JP7179308B2 - game machine - Google Patents

Description

The present invention relates to gaming machines such as pachislot machines.

Conventionally, a plurality of reels each having a plurality of patterns arranged on its surface, game medals, coins, etc. (hereinafter referred to as "game media") are inserted, and the player's operation of the start lever is detected, It detects that a player has pressed a start switch requesting the start of rotation of a plurality of reels and a stop button provided corresponding to each of the plurality of reels, and requests stoppage of the rotation of the relevant reel. a stop switch that outputs a signal; a stepping motor that is provided corresponding to each of a plurality of reels and transmits the respective driving force to each reel; and a reel control device that controls the operation of and rotates and stops each reel, and when it detects that the start lever has been operated, a lottery is performed based on a random number value, and the result of this lottery (hereinafter referred to as " A so-called pachislot machine is known that stops the rotation of the reels based on the timing of detecting that the stop button has been operated.

As a game machine of this type, Patent Document 1 proposes a game machine that performs PWM control by setting a duty ratio for a driving signal of an LED for effect, thereby performing lighting control of the LED in accordance with an image or a sound effect. .

JP 2007-282925 A

In PWM control, switching noise occurs when ON/OFF control is performed on the output signal output from the output terminal of the LED driver IC. Therefore, when a plurality of output terminals are ON/OFF-controlled simultaneously, output signals may interfere with each other due to switching noise emitted from the respective terminals, causing flickering of light emitted from a light emitter such as a performance LED.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a game machine capable of preventing flickering of light emitted from a light emitter.

The game machine according to the present invention is
a plurality of light emitters (LEDs of an LED module);
a plurality of drivers (driver ICs 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs drive data for driving the light emitter to the driver and controls it,
The driver is composed of a master driver (driver IC 121) connected to the control unit and a plurality of slave drivers (for example, driver ICs 122 to 131),
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
address setting terminals (A0 to A5) capable of setting driver addresses;
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
an input setting terminal (MODE) capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit (driver ICs 121 to 131) that outputs drive data input to the input terminals as differential signals;
and a drive circuit (for example, each driver IC 121 to 131) for driving the light emitter,
The drive circuit is
a plurality of output terminals (OUT00 to OUT23);
PWM control means (drivers 121 to 131) for PWM-controlling drive signals output from each of the plurality of output terminals based on drive data input to the input terminals;
delay means (drivers 121 to 131) capable of delaying the drive signal PWM-controlled by the PWM control means;
mode setting means capable of setting the delay means to either a first mode in which the plurality of output terminals are grouped into groups of a predetermined number of terminals or a second mode in which the plurality of output terminals are not grouped; Each driver 121 to 131), and
The delay means is
In the first mode, it is possible to start outputting the drive signals from the plurality of output terminals with different phases between the groups,
In the second mode, it is possible to start outputting the drive signal from the plurality of output terminals with different phases among the plurality of output terminals,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. outputting a drive signal for driving the light emitter from the circuit;
Between each driver of the master driver and the slave driver,
a data positive and data negative pair line for transmitting the driving data;
connected by a clock positive and clock negative pair line for transmitting a synchronization clock for driving data transmitted by the data positive and data negative pair lines ;
Each of the master driver and the slave driver operates at a predetermined position of the drive data input to the input terminal (position corresponding to a predetermined bit (7th bit, BIT6) of the internal setting register (address 00H)). is a predetermined value (0), regardless of values other than the predetermined position of the drive data input to the input terminal, the plurality of light emitters respectively connected to the plurality of output terminals are placed in a non-light emitting state. to make
have a configuration.

With this configuration, when the delay means is in the second mode, the gaming machine according to the present invention sequentially shifts the phase between the plurality of output terminals in order to reduce switching noise emitted from the driver that drives the light emitter. By starting to output drive signals from a plurality of output terminals differently, it is possible to prevent the drive signals from interfering with each other between the plurality of output terminals, thereby preventing flickering of light emitted from the light emitter.

Further, in the gaming machine according to the present invention, when the delay means is in the first mode, phases are sequentially shifted between groups of the plurality of output terminals in order to reduce switching noise emitted from the driver that drives the light emitter. By starting to output drive signals from different output terminals, it is possible to prevent the drive signals from interfering between the groups of output terminals, thereby preventing flickering of light emitted from the light emitter. .

According to the present invention, it is possible to provide a game machine capable of preventing flickering of light emitted from a light emitter.

