JP5645314B2 - Control device for gaming machine - Google Patents

Description

  The present invention relates to a technique for controlling a plurality of control objects mounted on a gaming machine.

  In recent years, in gaming machines such as slot machines and pachinko machines, it has been required to reduce power consumption of electric devices provided in gaming machines when the player is not actually playing a game, thereby suppressing power consumption. . For example, in the gaming machine described in Patent Document 1, whether or not the player is operating the gaming machine is detected by the operation detecting means, and it is determined by the operation detecting means that the player is not operating the gaming machine. In some cases, the power saving means turns off the power of an electric device such as a discharger lamp and an incandescent lamp included in the decorative lamp and a liquid crystal display device for displaying various data, or reduces the power consumption.

  Specifically, the operation detecting means includes a human sensor that detects a player formed by an infrared sensor or an ultrasonic sensor, and a pachinko ball sensor that detects whether a pachinko ball is present in the pachinko ball receiver. The game situation of the gaming machine is detected by the operation detection means based on the detection signal of the human sensor or the pachinko ball sensor. Based on the gaming situation of the gaming machine detected by the operation detecting means, the power on / off of the discharger lamp or the liquid crystal display device is switched by the power saving means, or the duty of the pulse voltage for driving the incandescent lamp to turn on. The ratio is adjusted by the power saving means.

  Further, for example, in the gaming machine described in Patent Document 2, the effect button provided on the upper ball tray is operated by the player, or the power saving switch provided inside the gaming machine is operated by the store clerk of the gaming store. By doing so, the gaming machine can save power. In other words, when the effect button or the power saving switch described above is operated, the power generation resistance used in the power generation circuit is generally controlled between the normal usage and the power saving resistance having a larger resistance value than the normal usage. It is switched by the CPU. Then, the drive voltage generated in the power supply generation circuit to be supplied to the lamp drive circuit and the sound generation circuit is switched between the normal use and the power saving for lower voltage than the normal use. Power saving.

  When the effect button or the power saving switch described above is operated, a power saving command is output to the display control CPU that controls the symbol display device. Then, based on the power saving command input to the display control CPU, the gaming machine is saved by reducing the luminance of the backlight of the symbol display device by reducing the drive voltage supplied from the inverter board to the symbol display device. Powered.

  Further, for example, in the gaming machine described in Patent Document 3, the power supply circuit that drives the backlight of the liquid crystal display device is controlled by the effect control board via the lamp control board, so that the gaming machine according to the gaming situation of the gaming machine. Adjusts the light intensity of the backlight.

Japanese Unexamined Patent Publication No. 2000-271323 (paragraphs 0023 to 0055, 0067, FIGS. 2 to 4, abstract, etc.) JP 2010-268936 A (paragraphs 0063, 0073 to 0075, 0083, FIG. 4, abstract, etc.) JP 2011-24801 (paragraphs 0057 to 0068, FIG. 3, abstract, etc.)

  In the gaming machine described in Patent Document 1 described above, control signals for powering on and off each control target, such as a discharger lamp, an incandescent lamp, and a liquid crystal display device, and the brightness of the incandescent lamp A control signal for setting the duty ratio of the pulse voltage to adjust the pulse voltage is individually generated for each control object by the power saving means. Then, each control signal generated corresponding to each control object by the power saving means is individually transmitted to each corresponding control object, so that each control object is transmitted from the power saving means. Each is controlled to a predetermined control state based on the signal. Therefore, for example, when the number of control objects increases, the number of signal lines for transmitting control signals to the increased control objects must be increased, and the configuration of the interface of the power saving means is designed. Must be changed.

  Further, in the gaming machine described in Patent Document 2 described above, the gaming machine is configured by outputting control signals individually from the overall control CPU to each control target (power generation circuit (switching of resistance), display control CPU). Power saving. Therefore, similarly to the gaming machine described in Patent Document 1, when the number of control objects increases, the interface (I / O) of the general control CPU is used to transmit a control signal to the increased control objects. Must be redesigned.

  In addition, in the gaming machine described in Patent Document 3, the circuit configuration in which the backlight is adjusted to a predetermined control state (luminance) by the effect control board via the lamp control board is not specifically disclosed. However, a circuit configuration for controlling a plurality of control objects such as a backlight by the effect control board has not been sufficiently studied.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique capable of switching a plurality of control targets to a predetermined control state based on a pulse voltage that can be transmitted by a single signal line. And

To achieve the above object, a game machine control device according to the present invention, a pulse voltage generating means for generating a pulse voltage of one of the duty ratio of a plurality of preset duty ratio, Yu technique A control signal for switching a control state of each of a plurality of control objects included in the machine to a predetermined control state corresponding to the duty ratio of the pulse voltage is output to each control object to change the control state of each control object. Switching means for switching, and the switching means is provided corresponding to each control object, and voltage averaging means for averaging the pulse voltage and outputting a voltage having a magnitude corresponding to the duty ratio. A plurality of voltages for comparing the magnitudes of the output voltages of the voltage averaging means and the magnitudes of the comparison voltages respectively set for the corresponding control objects. And compare means, and an outputting means for outputting the control signal based on the comparison result of the respective voltage comparator means (claim 1).

Also, further comprising a game situation detecting means for detecting the Yu technique situation, if the game situation is preset by the game status detecting means is detected, the pulse voltage generating means, at least one of said controlled object The pulse voltage with the duty ratio may be generated such that the switching means outputs the control signal for switching the control state to the power-off state.

  Each of the control objects may include a power switch circuit that switches on and off the power of the control object based on the control signal output by the switching means.

  The control unit may include an illuminating unit, and the illuminating unit may include a luminance adjustment circuit that adjusts the luminance of the illuminating unit based on the pulse voltage generated by the pulse voltage generating unit. ).

  Further, each comparison voltage is set to a different value for each control target, and the output means gradually increases the duty ratio of the pulse voltage generated by the pulse voltage generation means, and the voltage averaging As the output voltage of the means gradually increases, the control corresponding to the voltage comparison means in which the comparison voltage is set large from the control object corresponding to the voltage comparison means in which the comparison voltage is set low. The control signal is sequentially output to a target, and the duty ratio of the pulse voltage generated by the pulse voltage generation unit is gradually decreased, and the output voltage of the voltage averaging unit is gradually decreased. The voltage comparison means in which the comparison voltage is set small from the control object corresponding to the voltage comparison means in which the comparison voltage is set large. Corresponding may sequentially outputs the control signal to said control object (claim 5).

  The switching means includes a pulse voltage detection means for detecting the pulse voltage, and whether or not the pulse voltage detected by the pulse voltage detection means is in an abnormal state in which the duty ratio is outside a predetermined range. When the pulse voltage is determined to be abnormal by the abnormal state determination unit and the abnormal state determination unit, the duty ratio of the normal pulse voltage is set to at least one of the control objects. Instead of the control signal output based on the control signal, an abnormality response signal output means for outputting an abnormality response signal for controlling the control target to a specified abnormality response state may be further provided.

According to the first aspect of the present invention, a pulse voltage having any one of a plurality of preset duty ratios is generated by the pulse voltage generation means, and each control state of the plurality of control objects provided in the gaming machine is determined. Is switched to a predetermined control state corresponding to the duty ratio of the pulse voltage, and the control unit outputs the control state to each control target, whereby the control state of each control target is switched.

