighting control is performed using one output terminal has been described, but the static lighting control may be performed using a plurality of output terminals. For example, the anode of the LED 35 whose cathode is connected to the output terminal TE11 shown in FIG. 2 is connected to the LED power supply B. However, if the output terminal TE1 can be used, the anode is connected to the output terminal TE1. In this case, when the output terminal TE1 is “ON” and the output terminal TE11 is “ON”, the LED 35 is turned on. According to this, the occurrence of a vacant terminal can be more easily prevented.
Further, in the present embodiment, the case where the display means is controlled to be turned on / off by the display control circuit 21 has been described. However, the main control circuit 11, the prize ball control circuit (not shown), and the like are turned on. / Light-off control may be performed. In this case, the main control circuit 11 for controlling turning on / off of the display means, the prize ball control circuit, and the like include the "display control means" of the present invention, and the main control board 10a on which the main control circuit 11 is provided, The prize ball control board provided with the prize ball control circuit corresponds to the “display control board” of the present invention.
[0039]
The present invention can be configured as follows.
For example, “(Aspect 1) A display unit and a display control board are provided, and the display control board includes an output terminal of a first group, an output terminal of a second group, and an output terminal of the first group. A first switching circuit to be connected, a second switching circuit to be connected to an output terminal of the second group, and display control means for controlling the first and second switching circuits according to a game state are provided. The output terminals of the first group are connected to either a common side of a dynamic lighting circuit for dynamically lighting the display means or a static lighting circuit for statically lighting the display means, and the output terminals of the second group are The data side of the dynamic lighting circuit for dynamically lighting the display means or the static lighting circuit for statically lighting the display means The display control means determines whether the output terminal of the first group is connected to the common side of the dynamic lighting circuit or to the static lighting circuit, and determines whether the output terminal of the second group is the dynamic lighting circuit. Gaming machine that controls the first and second switching circuits in accordance with which of the data side or the static lighting circuit is connected. "
In the gaming machine of the first aspect, the output terminal of the gaming machine is a common side of a dynamic lighting circuit for dynamically lighting the display means, a static lighting circuit for statically lighting the display means, or a dynamic lighting circuit for dynamically lighting the display means. Connected to either side. Therefore, the same display control board can easily cope with a change in specifications such as the number of display means and the display mode, and all output terminals are connected to a static lighting circuit or a dynamic lighting circuit. In addition, the switching circuit and the like provided on the display control board can be effectively used. Furthermore, since no vacant terminal is generated at the output terminal of the display control board, it is possible to prevent an illegal signal from being input to the vacant terminal.
Here, when a common terminal or a data terminal is provided in the dynamic lighting circuit, “connect to the common side” of the dynamic lighting circuit means “connect to the common terminal”. Further, “connect to the data side” of the dynamic lighting circuit means “connect to the data terminal”.
"(Aspect 2) The gaming machine according to aspect 1, wherein the first switching circuit uses a first conductivity type switching element and the second switching circuit uses a second conductivity type switching element. ].
In the gaming machine of the second aspect, since the first and second switching circuits use switching elements of the first conductivity type and the second conductivity type, the circuit configuration is simple.
"(Aspect 3) The gaming machine according to aspect 3, wherein one of an NPN transistor and a PNP transistor is used as the first conductivity type switching element, and an NPN transistor or A gaming machine using the other of the PNP transistors. "
In the gaming machine according to the third aspect, an inexpensive switching element can be used, so that the gaming machine can be configured at low cost.
[0040]
【The invention's effect】
As described above, the use of the gaming machine according to claim 1 increases the degree of freedom with respect to specification changes and the like, and allows the display control device to be effectively used.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of an embodiment of a main control device 10, a display control device 20, and a display means used in a gaming machine of the present invention.
FIG. 2 is a circuit diagram of an embodiment of a display control device 20 and a display substrate 30a.
FIG. 3 is a timing chart of an output from the display control device 20 to the display substrate 30a shown in FIG. 2, and a diagram showing a turned on / off state of connected LEDs and the like.
FIG. 4 is a circuit diagram when the configuration of the display substrate 30a is different.
FIG. 5 is a timing chart of an output from the display control device 20 to the display substrate 30a shown in FIG. 4, and a diagram showing a turned on / off state of connected LEDs and the like.
FIG. 6 is a circuit diagram when the configuration of the display substrate 30a is different.
FIG. 7 is a timing chart of an output from the display control device 20 to the display substrate 30a shown in FIG. 6, and a diagram showing a turned on / off state of connected LEDs and the like.
FIG. 8 is a circuit diagram when the configuration of the display substrate 30a is different.
9 is a timing chart of an output from the display control device 20 to the display substrate 30a shown in FIG. 8, and a diagram showing a turned on / off state of a connected LED and the like.
FIG. 10 is a diagram showing a conventional technique.
FIG. 11 is a diagram showing a conventional technique.
[Explanation of symbols]
10 Main controller
20 Display control device
20a Display control board
22a-22m switching circuit
30 Display device
30a Display substrate
31-33, 367-segment display
TE1 to TE12 output terminal
TL1 to TL12 input terminal

Claims (1)

Display means, comprising a display control board,
The display control board includes an output terminal of a first group, an output terminal of a second group, a first switching circuit connected to each output terminal of the first group, and an output terminal of the second group. A second switching circuit connected to the terminal, and display control means for controlling the first and second switching circuits according to a game state are provided;
Each output terminal of the first group is connected to the display means in a first connection mode or a second connection mode,
Each output terminal of the second group is connected to the display means in a third connection mode or a fourth connection mode,
The display control means determines whether the output terminals of the first group are connected in the first connection mode or the second connection mode, and whether the output terminals of the second group are in the third connection mode or A gaming machine that controls the first and second switching circuits in accordance with which of the fourth connection modes the connection is made.

Images