1 is a front perspective view of a gaming machine according to an embodiment of the present invention; FIG. It is a back perspective view of the gaming machine according to the embodiment of the present invention. 1 is a front view of a gaming machine according to an embodiment of the present invention; FIG. 1 is a front view of a gaming machine when an upper door mechanism and a lower door mechanism according to an embodiment of the present invention are opened; FIG. 1 is an exploded perspective view of a gaming machine according to an embodiment of the present invention; FIG. FIG. 2 is a vertical cross-sectional view of the display unit of the gaming machine according to the embodiment of the present invention cut in a direction perpendicular to the left-right direction; FIG. 4 is a diagram showing the relationship between the irradiation range of light projected from the projector of the gaming machine and the main screen according to the embodiment of the present invention; 1 is a block diagram showing an electrical configuration of a gaming machine according to an embodiment of the present invention; FIG. FIG. 4 is a block diagram for explaining LED signal lines for controlling LEDs provided in the gaming machine according to the embodiment of the present invention; 4 is a block diagram showing the configuration of a sub-relay board in the gaming machine according to the embodiment of the present invention; FIG. 4 is a timing chart for explaining modes of drivers provided on the sub-relay board in the gaming machine according to the embodiment of the present invention; FIG. 4 is a block diagram showing another connection mode of the configuration of the sub-relay board in the gaming machine according to the embodiment of the present invention; 2 is a block diagram showing the configuration of a lower peripheral connection board and its peripheral board in the game machine according to the embodiment of the present invention; FIG. 4 is a block diagram showing the configuration of a lower left LED board in the gaming machine according to the embodiment of the present invention; FIG. FIG. 4 is a block diagram showing the configuration of a lower right LED board in the gaming machine according to the embodiment of the present invention; 3 is a block diagram showing configurations of an upper relay board, a side right LED board and a top center LED board in the gaming machine according to the embodiment of the present invention; FIG. 4 is a block diagram showing the configuration of the left side LED board in the gaming machine according to the embodiment of the present invention; FIG. FIG. 4 is a block diagram showing the configuration of the top-side left LED board in the gaming machine according to the embodiment of the present invention; FIG. 4 is a block diagram showing the configuration of the top-side right LED board in the gaming machine according to the embodiment of the present invention; FIG. 4 is a conceptual diagram showing a first example of data output from the sub CPU to each driver in the gaming machine according to the embodiment of the present invention; FIG. 5 is a conceptual diagram showing a second example of data output from the sub CPU to each driver in the gaming machine according to the embodiment of the present invention; FIG. 9 is a conceptual diagram showing a third example of data output from the sub CPU to each driver in the gaming machine according to the embodiment of the present invention; FIG. 11 is a conceptual diagram showing a fourth example of data output from the sub CPU to each driver in the gaming machine according to the embodiment of the present invention;

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

First, the configuration will be explained. As shown in FIGS. 1 to 5, gaming machine 1 is a so-called pachi-slot machine. The gaming machine 1 is capable of playing games using game media such as coins, medals, game balls, tokens, etc., as well as cards storing game value information, which are given or given to players. , and the description below assumes that medals are used.

In the following description, the side (direction) facing the player from the gaming machine 1 is referred to as the front side (front direction) of the gaming machine 1, and the opposite side to the front side is referred to as the rear side (rear direction, depth direction). The right side and left side as seen from the player are referred to as the right side (right direction) and the left side (left direction) of the gaming machine 1, respectively. A direction including the front side and the rear side is referred to as a front-rear direction or a thickness direction, and a direction including the right side and the left side is referred to as a left-right direction or a width direction. A direction perpendicular to the front-rear direction (thickness direction) and the left-right direction (width direction) is referred to as the vertical direction or the height direction.

As shown in FIGS. 1 and 2, the appearance of the gaming machine 1 is composed of a rectangular box-shaped housing 2 . The housing 2 includes a metal cabinet G having a rectangular opening on the front side as a game machine main body, an upper door mechanism UD arranged in the upper front part of the cabinet G, and a lower door mechanism UD arranged in the lower front part of the cabinet G. and a door mechanism DD.

In addition, two openings G41 are formed in the top wall G4 of the cabinet G so as to penetrate vertically at a predetermined interval in the horizontal direction. A wooden plate member G42 is attached to the top wall G4 so as to block the two openings G41.

As shown in FIGS. 3 and 4, the upper door mechanism UD and the lower door mechanism DD are formed to correspond to the shape and size of the opening of the cabinet G. As shown in FIG. The upper door mechanism UD and the lower door mechanism DD are provided so as to be able to close the upper and lower portions of the opening in the cabinet G. As shown in FIG. The upper door mechanism UD has an upper display window UD1 in the center. A transparent panel UD11 that transmits light is provided in the upper display window UD1. An upper left speaker UD25L and an upper right speaker UD25R are provided above the upper door mechanism UD.

The lower door mechanism DD is provided with a main display window DD4 formed as a rectangular opening substantially at the center of the upper portion. A reel unit RU attached from the inside of the cabinet G is mounted on the back side of the main display window DD4. Further, a main control board 71 is attached to the rear surface of the reel unit RU.

The reel unit RU is mainly composed of three reels RL (left reel), RC (middle reel), and RR (right reel) each having a plurality of types of patterns drawn on its outer peripheral surface. These reels RL, RC, and RR are arranged in parallel (in a horizontal row) so that they can rotate in the vertical direction at a constant speed. As for the reels RL, RC, RR, the operation of each reel RL, RC, RR and the symbols drawn on each reel RL, RC, RR can be visually recognized through the main display window DD4.