  Specifically, the pulse voltage is averaged, and a voltage having a magnitude corresponding to the duty ratio is output by the voltage averaging means. Also, each voltage comparison means provided corresponding to each control object compares the magnitude of the output voltage of the voltage averaging means with the magnitude of the comparison voltage set for each control object. And the control signal based on the comparison result in each voltage comparison means provided corresponding to each control object is output from the output means to each control object. Therefore, based on the pulse voltage that is generated by the pulse voltage generation means and can be transmitted by one signal line, the switching means outputs a control signal corresponding to the duty ratio of the pulse voltage to each control object. Thus, a plurality of control objects can be switched to a predetermined control state.

  According to the second aspect of the present invention, the control for switching the control state of at least one control target to the power-off state by the pulse voltage generation means when the gaming situation preset by the gaming situation detection means is detected. A pulse voltage having a duty ratio such that the signal is output by the switching means is generated. Therefore, in a preset game situation, the control state of at least one control object is switched to the power-off state by the switching means, so that the gaming machine can save power with a simple configuration.

  According to the invention of claim 3, each control object includes the power switch circuit for switching the power on and power off of the control object on the basis of the control signal output by the switching means. By appropriately adjusting the ratio, it is possible to control the power-on and power-off of each controlled object by the switching means, so that it is possible to provide a gaming machine control device having a very practical configuration.

  According to the invention of claim 4, the illumination unit is provided as a control target, and the illumination unit includes a luminance adjustment circuit that adjusts the luminance of the illumination unit based on the pulse voltage generated by the pulse voltage generation unit. By appropriately adjusting the duty ratio of the pulse voltage generated by the pulse voltage generating means, the lighting means can be switched to a predetermined control state by the switching means based on the same pulse voltage, and the brightness adjusting circuit The brightness of the illumination means can be adjusted appropriately.

  In addition, if the power switch circuit is controlled by the switching means based on the duty ratio of the pulse voltage and the power supply of the illumination means is switched on and off, the duty ratio of the pulse voltage is adjusted appropriately. By appropriately performing power-on / off control of the lighting means by the switching means and brightness adjustment of the lighting means by the brightness adjustment circuit, it is possible to reduce power consumption of the lighting means and save power of the gaming machine. .

  According to the invention of claim 5, each comparison voltage used in each voltage comparison means is set to a different value for each controlled object. Then, as the duty ratio of the pulse voltage generated by the pulse voltage generation means gradually increases and the output voltage of the voltage averaging means gradually increases, the control corresponding to the voltage comparison means in which the comparison voltage is set to be small A control signal is sequentially output from the target to the control target corresponding to the voltage comparison unit for which the comparison voltage is set large. In addition, as the duty ratio of the pulse voltage generated by the pulse voltage generation means gradually decreases and the output voltage of the voltage averaging means gradually decreases, the control target corresponding to the voltage comparison means for which the comparison voltage is set to be large Then, the output means sequentially outputs the control signal to the control object corresponding to the voltage comparison means for which the comparison voltage is set to be small. Therefore, each control object can be controlled in an arbitrary order by appropriately setting the magnitude of each comparison voltage corresponding to each control object and appropriately adjusting the duty ratio of the pulse voltage.

  According to the invention of claim 6, the abnormal state determination means determines whether or not the pulse voltage detected by the pulse voltage detection means is in the abnormal state having the duty ratio outside the predetermined range, and the abnormal state When the determination means determines that the pulse voltage is abnormal, the control object is defined for at least one control object instead of the control signal output based on the duty ratio of the normal pulse voltage. An abnormality response signal for controlling the abnormality response state is output by the abnormality response signal output means. Accordingly, the manager of the hall in which the player or the gaming machine is installed has generated the pulse voltage normally by the pulse voltage generation means based on whether or not the control target is controlled to the specified abnormality handling state. It is possible to reliably recognize no abnormality.

It is a perspective view of a slot machine provided with the control device for gaming machines according to the present invention. FIG. 3 is a block diagram showing an electrical configuration of the slot machine. It is a block diagram which shows the structure of a sub control board | substrate and a liquid crystal display device. It is a block diagram which shows the structure of the power supply control circuit with which a liquid crystal display device is provided. It is a figure which shows the relationship between the duty ratio of a pulse voltage, and a power supply state. It is a timing chart which shows an example of ON / OFF control of the power supply according to the duty ratio of a pulse voltage.

  With reference to FIGS. 1-6, the slot machine which is one Embodiment of the game machine provided with the control apparatus for game machines concerning this invention is demonstrated.

<Overview of slot machine>
FIG. 1 is a perspective view of a slot machine including a gaming machine control device according to the present invention. FIG. 2 is a block diagram showing an electrical configuration of the slot machine.

  In the slot machine 1 in this embodiment, one game is executed based on a player's operation on condition that a prescribed number of game media such as medals are inserted. It is configured as follows. That is, in this slot machine 1, the front surface of the housing 3 is closed by the front door 5 so as to be freely opened and closed, and the operation plate 7 is disposed at a substantially central height position of the front door 5. A front plate 9 is disposed above the front plate 9.

  The front plate 9 is provided with a horizontally long display window 11. In addition, left, middle, and right reels that variably display a plurality of types of symbols are arranged inside the display window 11. For example, “Red 7” “White 7” “BAR” “Bell (BE)” “Replay (RP)” “Orange (OR)” “Cherry (CH)” “Hana (HA)” A total of 21 symbols of “catfish (NA)” (9 in this embodiment) are provided in a predetermined arrangement. Further, frame numbers from 0 to 20 are assigned to each symbol in order. Then, for example, a reel tape on which symbols from frame numbers 0 to 20 are printed is attached to the peripheral surface of the reel to form each reel. When the reel rotates, a plurality of symbols are variably displayed in the order of frame numbers 20, 19,..., 0, 20,. From the display window 11, when the rotation of each reel is stopped, the symbols are set to look into a total of three symbols, one in each of the upper, middle and lower stages. That is, when all three reels are stopped, a total of nine symbols arranged in three columns and three rows are stopped and displayed on the display window 11.

  In addition, reel motors 14L, 14M, and 14R each formed of a stepping motor are coupled to each reel so that each reel can be independently rotated.

  Further, the operation board 7 has a bet switch 15 for instructing to insert one medal from each credit medal stored inside as a game medium owned by the player, and the maximum per game (game) from the credit medal. Maximum bet switch 17 for instructing insertion of medals for the number of inserted coins (in this embodiment, one or three depending on the gaming state), lever-shaped start for starting rotation of each reel A switch 19, left / middle / right stop switches 21L, 21M, and 21R for stopping rotation of the left, middle, and right reels, a settlement switch 23 for paying out credit medals, and a medal slot 25 are provided. Yes. In this embodiment, the number of medals inserted for one game (specified number) is set to two types, one or three, depending on the gaming state.

  In addition, a liquid crystal display device 27 is provided almost at the center above the front plate 9 to display an image or the like to give an effect of notifying a player of winning or winning, and immediately above the liquid crystal display device 27. Is provided with an explanation panel 29 on which various winning symbols are displayed, and speakers 31L and 31R for performing effects such as music are provided on the left and right sides of the liquid crystal display device 27 and the explanation panel 29, respectively. A central lamp portion 33M is disposed on the upper side of the explanation panel 29 and the speakers 31L and 31R, and left and right lamp portions 33L and 33R are disposed on the left and right sides thereof. Each lamp unit 33M, 33L, 33R is provided with a light source such as a light emitting diode. These lamp portions 33M, 33L, and 33R are integrally formed, and constitute an upper lamp portion 33 for performing effects such as notifying a player of winning and winning.