A transparent panel made of a rectangular acrylic plate or the like is attached and fixed to the surface of the main display window DD4 so that the player or the like cannot touch the reel unit RU. Below the main display window DD4, substantially horizontal first, second and third pedestals DD2a, DD2b and DD2c are formed. A first pedestal DD2a located on the right side of the main display window DD4 is provided with a medal slot DD5 for inserting medals. The medal slot DD5 is an opening into which the player inserts medals. The medals inserted from the medal insertion slot DD5 are credited or bet on the game.

A maximum BET button DD8 (also referred to as a MAXBET button) as a valid line setting means for betting credited medals is provided on the second pedestal portion DD2b located on the left side of the main display window DD4. When the maximum BET button DD8 is pressed, "3" is selected as the number of inserted medals.

On the front side of the maximum bet button DD8, there is provided a start lever DD6 for rotating the reels RL, RC, and RR by the player's operation and for starting the variable display of symbols in the main display window DD4. The start lever DD6 is attached so as to be tiltable within a predetermined angular range.

On the right side of the start lever DD6 and on the front side of the third base portion DD2c, there are three stop buttons for stopping the rotation of the three reels RL, RC, and RR by the player's pressing operation (stopping operation). DD7L, DD7C, and DD7R are provided.

A C/P button (not shown) is provided in the vicinity of the maximum BET button DD8. The C/P button is used to switch the credit/payout of the medals the player has won in the game by pressing the button. When payout is selected by switching the C/P button (non-credit state), medals are paid out from a medal payout opening DD14 (cancellation chute) provided in the coin guard plate portion on the lower side of the lower door mechanism DD. The medals thus paid out are accumulated in the medal receiving part DD15.

Below the start lever DD6 and the stop buttons DD7L, DD7C, and DD7R, a waist panel DD18 (waist light guide plate) is arranged. The waist panel DD18 is configured as a decorative panel using an acrylic plate or the like. The waist panel DD18 displays the name representing the model of the gaming machine 1, various patterns, and the like.

A lower right speaker DD25R is provided on the right side of the medal payout port DD14. On the left side of the medal payout port DD14, a lower left woofer DD25L is provided. An opening communicating with an outlet of a bass reflex port of the enclosure unit 20, which will be described later, is provided on the right side of the lower left woofer DD25L.

The enclosure unit 20 (see FIG. 4) consists of an enclosure (housing) 21 attached to the rear side of the lower door mechanism DD, and a lower left woofer DD25L accommodated in the enclosure 21. As shown in FIG. The lower right speaker DD25R and the lower left woofer DD25L notify the player of various information regarding the game by voice, music, and other sounds.

A sub-display device DD19 is arranged on the left side of the main display window DD4. The sub-display device DD19 displays, for example, the number of medals to be paid out and the number of credited remaining medals when winning is established. Normally, the maximum number of medals to be credited to the gaming machine 1 is 50, so the number of credits of 50 or less is displayed. When the maximum number of 50 medals has been credited, the inserted medals are directly paid out from the medal payout opening DD14. Also, the sub-display device DD19 may have a touch panel on the front surface.

An operation unit 150 is arranged above the sub-display device DD19. The operation unit 150 consists of a LEFT button, a RIGHT button, an UP button, a DOWN button and an ENTER button, and receives various operations from the player. A right chance button 157 is arranged on the right side of the main display window DD4, and a middle chance button 158 is arranged below the main display window DD4. The right chance button 157 and the middle chance button 158 are operated by the player in accordance with the effects associated with the game.

As shown in FIG. 4, inside the cabinet G, an upper opening G101 that opens forward is formed on the upper side with the intermediate support plate G1 interposed therebetween, and the upper opening G101 opens forward on the lower side with the intermediate support plate G1 interposed therebetween. A lower opening G102 is formed. The interior of the cabinet G is partitioned into an upper space and a lower space with an intermediate support plate G1 interposed therebetween. there is The upper space is a space on the rear side of the upper door mechanism UD inside the cabinet G, and accommodates the display unit A and the like. The lower space is a space on the rear side of the lower door mechanism DD in the cabinet G, and includes a reel unit RU, a main control board 71 and a sub control board 72 (see FIG. 8) that control the operation of the game machine 1 as a whole. etc. are accommodated. The main control board 71 constitutes a circuit (main control circuit) that controls the main flow of the game in the gaming machine 1, such as determining the internal winning combination, rotating and stopping the reels RL, RC, and RR, and determining whether or not there is a prize. do. The sub-control board 72 constitutes a circuit (sub-control circuit) that controls execution of effects such as image display.

Further, the upper door mechanism UD can close or open the upper opening G101, and constitutes an opening/closing member of the present invention. The lower opening G102 can be closed or opened by a lower door mechanism DD.

(Display unit A)
As shown in FIG. 5, the display unit A is replaceably mounted on an intermediate support plate G1 inside the cabinet G. As shown in FIG. The display unit A is a so-called projection mapping device having an irradiation unit B that emits irradiation light for displaying an image, and a screen device C that makes an image appear by being irradiated with the irradiation light from the irradiation unit B. .