  In addition, a lower panel 35 on which a decorative image or the like is displayed is provided below the operation panel 7. A lower lamp unit in which a plurality of light sources are arranged in, for example, two rows on the left and right sides of the lower panel 35. 37L and 37R are provided. A medal payout opening 39 and a medal receiver 41 for receiving medals paid out from the payout opening 39 are provided below the lower panel 35. In addition, a winning line is drawn on the front plate 9, and a credit indicator 45 for displaying the number of stored credit medals is disposed at the lower left corner of the front plate 9. The credit display 45 is composed of, for example, two 7-segment LEDs, and can display a 2-digit stored number (up to 50).

  Each reel is supported by a support frame provided inside the housing 3, and the support frame is fixed to the rear wall of the housing 3. A hopper unit 43 for discharging medals to the payout opening 39 is disposed below the support frame. In addition, a medal selector 48 is arranged on the back side near the medal slot 25 to select whether or not the medal inserted into the medal slot 25 is a legitimate one and guide only the legitimate medal to the hopper unit 43. ing. An operation box 49 is fixed to the left side wall of the housing 3 on the left side of the hopper unit 43. The operation box 49 is provided with a power switch 50 for switching the power on and off, and a key cylinder and a push button type setting for setting change processing for setting the winning probability in the winning combination in the winning lottery. A change button 52 is provided.

  In FIG. 2, the insertion sensor 53 is provided in the vicinity of the medal insertion slot 25 inside the housing 3 and detects one medal inserted into the medal insertion slot 25 one by one. The payout sensor 54 is provided at the exit of the hopper unit 43 and detects medals paid out to the payout outlet 39 one by one.

  The left / middle / right position sensors 55L, 55M, and 55R are for detecting the rotation positions of the left, middle, and right reels, respectively. For example, the photo that detects protrusions provided on the left, middle, and right reels, respectively. When the left, middle, and right reels are made of interrupters, the protrusions are detected every round and the detection signals are output to the main control board 63. In this embodiment, for example, when the left / middle / right position sensors 55L, 55M, and 55R detect the protrusions, the symbol of frame number 20 is arranged in the middle of the display window 11, respectively. .

  The change process start switch 56 is provided inside the key cylinder of the operation box 49, and is turned on and off by inserting and rotating a setting change key (not shown) into the key cylinder.

  The hopper motor 57 is disposed in the hopper unit 43 and pays out medals toward the payout opening 39 by driving thereof.

  Further, in the slot machine 1, a main control board 63 on which a main CPU 61 that controls a game is mounted and a sub control board 73 on which a sub CPU 71 that controls an effect related to the game is mounted are provided separately. ing.

  The RAM 65 of the main control board 63 temporarily stores data indicating the gaming state of the slot machine 1 and data relating to the progress of the game such as the role lottery result of the role lottery means. A storage area for storing the number of medals detected by the insertion sensor 53 and the number of credit medals is formed up to a specified number set in accordance with the gaming state. The ROM 67 of the main control means 63 stores a game machine program (a program for the slot machine 1) including preset data (a role lottery table and a stop table).

  Further, the main CPU 61 of the main control board 63 has an interrupt function such as a timer interrupt, and executes a game machine program stored in the ROM 67 to perform processing related to the progress of the game. Further, the main CPU 61 transmits various data such as data indicating the gaming state of the slot machine 1 and data relating to the progress of the game, such as the role lottery result of the role lottery means, to the sub control board 73 (sub CPU 71) in a command format. To do.

  The memory 75 of the sub-control board 73 includes a RAM unit that temporarily stores various data and a ROM unit that stores various programs for effects. In addition, the sub CPU 71 of the sub control board 73 has an interrupt function such as a timer interrupt, and the sub CPU 71 transmits various data related to the slot machine 1 transmitted from the main CPU 61 (game state and role of the slot machine 1). By executing a program stored in the memory 75 on the basis of data on whether or not a plurality of winning combinations have been won by the winning lottery of the lottery means, the contents of effects related to the game for the player are determined. Further, the sub CPU 71 of the sub control board 73, based on the determined contents of the production, via the I / O port of the sub control board 73, the liquid crystal display device 27, the speakers 31L and 31R, the upper lamp unit 33, Control of effect devices such as the lower lamp portions 37L and 37R is performed.

<Sub-control board and liquid crystal display>
Next, the sub control board 73 and the liquid crystal display device 27 will be described in detail. FIG. 3 is a block diagram showing the configuration of the sub-control board and the liquid crystal display device. FIG. 4 is a block diagram illustrating a configuration of a power supply control circuit included in the liquid crystal display device.

(Sub control board)
The sub control board 73 receives the communication command transmitted from the main control board 63, and performs effects according to the operation and state of the main control board 63. As shown in FIG. 3, the sub-control board 73 has various functions realized by executing a program stored in the memory 75 and various functions realized by hardware. A control signal CS for 27a (VDP: Video Display Processor), a pulse voltage (PWM signal) for the power supply control circuit 100, and power supply voltages V1 and V2 are output to the power supply control circuit 100.

(1) Game situation detecting means 73a
The game situation detection means 73a is a game sensor of the slot machine 1, such as a human sensor formed by an infrared sensor or an ultrasonic sensor to detect a player, or a sensor to detect whether or not a medal is present in the medal receiver 41. Are provided with various sensors. Then, the gaming status detection means 73a detects the detection signal of each sensor and information on whether or not each switch 15, 17, 19, 21L, 21M, 21R, 23 transmitted from the main control board 63 has been operated by the player. Based on the above, the gaming state of the slot machine 1 is detected, such as whether a player is playing a game in the slot machine 1 or whether the player is seated in front of the slot machine 1.

(2) Pulse voltage generation means 73b
The pulse voltage generation means 73b generates a pulse voltage (PWM signal) having a predetermined duty ratio D according to each gaming situation of the slot machine 1 detected by the gaming situation detection means 73a. The pulse voltage generation means 73b can be constituted by a known general PWM signal generation circuit such as a circuit using on / off of a switching element, for example, and the pulse voltage generation means 73b of the slot machine 1 detected by the game situation detection means 73a. A pulse voltage having an arbitrary duty ratio D can be generated by changing the ON / OFF timing of the switching element according to the game situation. In this embodiment, the pulse voltage generation means 73b is configured to generate a pulse voltage with a duty ratio D of 0% <D <100%.

(Liquid crystal display device)
The liquid crystal display device 27 includes a liquid crystal display substrate 27a, a liquid crystal display (LCD) 27b, a cooling fan 27c, and a power supply control circuit 100, and is based on a control signal CS input from the sub control substrate 73 to the liquid crystal display substrate 27a. When the LCD 27b is controlled by the liquid crystal display board 27a, an effect is displayed by displaying a moving image or a still image on the LCD 27b, or various errors are given to the player or the manager of the hall where the slot machine 1 is installed. A message is displayed on the LCD 27b. The power supply control circuit 100 of the liquid crystal display device 27 is supplied with a power supply voltage V1 for the liquid crystal display substrate 27a and the fan 27c and a power supply voltage V2 for the backlight of the LCD 27a from the sub control substrate 73. The pulse voltage having a predetermined duty ratio D generated by the pulse voltage generation means 73b is input.

  The power supply control circuit 100 includes switching means 110 that outputs a control signal based on the duty ratio D of the input pulse voltage. The power supply control circuit 100 also includes a first power switch circuit 120 that switches the supply state of the power supply voltage V1 to the liquid crystal display substrate 27a and the fan 27c based on the control signal output from the switching means 110, and the power supply voltage V2. And a second power switch circuit 130 that switches a supply state of the LCD 27b to the backlight.

(3) Switching means 110
The switching means 110 receives the control states of the liquid crystal display substrate 27a, LCD 27b, and fan 27c as the “control target” of the present invention provided in the liquid crystal display device 27 (slot machine 1) from the pulse voltage generation means 73b. A control signal for switching to a predetermined control state corresponding to the duty ratio D of the pulse voltage is provided corresponding to the first power switch circuit 120 provided corresponding to the liquid crystal display substrate 27a and the fan 26c and the LCD 27b. By outputting to the second power switch circuit 130, the control state of each of the control objects 27a to 27c is switched.

  Specifically, in this embodiment, based on a control signal from the switching means 110, the supply state of the power supply voltage V1 to the liquid crystal display substrate 27a and the fan 27c is switched by the first power switch circuit 120, and the back of the LCD 27b The supply state of the power supply voltage V2 to the light is configured to be switched by the second power switch circuit 130, and the switching unit 110 includes a voltage averaging unit 111 (corresponding to the “voltage averaging unit” of the present invention), A voltage comparison unit 112, a voltage monitoring unit 113 (corresponding to "pulse voltage detection means" and "abnormal state determination means" of the present invention), an abnormality response signal output unit 114 (corresponding to "abnormality response signal output means" of the present invention), An output unit 115 (corresponding to “output unit” and “abnormality response signal output unit” of the present invention) is provided.

a) Voltage averaging unit 111
The voltage averaging unit 111 averages the pulse voltage generated by the pulse voltage generation unit 73b and input to the power supply control circuit 100, and outputs a voltage having a magnitude corresponding to the duty ratio D of the pulse voltage. . The voltage averaging unit 111 includes, for example, an averaging circuit including two voltage dividing resistors that divide the input pulse voltage and a capacitor connected in parallel to the ground side of the voltage dividing resistor. A voltage having a magnitude corresponding to the duty ratio D of the pulse voltage resulting from the averaging is output across the capacitor of the averaging circuit. The configuration of the voltage averaging unit 111 may be any known configuration such as one using an integration circuit as long as a voltage having a magnitude corresponding to the duty ratio D of the pulse voltage can be output. Also good.

b) Voltage comparison unit 112
The voltage comparison unit 112 includes a first voltage comparison circuit 112a provided corresponding to the liquid crystal display substrate 27a and the fan 27c, and a second voltage comparison circuit 112b provided corresponding to the LCD 27b. The first voltage comparison circuit 112a is configured by a general comparator circuit having an operational amplifier, and is set in advance corresponding to the magnitude of the output voltage of the voltage averaging unit 111 and the liquid crystal display substrate 27a and the fan 27c. By comparing the magnitude of the comparison voltage Vref1, if the magnitude of the output voltage of the voltage averaging unit 111 is larger than the magnitude of the comparison voltage Vref1, a control signal in a high (H) level state is output. Similar to the first voltage comparison circuit 112a, the second voltage comparison circuit 112b is configured by a general comparator circuit having an operational amplifier, and corresponds to the magnitude of the output voltage of the voltage averaging unit 111 and the LCD 27b. The comparison voltage Vref2 set in advance is compared, and if the output voltage of the voltage averaging unit 111 is larger than the comparison voltage Vref2, a control signal in a high (H) level state is output. .

c) Voltage monitoring unit 113
The voltage monitoring unit 113 detects a pulse voltage input to the power supply control circuit 100 and determines whether or not the detected pulse voltage is in an abnormal state. Specifically, the voltage monitoring unit 113, for example, describes the clock terminal CK and the output terminal R bar (hereinafter “bar” as “/”, for example, “R bar” as “/ R”. The pulse voltage generated by the pulse voltage generation means 73b and input to the power supply control circuit 100 is input to the clock terminal CK to detect the pulse voltage. Further, the voltage monitoring unit 113 determines whether or not the detected pulse voltage is in an abnormal state having a duty ratio other than a predetermined range. Specifically, in this embodiment, the voltage monitoring unit 113 determines whether the duty ratio D of the pulse voltage is 0% or 100%. In this embodiment, the voltage monitoring unit 113 detects that the detected pulse voltage is between a high (H) level state and a low (L) level state for a predetermined time (for example, 5 seconds). Then, it is determined whether the duty ratio D of the pulse voltage is 0% or 100% by determining whether the potential is in an abnormal state where the potential does not switch. When the pulse voltage is determined to be abnormal, the voltage monitoring unit 113 outputs a high (H) level control signal from the output terminal / R.

d) Abnormality response signal output unit 114
The abnormality response signal output unit 114, when the voltage monitoring unit 113 determines that the pulse voltage is abnormal and outputs a control signal in the H level state from the voltage monitoring unit 113, the liquid crystal display substrate 27a, the LCD 27b, and the fan 27c. Is output to an abnormal response signal for controlling to a specified abnormal response state. Specifically, the abnormality response signal output unit 114 includes, for example, a synchronous D flip-flop, the input terminal D is grounded, and the output terminal / R of the voltage monitoring unit 113 is connected to the reset terminal / PRE. It is connected.

  Therefore, when the pulse voltage is normal, the control signal in the L level state is input from the output terminal / R of the voltage monitoring unit 113 to the reset terminal / PRE of the D flip-flop. Outputs a control signal in the low (L) level state from the output terminal Q regardless of the clock signal input to the clock terminal CK. Further, when the pulse voltage is abnormal, the abnormality response signal output unit 114 outputs a control signal in the H level state from the output terminal / R of the voltage monitoring unit 113 to the reset terminal / PRE of the D flip-flop. When the flip-flop is reset, the control signal in the high (H) level state is output from the output terminal Q as the abnormality corresponding signal regardless of the clock signal input to the clock terminal CK.

  Although not shown, for example, a monitor LED is connected to the output terminal / Q of the D flip-flop provided in the abnormality response signal output unit 114. When the pulse voltage monitored by the voltage monitoring unit 113 is in a normal state, a control signal in a high (H) level state is output from the output terminal / Q of the D flip-flop. Is kept lit. On the other hand, when the pulse voltage monitored by the voltage monitoring unit 113 is in an abnormal state, a low (L) level control signal is output from the output terminal / Q of the D flip-flop. LED goes off. Therefore, by visually checking the lighting state of the output terminal / Q of the D flip-flop, the manager of the hall where the slot machine 1 is installed can check whether the pulse voltage monitored by the voltage monitoring unit 113 is normal or abnormal. It can be confirmed whether it is in a state. In this embodiment, in order to stabilize the operation of the synchronous D flip-flop provided in the abnormality response signal output unit 114, the clock terminal CK of the D flip-flop is generated by the pulse voltage generating unit 73b to control the voltage. The pulse voltage input to the circuit 100 is input.

e) Output unit 115
Based on the comparison result based on the duty ratio D of the pulse voltage in the voltage comparison unit 112 and the monitoring state of the pulse voltage in the voltage monitoring unit 113, the output unit 115 outputs a first power switch circuit 120 and a second power switch described later. A control signal is output to the circuit 130. Specifically, the output unit 115 is configured by a logic circuit in this embodiment, and is provided corresponding to the first OR circuit 115a provided corresponding to the liquid crystal display substrate 27a and the fan 27c and the LCD 27b. And a control signal based on the comparison result in the first and second voltage comparison circuits 112a and 112b is output to the first power switch circuit 120 and the second power switch circuit 130. When the voltage monitoring unit 113 determines that the pulse voltage is abnormal and an abnormality response signal is output from the abnormality response signal output unit 114, the output unit 115 is based on the duty ratio D of the normal pulse voltage. In place of the control signals output from the voltage comparison unit 112 (first and second voltage comparison circuits 112a and 112b), the liquid crystal display substrate 27a, the LCD 27b, and the fan 27c are turned on in a power-on state that is in a prescribed abnormality handling state. Is output to the liquid crystal display substrate 27a, the LCD 27b, and the fan 27c.