Here, the projection mapping device is for projecting an image onto the surface of a three-dimensional object such as a structure or a natural object. etc.) or shape, and by projecting an image according to the presentation information, a sophisticated and powerful presentation is possible.

As shown in FIG. 5, the display unit A has a housing A1 with an opening formed in front. The housing A1 is composed of a projector cover B1 forming an upper portion of the irradiation unit B, and a projector housing C10 having a mirror mechanism B3. The projector housing C10 has a box-like shape including a bottom plate C1, a right side plate C2, a left side plate C3, and a back plate C4. The projector cover B1 is replaceably attached to the upper surface of the projector housing C10.

(Display unit A: irradiation unit B)
As shown in FIG. 6, the irradiation unit B has a projector device B2 that emits irradiation light downward. Since the projector device B2 projects images including still images and moving images and light including video images, for convenience of explanation, the images projected from the projector device B2 will be collectively referred to as "images".

(Display unit A: irradiation unit B: projector device B2)
As shown in FIG. 6, the projector device B2 is attached to the projector cover B1 and arranged in the rear part of the cabinet G (see FIG. 4). The projector cover B1 is attached to the right side plate C2 and the left side plate C3 of the projector housing C10, and has an upper cover 171 and a lower cover 172. As shown in FIG.

A lens unit and an optical mechanism (not shown) are provided inside the projector cover B1.

The lens unit is arranged so that the illumination light emitted from the plurality of LED light sources of the optical mechanism and reflected by a DMD (Digital Micromirror Device) is emitted toward the mirror mechanism B3 below via a lens or the like.

A mirror mechanism B3 is arranged below the projector device B2 (in the direction in which the irradiation light is emitted). The mirror mechanism B3 is composed of a mirror holder 173, an optical mirror 174 supported by the mirror holder 173, and a mirror holder bracket 175 supporting the mirror holder 173 and the optical mirror 174. FIG. The mirror holder bracket 175 is fixed to the bottom plate C1 of the projector housing C10. Light projected downward from projector device B2 is reflected forward by optical mirror 174 .

(Upper door mechanism UD and screen device C)
As shown in FIG. 6, the upper door mechanism UD has a front panel 180 and a back panel 181. As shown in FIG. A screen device C is attached to the front surface of the front panel 180 . The screen device C faces the player, and behind the screen device C, an optical mirror 174 and a projector device B2 are installed.

The screen device C includes a main screen 182 and a projection sheet 183 attached to the back surface of the main screen 182 in close contact therewith. The main screen 182 is mainly made of resin such as a translucent acrylic plate or a glass plate, and is formed to have a uniform thickness over the entire surface.

The projection sheet 183 is a transmissive screen that displays an image by projecting it from behind. and a front display surface through which an image is projected.

The projection sheet 183 is mainly made of, for example, a translucent glass plate, an acrylic plate, or a resin film, and is formed so as to have a uniform thickness over the entire surface. It has a gray color.

When the light projected from the projector device B2 is incident on the incident surface (back side surface) of the projection sheet 183, an image ( images (including still images and moving images) are displayed.

The main screen 182 is transparent, and there is no structure in front of the main screen 182 that blocks the view of the player. becomes visible.

FIG. 7 is a diagram showing the relationship between the irradiation range of light projected from the projector device B2 and the screen device C on the side of the upper door mechanism UD. In FIG. 7, the display surface of the screen device C on the side of the upper door mechanism UD is shaded. The irradiation range of the light projected from the projector device B2 is wider than that of the screen device C. As shown in FIG.

Specifically, the light projected from the projector device B2 is incident on the entire surface of the screen device C (shaded area) and passes through the peripheral area of the screen device C on the side of the upper door mechanism UD. In FIG. 7, the peripheral area of the screen device C in the irradiation range of the light projected from the projector device B2 is indicated by oblique lines.

[Electrical Configuration of Gaming Machine 1]
The electrical configuration of the game machine 1 will be described below with reference to FIGS. 8 to 18. FIG.

As shown in FIG. 8, the gaming machine 1 has a main control board 71 arranged in the reel unit RU and a sub control board 72 arranged in the cabinet G. As shown in FIG. The main control board 71 controls game operations of the gaming machine 1 . The sub-control board 72 controls production.

A reel relay board 53, a door relay board 54, and a sub-relay board 69 are connected to the main control board 71 by harnesses or the like. A first drum unit 51L, a second drum unit 51C, a third drum unit 51R, an external terminal plate 56, a hopper device HP, and an auxiliary storage 57 are connected to the drum relay board 53 as harnesses. etc. is connected.

The drum relay board 53 is arranged between the main control board 71, the first drum unit 51L, the second drum unit 51C, the third drum unit 51R, the external terminal plate 56, the hopper device HP, and the auxiliary storage 57. Relays signals input and output by

In this way, the first drum unit 51L, the second drum unit 51C, the third drum unit 51R, the external terminal plate 56, the hopper device HP, and the auxiliary storage 57 are mainly controlled via the drum relay board 53. It is connected to the substrate 71 .