  More specifically, the first OR circuit 115a is supplied with the output of the first voltage comparison circuit 112a and the output of the output terminal Q of the abnormality response signal output unit 114, so that the first voltage comparison is performed. If either the output of the circuit 112a or the output of the output terminal Q of the abnormality response signal output unit 114 is the control signal in the H level state, the first OR circuit 115a applies the control signal in the high (H) level state to the first level. 1 Output to power switch circuit 120. The output of the second voltage comparison circuit 112b and the output of the output terminal Q of the abnormality response signal output unit 114 are input to the second OR circuit 115b, and the output of the second voltage comparison circuit 112b. If any of the outputs from the output terminal Q of the abnormality response signal output unit 114 is a control signal in the H level state, the second OR circuit 115b sends the control signal in the high (H) level state to the second power switch circuit. To 130.

  The output unit 115 outputs the first power switch circuit 120 and the second power switch circuit 130 when both of the output signals of the voltage comparison unit 112 and the abnormality response signal output unit 114 are L level control signals. A control signal in a low (L) level state is output for each.

(4) First power switch circuit 120
The first power switch circuit 120 is provided corresponding to the liquid crystal display substrate 27a and the fan 27c, and based on the control signal output from the first OR circuit 115a of the output unit 115, the liquid crystal display substrate 27a and the fan By switching the supply state of the power supply voltage V1 to 27c, the liquid crystal display substrate 27a and the fan 27c are switched on (ON) and off (OFF). Specifically, the first power switch circuit 120 includes a switching element such as a power MOSFET for power, for example, and the first OR circuit 115a of the output unit 115 is connected to the gate of the FET, and the liquid crystal display substrate 27a. The source and drain of the FET are inserted in the supply line of the power supply voltage V1 to the fan 27c.

  Accordingly, when a control signal in the H level state is output from the first OR circuit 115a, the switching element of the first power switch circuit 120 is turned on, and the power supply voltage V1 is supplied to the liquid crystal display substrate 27a and the fan 27c. Then, the liquid crystal display substrate 27a and the fan 27c are switched to the power-on state. If a control signal in the L level state is output from the first OR circuit 115a, the switching element of the first power switch circuit 120 is turned off, and the power supply voltage V1 to the liquid crystal display substrate 27a and the fan 27c is cut off. Thus, the liquid crystal display substrate 27a and the fan 27c are switched to the power-off state.

  More specifically, the output of the first voltage comparison circuit 112a and the output from the output terminal Q of the abnormality response signal output unit 114 are input to the first OR circuit 115a of the output unit 115. Therefore, if the duty ratio D of the pulse voltage is greater than or equal to a predetermined value and the magnitude of the output voltage output from the voltage averaging unit 111 according to the duty ratio D is greater than or equal to the comparison voltage Vref1, The first voltage comparison circuit 112a outputs an H level control signal, and the first OR circuit 115a outputs an H level control signal, whereby the first power switch circuit 120 is turned on. Thus, the liquid crystal display substrate 27a and the fan 27c are switched to the power-on state. Further, if the duty ratio D of the pulse voltage is smaller than a predetermined magnitude and the magnitude of the output voltage output from the voltage averaging unit 111 according to the duty ratio D is smaller than the comparison voltage Vref1, the first voltage The control signal in the L level state is output from the comparison circuit 112a and the control signal in the L level state is output from the first OR circuit 115a, whereby the first power switch circuit 120 is turned off, and the liquid crystal display The board 27a and the fan 27c are switched to the power off state.

  Further, the pulse voltage monitored by the voltage monitoring unit 113 is in an abnormal state, and a control signal in the H level state is output as an abnormality response signal from the output terminal Q of the abnormality response signal output unit 114, and the first OR circuit 115a. When the first power switch circuit 120 is turned on, the first OR circuit 115a outputs an H level control signal regardless of the output state of the first voltage comparison circuit 112a. In this state, the liquid crystal display substrate 27a and the fan 27c are forcibly switched to the power-on state. As described above, in this embodiment, when the pulse voltage monitored by the voltage monitoring unit 113 is in an abnormal state (duty ratio D is 0% or 100%), the first OR circuit of the output unit 115 The control signal in the H level state is output as an abnormality response signal from 115a, whereby the liquid crystal display substrate 27a and the fan 27c are forcibly controlled to a power-on state that is a prescribed abnormality response state. Yes.

  As described above, since the first power switch circuit 120 for switching the power on and power off of the liquid crystal display substrate 27a and the fan 27c based on the control signal output by the switching means 110 is provided, the duty ratio D of the pulse voltage is set. By appropriately adjusting, the switching means 110 can control the power-on and power-off of the liquid crystal display substrate 27a and the fan 27c.

(5) Second power switch circuit 130
The second power switch circuit 130 is provided corresponding to the LCD 27b, and determines the supply state of the power supply voltage V2 to the backlight of the LCD 27b based on the control signal output from the second OR circuit 115b of the output unit 115. By switching, the backlight of the LCD 27b is switched on and off. Specifically, the second power switch circuit 130 includes a switching element such as a power MOSFET for power supply, the second OR circuit 115b of the output unit 115 is connected to the gate of the FET, and the backlight of the LCD 27b. The source and drain of the FET are inserted in the supply line of the power supply voltage V2.

  Accordingly, when a control signal in the H level state is output from the second OR circuit 115b, the switching element of the second power switch circuit 130 is turned on, the power supply voltage V2 is supplied to the backlight of the LCD 27b, and the LCD 27b The backlight is switched on. Further, when the control signal in the L level state is output from the second OR circuit 115b, the switching element of the second power switch circuit 130 is turned off, the power supply voltage V2 to the backlight of the LCD 27b is cut off, and the LCD 27b Is switched to the power off state.

  More specifically, the output of the second voltage comparison circuit 112b and the output from the output terminal Q of the abnormality response signal output unit 114 are input to the second OR circuit 115b of the output unit 115. Therefore, if the duty ratio D of the pulse voltage is greater than or equal to a predetermined value and the magnitude of the output voltage output from the voltage averaging unit 111 according to the duty ratio D is greater than or equal to the comparison voltage Vref2, The second voltage comparison circuit 112b outputs an H level control signal, and the second OR circuit 115b outputs an H level control signal, whereby the second power switch circuit 130 is turned on. Thus, the backlight of the LCD 27b is switched to the power-on state. Further, if the duty ratio D of the pulse voltage is smaller than a predetermined magnitude and the magnitude of the output voltage output from the voltage averaging unit 111 according to the duty ratio D is smaller than the comparison voltage Vref2, the second voltage The control signal in the L level state is output from the comparison circuit 112b and the control signal in the L level state is output from the second OR circuit 115b, so that the second power switch circuit 130 is turned off, and the LCD 27b The backlight is switched to the power off state.