The first spinning drum unit 51L, the second spinning drum unit 51C, and the third spinning drum unit 51R are arranged inside the reel bodies of the reels RL, RC, and RR, respectively. The first drum unit 51L, the second drum unit 51C, and the third drum unit 51R each have a two-phase excitation type stepping motor.

Each stepping motor rotates the reels RL, RC, and RR under the control of the main control board 71 based on the establishment of a predetermined start condition, that is, the operation of the start lever DD6 (start operation), thereby varying the pattern. .

The external terminal plate 56 is attached to the cabinet G, and is provided for outputting to the outside of the game machine 1 signals such as a medal insertion signal, a medal payout signal, external signals 1 to 4 and a security signal.

The hopper device HP stores medals. The hopper device HP pays out medals under the control of the main control board 71 . The hopper device HP outputs information representing the number of paid out medals to the main control board 71 .

The auxiliary storage box 57 stores medals overflowing from the hopper device HP. The auxiliary storage 57 is provided with an auxiliary storage switch (not shown) penetrating into the auxiliary storage 57 . This auxiliary storage switch detects whether or not the auxiliary storage 57 is full of medals, and outputs the detection result to the main control board 71 .

The door relay board 54 includes a medal selector 46 connected to the medal slot DD5 and arranged on the back side of the lower door mechanism DD, a door opening/closing switch 61, an input/settlement switch 62, a start switch 64, a stop switch board 65, and a game state. The display board 66 and the error cancellation switch 67 are connected by a harness or the like.

In this way, the medal selector 46, the door open/close switch 61, the input/settlement switch 62, the start switch 64, the stop switch board 65, the game state display board 66, and the error release switch 67 are connected to the main control board via the door relay board 54. 71.

The medal selector 46 detects that a medal has passed through and outputs the detection result to the main control board 71 . Also, the medal selector 46 discharges the medal inserted into the medal slot DD5 to the medal payout slot DD14 under the control of the main control board 71 . The door opening/closing switch 61 outputs a security signal to the outside of the game machine 1 to notify opening/closing of the upper door mechanism UD and the lower door mechanism DD.

The input/settlement switch 62 detects that the MAX bet button DD8 and the 1 bet button have been pressed, and detects that the input switch outputs the detection result to the main control board 71 and that the settlement button has been pressed. and an adjustment switch for outputting the detection result to the main control board 71 . The start switch 64 detects that the start lever DD6 has been operated (start operation), and outputs the detection result to the main control board 71. FIG.

The stop switch board 65 is provided with stop switches (not shown) corresponding to the three reels RL, RC, and RR. The stop switch detects a stop operation for stopping the rotation of the reels RL, RC, RR, that is, the pressing of each stop button DD7L, DD7C, DD7R, and outputs the detection result to the main control board 71. .

The game status display board 66 displays information about games such as the number of bet medals, the number of medals paid out when winning is established, the number of remaining credited medals, the operation status of replay, and the game waiting status by LEDs (not shown). etc.

The error canceling switch 67 detects the operation of an error canceling button (not shown) for canceling the error notification, changing the setting of the gaming machine 1, confirming the setting of the gaming machine 1, etc., and is output to the main control board 71 .

A sub relay board 69 is connected to the sub control board 72 by BtoB (Board to Board). The sub-control board 72 is connected to the sub-control board 72 via the sub-relay board 69 by unidirectional asynchronous (also referred to as “asynchronous”) serial communication from the main control board 71 to the sub-control board 72 .

A unidirectional (one) optical fiber is interposed between the main control board 71 and the sub-relay board 69 . A signal is transmitted in one direction from the main control board 71 to the sub-relay board 69 by this optical fiber.

The sub-relay board 69 relays wiring that connects the sub-control board 72 and the main control board 71 . Further, the sub-relay board 69 relays wiring connecting the sub-control board 72 and a plurality of boards and input/output devices arranged around the sub-control board 72 .

Specifically, an upper relay board 81, a lower peripheral connection board 82, a lower right speaker DD25R, and a lower left woofer DD25L are connected to the sub-relay board 69 by harnesses or the like. Further, when the sub display device DD19 has a touch panel on the front surface, the touch panel is connected to the sub relay board 69 by a harness or the like.

In this way, the upper relay board 81, the lower peripheral connection board 82, the panel relay board 83, the lower right speaker DD 25R, the lower left woofer DD 25L, and the sub display unit 84 are connected via the sub relay board 69. It is connected to the control board 72 .

The upper relay board 81 is arranged in the upper door mechanism UD. A top center LED board 90, an upper left speaker UD 25L, an upper right speaker UD 25R, a side right LED board 91, and a side left LED board 92 are connected to the upper relay board 81 by harnesses or the like.