  In addition, the pulse voltage monitored by the voltage monitoring unit 113 is in an abnormal state, and a control signal in the H level state is output as an abnormal response signal from the output terminal Q of the abnormal response signal output unit 114, and the second OR circuit 115b. , The second power switch circuit 130 is turned on by outputting the H level control signal from the second OR circuit 115b regardless of the output state of the second voltage comparison circuit 112b. In this state, the backlight of the LCD 27b is forcibly switched to the power-on state. As described above, in this embodiment, when the pulse voltage monitored by the voltage monitoring unit 113 is in an abnormal state (duty ratio D is 0% or 100%), the second OR circuit of the output unit 115 is used. The control signal in the H level state is output as an abnormality response signal from 115b, so that the backlight of the LCD 27b is forcibly controlled to a power-on state that is a specified abnormality response state.

  As described above, since the second power switch circuit 130 for switching the power of the backlight of the LCD 27b on and off based on the control signal output from the switching means 110 is provided, the duty ratio D of the pulse voltage is appropriately adjusted. Thus, the switching unit 110 can control the power on / off of the backlight of the LCD 27b.

(6) Liquid crystal display substrate 27a
The liquid crystal display board 27a controls the LCD 27b based on the control signal CS input from the sub-control board 73, so that an image based on effect data stored in a storage means such as a hard disk drive or a memory (not shown) is displayed on the LCD 27b. And various error messages are displayed on the LCD 27b.

(7) LCD27b
The LCD 27 b includes a backlight (not shown) (not shown) and a luminance adjustment circuit 27 b 1 for adjusting the luminance of the backlight. The pulse voltage generated by the pulse voltage generation means 73b is input as it is to the luminance adjustment circuit 27b1 via the power supply control circuit 100, and the luminance adjustment circuit 27b1 uses a general PWM signal. Similar to the luminance adjustment of the light source, the luminance of the backlight of the LCD 27b is adjusted based on the duty ratio D of the input pulse voltage.

  Therefore, by appropriately adjusting the duty ratio D of the pulse voltage generated by the pulse voltage generation unit 73b, the switching unit 110 turns on and off the backlight of the LCD 27b based on the same generated pulse voltage. Can be appropriately switched, and the luminance of the backlight can be appropriately adjusted by the luminance adjustment circuit 27b1.

(8) Fan 27c
The fan 27c cools the liquid crystal display substrate 27a and the LCD 27b by air cooling.

  As described above, the game situation detection means 73a, the pulse voltage generation means 73b, the power supply control circuit 100, and the brightness adjustment circuit 27b1 function as the “gaming machine control device” of the present invention.

<Operation example>
Next, an example of power on / off control in the slot machine 1 will be described. FIG. 5 is a diagram showing the relationship between the duty ratio of the pulse voltage and the power supply state. FIG. 6 is a diagram showing an example of power on / off control according to the duty ratio of the pulse voltage. In the following, an example of the operation of the slot machine 1 will be described by taking as an example a case where a pulse voltage whose potential is switched between the L level (0 V) and the H level (5 V) is used.

  In this embodiment, as shown in FIG. 5, the supply state of the power supply voltage V1 to the liquid crystal display substrate 27a and the fan 27c is switched according to the duty ratio D generated by the pulse voltage generation means 73b, and the power supply voltage to the LCD 27b is switched. It is set so that the supply state of V2 is switched. That is, the duty ratio D is any one of 1% ≦ D <2%, 15% ≦ D16%, and 30% ≦ D <100% according to the gaming situation of the slot machine 1 detected by the gaming situation detection unit 73a. Is generated by the pulse voltage generation means 73b. Note that the "prohibited" band is provided in the duty ratio D of the pulse voltage for switching on and off of the supply state of the power supply voltages V1 and V2. The on and off of the power supply voltages V1 and V2 are set. This is to prevent a malfunction of switching between power-on and power-off by providing a “prohibited” band between the above three bands of the respective duty ratios D.

  Specifically, as shown in FIG. 5, in this embodiment, the power supply voltage V1 is supplied to the liquid crystal display substrate 27a and the fan 27c when the duty ratio D of the pulse voltage is 15% or more. The comparison voltage Vref1 of the first voltage comparison circuit 112a is set to 0.6 V corresponding to the output voltage of the voltage averaging unit 111 when the duty ratio D of the pulse voltage is about 10%. With this configuration, as shown in the figure, when the duty ratio D of the pulse voltage generated by the pulse voltage generation means 73b is 1% ≦ D <2%, the first voltage comparison circuit 112a Since the control signal in the L level state is surely output, the first power switch circuit 120 is turned off, and the supply of the power supply voltage V1 to the liquid crystal display substrate 27a and the fan 27c is cut off (turned off). On the other hand, when the duty ratio D of the pulse voltage generated by the pulse voltage generation means 73b is 15% ≦ D <16% and 30% ≦ D <100% as shown in FIG. Since the H level control signal is reliably output from the comparison circuit 112a, the first power switch circuit 120 is turned on and the power supply voltage V1 is supplied (turned on) to the liquid crystal display substrate 27a and the fan 27c.

  Further, as shown in FIG. 5, in this embodiment, the second voltage comparison circuit 112b is supplied so that the power supply voltage V2 is supplied to the backlight of the LCD 27b when the duty ratio D of the pulse voltage is 30% or more. The comparison voltage Vref2 is set to 1.7 V corresponding to the output voltage of the voltage averaging unit 111 when the duty ratio D of the pulse voltage is about 24%. With this configuration, as shown in the figure, when the duty ratio D of the pulse voltage generated by the pulse voltage generation means 73b is 1% ≦ D <2% and 15% ≦ D <16%, Since the L level control signal is reliably output from the second voltage comparison circuit 112b, the second power switch circuit 130 is turned off and the supply of the power supply voltage V2 to the backlight of the LCD 27b is cut off (off). Is done. On the other hand, as shown in the figure, when the duty ratio D of the pulse voltage generated by the pulse voltage generating means 73b is 30% ≦ D <100%, the second voltage comparison circuit 112b is surely at the H level. Since the state control signal is output, the second power switch circuit 130 is turned on, and the power supply voltage V2 is supplied (turned on) to the backlight of the LCD 27b.

  Thus, since the comparison voltages Vref1 and Vref2 of the first and second voltage comparison circuits 112a and 112b are set to different values, the duty ratio D of the pulse voltage generated by the pulse voltage generation means 73b is gradually increased. From the liquid crystal display substrate 27a and the fan 27c provided corresponding to the first voltage comparison circuit 112a to which the comparison voltage Vref1 having a small value is set as the output voltage of the voltage averaging unit 111 increases. A control signal is output from the output unit 115 so that power is sequentially supplied to the LCD 27b provided corresponding to the second voltage comparison circuit 112b in which the comparison voltage Vref2 having a large value is set. Further, as the duty ratio D of the pulse voltage generated by the pulse voltage generation unit 73b gradually decreases and the output voltage of the voltage averaging unit 111 decreases, the second comparison voltage Vref2 having a larger value is set. Power is sequentially supplied from the LCD 27b provided corresponding to the voltage comparison circuit 112b to the liquid crystal display substrate 27a and the fan 27c provided corresponding to the first voltage comparison circuit 112a to which the small comparison voltage Vref1 is set. A control signal is output from the output unit 115 so that the supply is interrupted. Therefore, by appropriately setting the magnitudes of the comparison voltages Vref1 and Vref2 of the voltage comparison circuits 112a and 112b and appropriately adjusting the duty ratio D of the pulse voltage, the voltage comparison circuits 112a and 112b can be respectively adapted to the voltage comparison circuits 112a and 112b. Thus, each control object (liquid crystal control board 27a, LCD 27b, fan 27c) provided can be controlled in an arbitrary order.