In this way, the top center LED board 90, the upper left speaker UD 25L, the upper right speaker UD 25R, the side right LED board 91, and the side left LED board 92 are connected via the upper relay board 81 and the sub relay board 69. It is connected to the sub control board 72 . The right side LED board 91 and the left side LED board 92 are arranged at the right end and left end of the upper door mechanism UD, respectively.

A top-side right LED board 93 and a top-side left LED board 94 are connected to the top center LED board 90 by harnesses or the like.

Thus, the top side right LED board 93 and the top side left LED board 94 are connected to the sub control board 72 via the top center LED board 90 , the upper relay board 81 and the sub relay board 69 . The top side right LED board 93 and the top side left LED board 94 are arranged near the upper left speaker UD25L and the upper right speaker UD25R of the upper door mechanism UD, respectively.

The lower peripheral connection board 82 is arranged in the lower door mechanism DD. The lower peripheral connection board 82 includes a lower left LED board 101, a lower right LED board 102, a middle right LED board 103, a navigation LED board 104, a reel illumination board 105, a stop button LED board 106, and an input board. / The adjustment unit 107, the right chance button unit 108, the middle chance button unit 109, the first reel backlight 110, the second reel backlight 111, and the third reel backlight 112 are connected by a harness or the like. It is connected.

Thus, the lower left LED board 101, the lower right LED board 102, the middle right LED board 103, the navigation LED board 104, the reel lighting board 105, the stop button LED board 106, and the input/settlement unit 107 , the right chance button unit 108, the middle chance button unit 109, the first drum backlight 110, the second drum backlight 111, and the third drum backlight 112 are connected to the lower peripheral connection board 82 and It is connected to the sub-control board 72 via the sub-relay board 69 .

The lower left LED board 101 is provided at the left end of the lower door mechanism DD. The lower right LED board 102 is provided at the right end of the lower door mechanism DD. The middle right LED board 103 is provided above the lower door mechanism DD in the lower door mechanism DD.

The navigation LED board 104 has a plurality of LEDs corresponding to each reel RL, RC, RR, and is provided near the main display window DD4. For example, the sub control board 72 notifies the operating order of the stop buttons DD7L, DD7C, and DD7R by causing the LEDs of the navigation LED board 104 to emit light.

The reel illumination board 105 is provided in the reel unit RU so as to irradiate the reels RL, RC, and RR with light from the outside under the control of the sub-control board 72 . The stop button LED board 106 has LEDs that irradiate the respective stop buttons DD7L, DD7C, and DD7R with light from the back side under the control of the sub control board 72 .

The input/settlement unit 107 includes a MAX bet button DD8, a 1-bet button, a settlement button, and an input/settlement switch 62. Under the control of the sub-control board 72, the MAX bet button DD8 is controlled by an LED that illuminates the MAX bet button DD8 from the back side. have.

The right chance button unit 108 includes a right chance button 157 and has an LED that irradiates the right chance button 157 with light from the rear surface under the control of the sub control board 72 .

The middle chance button unit 109 includes a middle chance button 158 and has an LED that irradiates the middle chance button 158 with light from the rear surface under the control of the sub control board 72 .

The first drum backlight 110, the second drum backlight 111, and the third drum backlight 112 irradiate the reels RL, RC, and RR with light from the inside under the control of the sub-control board 72. As such, it is provided in the reel unit RU.

In addition to the sub relay board 69 , the sub ROM board 76 and the graphic board 73 are connected to the sub control board 72 . The sub-ROM board 76 stores control programs executed by the sub-control board 72, images for presentation (images), sound, light (LED group 75), and communication data.

The image relay board 77 converts image signals transmitted from the sub control board 72 to the projector device B2 and the sub display device DD19 as the main display device according to the signal standards of each display device and relays them.

An image signal is transmitted from the image relay board 77 to the projector device B2 by differential transmission conforming to LVDS (Low voltage differential signaling). Further, a unidirectional (one) optical fiber is interposed between the image relay board 77 and the projector device B2.

That is, the image relay board 77 converts a differential signal representing an image into an optical signal and transmits the optical signal to the projector device B2. Project the image that the signal represents.

In this embodiment, an example in which the projector device B2 is applied as the main display device will be described, but other display devices such as a liquid crystal display device or an organic EL display device may be applied as the main display device.

When another display device such as a liquid crystal display device or an organic EL display device is applied as the main display device, the image relay board 77 is configured to transmit an image signal in accordance with the standard of the main display device. be. Further, it is not always necessary to interpose an optical fiber between the image relay board 77 and the main display device.

The sub-relay board 69 and sub-control board 72, the sub-control board 72 and sub-ROM board 76, the sub-control board 72 and graphic board 73, and the graphic board 73 and image relay board 77 are connected by board-to-board connectors. ing. The sub-control board 72 acquires the control program and data of images, sounds, lights, and communications for presentation from the sub-ROM board 76 in accordance with Serial ATA (Advanced Technology Attachment).