  Depending on the configurations of the pulse voltage generation means 73b and the voltage averaging unit 111, the potentials at the L level and the H level of the pulse voltage are different values, and the output of the voltage averaging unit 111 is the same even if the duty ratio is the same. Since the magnitudes of the voltages are different values, the values of the comparison voltages Vref1 and Vref2 of the voltage comparison circuits 112a and 112b are appropriately set according to the configurations of the pulse voltage generation unit 73b and the voltage averaging unit 111. You only have to set it.

  Further, in this embodiment, when the gaming situation preset by the gaming situation detection means 73a is detected, the control for switching the control state of the liquid crystal display board 27a, the backlight of the LCD 27b, and the fan 27c to the power-off state. A pulse voltage having a duty ratio D such that the signal is output by the switching means 110 is generated by the pulse voltage generating means 73b. Specifically, as shown in FIG. 6, when the player leaves for a long time (for example, 10 minutes), the control state of the liquid crystal display substrate 27a and the fan 27c is switched from the power-on state to the power-off state. A pulse voltage having a duty ratio D (1% ≦ D <2%) such that the switching means 110 outputs a control signal is generated by the pulse voltage generation means 73b. In addition, as shown in FIG. 6, when the player leaves the seat for a short time (for example, 5 minutes), a control signal for switching the control state of the backlight of the LCD 27b from the power-on state to the power-off state is switched 110. Is generated by the pulse voltage generation means 73b with a duty ratio D (15% ≦ D <16%).

  Therefore, when a preset game situation is detected by the game situation detection means 73a, the control state of the backlight of the liquid crystal display substrate 27a and the fan 27c or the LCD 27b is changed from the power-on state by the pulse voltage generation means 73b. Since a pulse voltage with a duty ratio D is generated such that the switching means 110 outputs a control signal for switching to the power-off state, at least one control object (liquid crystal display substrate 27a, LCD 27b) in a preset gaming situation. , The fan 27c) is switched to the power-off state by the switching means 110, so that the slot machine 1 can save power. In this embodiment, when the player leaves the seat for a long time, all the control states of the liquid crystal display substrate 27a, the LCD 27b, and the fan 27c are set to the power-off state.

  In the slot machine 1 configured as described above, as shown in FIG. 6, in a normal gaming situation, the pulse voltage generation means 73b generates a pulse voltage with a duty ratio D of 30% ≦ D <100%. The control state of the liquid crystal display substrate 27a and the fan 27c is controlled by the switching means 110 to the power-on state. In addition, the control state of the backlight of the LCD 27b is controlled by the switching means 110 to the power-on state, and the luminance of the backlight of the LCD 27b is adjusted by the luminance adjustment circuit 27b1 based on the duty ratio D of the pulse voltage (light control) State). When the player leaves for a short time, the pulse voltage generator 73b generates a pulse voltage with a duty ratio of 15% ≦ D <16%, thereby switching the backlight of the LCD 27b to the power-off state. Controlled by means 110.

  Further, when the player leaves for a long time, the pulse voltage generation means 73b generates a pulse voltage with a duty ratio of 1% ≦ D <2%, thereby causing the liquid crystal display substrate 27a, the LCD 27b, and the fan 27c to All the control states are controlled by the switching means 110 to the power-off state. Next, when the player returns to the seat and sits down, the pulse voltage generation means 73b generates a pulse voltage with a duty ratio of 15% ≦ D <16%, thereby causing the liquid crystal display substrate 27a and the fan 27c to The control state is controlled by the switching means 110 to the power-on state. Thus, before the control state of the LCD 27b is switched to the power-on state, first, only the control state of the liquid crystal display substrate 27a and the fan 27c is switched to the power-on state by the switching means 110, whereby the control state of the LCD 27b is changed. It is possible to prevent erroneous display on the LCD 27b when the power is turned on.

  When the control state of the liquid crystal display substrate 27a and the fan 27c is in the power-on state and the activation of the liquid crystal display substrate 27a is completed after a predetermined time has elapsed, the duty ratio D is 30% ≦ D by the pulse voltage generation means 73b. When the pulse voltage of <100% is generated, the control state of the backlight of the LCD 27b is controlled to the power-on state by the switching means 110, and the luminance of the backlight of the LCD 27b is based on the duty ratio D of the pulse voltage. Adjustment is performed by the luminance adjustment circuit 27b1.

  If the pulse voltage input to the power supply control circuit 100 by the voltage monitoring unit 113 is abnormal (duty ratio D is D = 0% or D = 100%), the switching means 110 causes the liquid crystal display substrate 27a and the fan to be switched. The control state of the LCD 27b is forcibly switched to the power-on state, the backlight control state of the LCD 27b is forcibly switched to the power-on state, and the luminance of the backlight of the LCD 27b is adjusted to 100 by the luminance adjustment circuit 27b1. Is done.

  As described above, according to this embodiment, the pulse voltage generating means 73b generates a pulse voltage having a preset duty ratio D in accordance with a plurality of gaming situations of the slot machine 1, and the slot machine 1 is provided. The switching means 110 outputs a control signal for switching the control state of each of a plurality of control objects (liquid crystal display board 27a, LCD 27b, fan 27c) to a power-on state or a power-off state according to the duty ratio D of the pulse voltage. Thus, the power-on state and the power-off state are switched.

  Specifically, the pulse voltage input to the power supply control circuit 100 is averaged, and a voltage having a magnitude corresponding to the duty ratio D is output by the voltage averaging unit 111 and provided for each control target. The respective voltage comparison circuits 112a and 112b compare the magnitude of the output voltage of the voltage averaging unit 111 with the magnitudes of the comparison voltages Vref1 and Vref2 set for each control target. And the control signal based on the comparison result in each voltage comparison circuit 112a, 112b provided corresponding to each control object is output from the output unit 115 to each control object. Therefore, based on the pulse voltage that can be transmitted by one signal line generated by the pulse voltage generation unit 73b, the switching unit 110 outputs a control signal corresponding to the duty ratio D of the pulse voltage to each control object. Thus, a plurality of control objects can be switched to a predetermined power-on and power-off state, and power saving control can be performed with a simple configuration.

  Further, even if the number of controlled objects arranged on the terminal side of the slot machine 1 increases, the pulse voltage that can be transmitted by one signal from the pulse voltage generating means 73b (sub control board 73) arranged on the central side. Based on the above, it is possible to control the control target for the increase without increasing the number of signal lines for transmitting the control signal as in the conventional case. That is, the control target for the increase can be controlled without changing the design of the interface configuration of the sub-control board 73 (pulse voltage generation means 73b) arranged on the central side of the slot machine 1, and thus the conventional configuration As compared with, the number of control objects arranged on the end side can be easily increased, and the design of the slot machine 1 can be easily changed.

  Further, the voltage monitoring unit determines whether or not the pulse voltage input to the power supply control circuit 100 is in an abnormal state in which the potential is not switched between a high level state and a low level state for a preset predetermined time. 113, and when the voltage monitoring unit 113 determines that the pulse voltage is abnormal, the duty ratio D of the normal pulse voltage is set for each control target (liquid crystal display substrate 27a, LCD 27b, fan 27c). Based on this, instead of the control signal output from the output unit 115, the output unit 115 outputs an abnormality response signal that forcibly controls each control target to be in a power-on state. Therefore, the player or the hall manager can normally control each control target to be in the power-on state, for example, by the pulse voltage generation means 73b depending on whether a predetermined error message is displayed on the LCD 27b. It is possible to reliably recognize an abnormality in which no pulse voltage is generated.

  The present invention is not limited to the above embodiments, and various modifications other than those described above can be made without departing from the spirit of the present invention. The control target of the present invention is not limited to the above example, and is provided in, for example, the upper lamp unit 33 and the lower lamp units 37L and 37R for production and the switches 15, 17, 19, 21L, 21M, 21R, and 23. The light source may be controlled in the same manner as in the above-described example, or the production speakers 31L and 31R may be controlled. In addition, the control state of each control target is not limited to the above example, and is provided in, for example, the upper lamp unit 33 and the lower lamp units 37L and 37R and the switches 15, 17, 19, 21L, 21M, 21R, and 23. The output unit 115 may output a control signal that causes the light source to repeat blinking according to the duty ratio of the pulse voltage. Further, for example, the output unit 115 may output a control signal such that a special sound effect or sound is output from the speakers 31L and 31R according to the duty ratio of the pulse voltage.

  Further, by providing the above-described configuration on the main control board 63, for example, the left / middle / right reel motors 14L, 14M, and 14R may be controlled. In this case, the voltage averaging unit 111, the voltage comparison unit 112, and the output unit 115 are configured by a module having a microprocessor configuration so that each reel is vibrated in a predetermined manner according to the duty ratio D of the pulse voltage. A control signal may be output from the output unit 115 so as to perform a reel effect.

  In the above-described embodiment, the power control circuit 100 includes the first power switch circuit 120 and the second power switch circuit 130. However, the first power switch circuit 120 and the second power switch circuit 130 Both or one of them may be provided in the corresponding control object.

  In the embodiment described above, the output of the abnormality response signal output unit 114 is configured to be output to each control target via the output unit 115, but the output of the abnormality response signal output unit 114 is You may make it output directly to a control object. In the above-described embodiment, when the pulse voltage is determined to be abnormal by the voltage monitoring unit 113, all the control targets are controlled to be in the abnormality handling state. However, at least one control target is abnormal. What is necessary is just to make it control to a corresponding state. Even with this configuration, the player or the hall manager can recognize that the pulse voltage is abnormal by confirming the control target controlled to the abnormality handling state.

  In addition, when a plurality of control objects are set, one of the plurality of control objects may be controlled based on the duty ratio of the pulse voltage, or the plurality of control objects may be simultaneously controlled. You may comprise so that it may be controlled. For example, when three types of control objects A to C are set, the on / off of the power supplied to each control object A to C is switched as shown in the table below based on the duty ratio of the pulse voltage. An alternative configuration can be adopted.

  In the above-described embodiment, the voltage monitoring unit 113 is configured to determine that the pulse voltage is in an abnormal state when the duty ratio D of the pulse voltage is 0% or 100%. The duty ratio D of the pulse voltage determined as an abnormal state by 113 is not limited to 0% and 100%. For example, when the value of the duty ratio D of the pulse voltage is within a “prohibited” band other than a predetermined range as shown in FIG. 5, the voltage monitoring unit 113 determines that the pulse voltage is in an abnormal state. You may be made to do.

  In the above-described embodiment, the slot machine 1 is described as an example of the gaming machine of the present invention. However, the present invention can be applied to a gaming machine (so-called parrot) in which a slot machine and a pachinko machine are combined. The present invention may be applied to pachinko machines, and the present invention can be widely applied to general gaming machines. Further, a video game by executing a computer program may be adopted as the gaming machine of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Slot machine (game machine), 27a ... Liquid crystal display board (control object), 27b ... Liquid crystal display (control object), 27b1 ... Luminance adjustment circuit, 27c ... Fan (control object), 73a ... Game condition detection means, 73b ... Pulse voltage generation means, 110 ... Switching means, 111 ... Voltage averaging section (voltage averaging means), 112a, 112b ... Voltage comparison circuit (voltage comparison means), 113 ... Voltage monitoring section (pulse voltage detection means, abnormal state) (Determination means), 114... Abnormality response signal output section (abnormality response signal output means), 115... Output section (output means, abnormality response signal output means), 120... First power switch circuit (power switch circuit), 130. 2 power switch circuit (power switch circuit), D ... duty ratio, Vref1, Vref2 ... comparison voltage

Claims (6)

Pulse voltage generation means for generating a pulse voltage of any one of a plurality of preset duty ratios;
A plurality of control target each control state Yu skill machine comprises the control signal for switching the predetermined control state corresponding to the duty ratio, the respective control target respective control outputs to the each control target of the pulse voltage Switching means for switching the state,
The switching means is
Voltage averaging means for averaging the pulse voltage and outputting a voltage having a magnitude corresponding to the duty ratio;
A plurality of voltage comparison means provided corresponding to each of the control objects, respectively, for comparing the magnitude of the output voltage of the voltage averaging means with the magnitude of the comparison voltage set for each of the corresponding control objects; ,
An output means for outputting the control signal based on the comparison result of each voltage comparison means. Further comprising a game situation detecting means for detecting the Yu technique status,
When the gaming situation preset by the gaming situation detection unit is detected, the pulse voltage generation unit switches the control signal for switching the control state of at least one of the controlled objects to a power-off state. 2. The game machine control device according to claim 1, wherein the pulse voltage having the duty ratio output by the means is generated.   3. The game according to claim 1, wherein each of the controlled objects includes a power switch circuit that switches power on and off of the controlled object based on the control signal output by the switching unit. Machine control device. Illuminating means is provided as the control object,
The game according to any one of claims 1 to 3, wherein the illumination unit includes a luminance adjustment circuit that adjusts the luminance of the illumination unit based on the pulse voltage generated by the pulse voltage generation unit. Machine control device. Each comparison voltage is set to a different value for each control target,
The output means includes
The voltage comparison means in which the comparison voltage is set to be smaller as the duty ratio of the pulse voltage generated by the pulse voltage generation means is gradually increased and the output voltage of the voltage averaging means is gradually increased. Sequentially output the control signal from the control object corresponding to the control object corresponding to the voltage comparison means for which the comparison voltage is set to be large,
The voltage comparison means in which the comparison voltage is set larger as the duty ratio of the pulse voltage generated by the pulse voltage generation means is gradually reduced and the output voltage of the voltage averaging means is gradually reduced. The control signal is sequentially output from the control target corresponding to the control target to the control target corresponding to the voltage comparison unit in which the comparison voltage is set to be small. Control device for gaming machines. The switching means is
Pulse voltage detection means for detecting the pulse voltage;
An abnormal state determination unit that determines whether or not the pulse voltage detected by the pulse voltage detection unit is an abnormal state having the duty ratio outside a predetermined range;
Instead of the control signal output based on the duty ratio of the normal pulse voltage for at least one control object when the abnormal voltage is determined to be abnormal by the abnormal state determination means 6. The gaming machine control device according to claim 1, further comprising: an abnormality response signal output unit that outputs an abnormality response signal for controlling the control target to a specified abnormality response state. .

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