The gaming machine 1 has a power supply unit 44 . The power supply unit 44 is composed of a stabilized power supply circuit that generates a DC voltage of 12 V and a DC voltage of 24 V from a commercial power supply (100 V AC) supplied when a power switch (not shown) is turned on.

A DC voltage of 12 V is supplied to the reel relay board 53 and the sub-relay board 69 . The 24V DC voltage is supplied to an amplifier (not shown) that drives the lower left woofer DD25L. The 12 V DC voltage supplied to the sub relay board 69 is supplied to the other boards. Therefore, power supply lines for other substrates are omitted in FIG.

[LED signal line]
The LED signal lines for controlling the LEDs provided in the gaming machine 1 will be described below.

As shown in FIG. 9, the sub-control board 72 has a sub-CPU 120 as a control section. The sub relay board 69 has a driver IC 121 with 3FH set as the driver address. The upper relay board 81 has a driver IC 122 with 10H set as the driver address.

The top central LED board 90 has a driver IC 123 with 11H set as the driver address. The topside left LED board 94 has a driver IC 124 with 12H set as the driver address.

The topside right LED board 93 has a driver IC 125 with 13H set as the driver address. The side left LED board 92 has a driver IC 126 with 14H set as the driver address.

The lower peripheral connection board 82 has a driver IC 127 with a driver address of 01H, a driver IC 128 with a driver address of 02H, and a driver IC 129 with a driver address of 03H.

The lower left LED board 101 has a driver IC 130 with 04H set as the driver address. The lower right LED board 102 has a driver IC 131 with 05H set as the driver address.

The sub CPU 120 outputs driving data for driving each LED to the driver IC 121 in a three-wire serial manner. In the present embodiment, the sub CPU 120 outputs driving data to the driver IC 121 through an SPI (Serial Peripheral Interface) using the sub CPU 120 as a master.

That is, the sub CPU 120 and the driver IC 121 are provided with a data line for transmitting drive data, a clock line for transmitting a synchronizing clock for the drive data, and a chip select line for selecting a driver to transmit data. connected by

The driver IC 121 relays drive data to the driver IC 122 and the driver IC 127 using differential signals. In the present embodiment, the driver IC 122 relays drive data by two-wire serial LVDS (Low Voltage Differential Signaling), which is a type of differential signal.

It should be noted that the driver IC 122 may use V-by-One, DisplayPort, or the like other than two-wire serial LVDS to relay drive data as long as it is a differential signal.

That is, the driver IC 121, the driver IC 122, and the driver IC 127 are composed of data positive and data negative pair lines for transmitting drive data, and clock positive and clock negative pair lines for transmitting a synchronization clock for the drive data. and are connected by

The driver IC 122 relays drive data to the driver IC 123 and the driver IC 126 by two-wire serial LVDS. Further, the driver IC 122 outputs drive signals based on the drive data to the side right LED substrate 91 from output terminals OUT00 to OUT23 (not shown).

The driver IC 123 relays drive data to the driver IC 124 and the driver IC 125 by two-wire serial LVDS. Driver IC 127 relays drive data to driver IC 128 and driver IC 129 by two-wire serial LVDS. Driver IC 127 also outputs drive signals based on the drive data to stop button LED board 106 and input/settlement unit 107 from output terminals OUT00 to OUT23 (not shown).

Driver IC 128 relays drive data to driver IC 130 via two-wire serial LVDS. Driver IC 128 also sends drive signals based on drive data from output terminals OUT00 to OUT23 (not shown) to navigation LED board 104, right chance button unit 108, middle chance button unit 109, and middle right LED board 103. Output.

The driver IC 129 relays drive data to the driver IC 131 by two-wire serial LVDS. Further, the driver IC 129 outputs drive signals based on drive data from output terminals OUT00 to OUT23 (not shown) to the first drum backlight 110, the second drum backlight 111, the third drum backlight 112, and the like. Output to the rotary drum illumination board 105 .

<Secondary relay board>
As shown in FIG. 10, the driver IC 121 provided on the sub-relay board 69 includes address setting terminals A0 to A5 capable of setting a driver address, input terminals SCL_INp, SCL_INn, SDA_INp, and SDA_INn, and drive data to the input terminals. and an input setting terminal MODE for setting whether to input by two-wire serial LVDS or by three-wire serial (SPI in this embodiment).

The driver IC 121 constitutes a drive circuit and has output terminals OUT00 to OUT23 for outputting drive signals based on drive data for light emitters such as LEDs. The output terminals OUT00 to OUT23 of the driver IC 121 are open-drain outputs to ensure expandability. The driver IC 121 also has relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, and SDA_OUTn.

The driver IC 121 is set with 3FH as a driver address by the address setting terminals A0 to A5. The driver IC 121 with 3FH set as the driver address functions as a master driver. Therefore, the driver IC 121 is hereinafter also referred to as a "master driver".

A driver address is set by connecting the address setting terminals A0 to A5 of the driver IC 121 to the driver IC 130 to a power supply line (VCC) or a ground line (GND), respectively. For example, in the case of the driver IC 126 described later, the driver address is set to 14H. In this case, address setting terminal A0=ground line, address setting terminal A1=ground line, address setting terminal A2=power line, address setting The terminal A3 is connected to the ground line, the address setting terminal A4 is connected to the power line, and the address setting terminal A5 is connected to the ground line.

The driver IC 121 is designed to function as a slave driver when any one of 01H to 3EH is set as the driver address. Therefore, hereinafter, drivers that function as slave drivers (driver IC 122 to driver IC 131 in this embodiment) are also referred to as "slave drivers."

In this embodiment, when the driver address is set to 3FH, the master driver is used. good. Also, the master driver may be set to any one of the driver addresses 01H to 3EH other than 00H and 3FH, and addresses other than those set to the master driver may be slave drivers.

Since driving data is input from the sub CPU 120 to the driver IC 121 in a three-wire serial manner, the input setting terminal MODE is connected to the power supply line and set to High level. When driving data is input to the driver IC 121 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to Low level.

When the input setting terminal MODE is High, the input terminal SCL_INp becomes an SPI clock (SCK) input terminal, the input terminal SCL_INn becomes an SPI chip select (CS) input terminal, and the input terminal SDA_INp becomes an SPI data (SI) input terminal. Since the input terminal SDA_INn is an unused terminal, it is connected to the ground line and fixed to the Low level.

When the input setting terminal MODE is Low, the input terminal SCL_INp is a clock positive input terminal, the input terminal SCL_INn is a clock negative input terminal, the input terminal SDA_INp is a data positive input terminal, and the input terminal SDA_INn is a positive input terminal for data. Negative input terminal for data.

The driver IC 121 constitutes an output circuit, and outputs drive data input by 3-wire serial or 2-wire serial LVDS from relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn by 2-wire serial LVDS.

Specifically, the driver IC 121 outputs a positive clock signal for synchronization from the relay output terminal SCL_OUTp, outputs a negative clock signal for synchronization from the relay output terminal SCL_OUTp, and represents positive drive data from the output terminal SDA_OUTp. A signal representing negative drive data is output from the output terminal SDA_OUTn.

In this way, the driver IC 121 has a bridge function of converting drive data input in a 3-wire serial format into a 2-wire serial LVDS format and outputting it from the relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn, and a 2-wire serial format. It has a repeater function that relays drive data input by LVDS in two-wire serial form from output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, and SDA_OUTn, and can relay drive data to other drivers by two-line serial LVDS. . The driver IC 121 outputs the driving data by one-way communication in order to reduce the processing load for returning a response signal such as ACK to the sub CPU 120 and the relay destination driver.

The driver IC 121 has an internal setting register (address 00H) and registers (addresses 01H to 18H) corresponding to the output terminals OUT00 to OUT23. Data including a driver address (first byte), a register address (second byte), and a register value (third and subsequent bytes) are serially input to the driver IC 121 .

When the driver address set by the address setting terminals A0 to A5 matches the driver address of the input data, the driver IC 121 sequentially sets register values from the register indicated by the register address.

The driver IC 121 constitutes PWM control means, and by executing PWM (Pulse Width Modulation) control, a drive signal controlled based on the duty ratio of the register value set in each register is output to each of the output terminals OUT00 to OUT23. Output from

In the present embodiment, when the register value is FFH (255), a driving signal with a duty ratio of 100% is output, and the luminance of the LED to be driven becomes the highest. A drive signal with a duty ratio of 0% is output (the output of the drive signal is stopped), and the LED to be driven enters a non-light emitting (extinguishing) state.

If the output terminals OUT00 to OUT23 are started to be driven at the same time, switching noise generated from each output terminal is generated at the same time, and the noise is amplified, causing malfunction of the LEDs connected to the output terminals.

Therefore, the driver IC 121 constitutes a delay means, and can delay the driving signals output from the output terminals OUT00 to OUT23. In order to reduce switching noise, the driver IC 121 can start outputting drive signals from the output terminals OUT00 to OUT23 with different phases.

In addition, the driver IC 121 constitutes mode setting means, and selects either a first mode in which the output terminals OUT00 to OUT23 are grouped into groups of a predetermined number of terminals or a second mode in which the output terminals OUT00 to OUT23 are not grouped. mode can be set.

In this embodiment, the driver IC 121 enters the first mode when a predetermined bit (bit 8, BIT7) of the internal setting register (address 00H) is 1, and enters the first mode when the bit is 0. , the second mode.

As shown in FIG. 11A, in the second mode, the driver IC 121 starts outputting drive signals from the output terminals OUT00 to OUT23 at fixed delay intervals Td. In this embodiment, the fixed delay Td is set to the transmission time of 1 byte of the serial signal (three-wire serial or two-wire serial LVDS described above). For example, assuming that the serial signal clock is 10 MHz, the fixed delay Td is 0.8 μs.

In this way, by matching the read interval (drive signal output interval) of each register with the write interval (serial signal reception interval) of each register, the driver IC 121 can set the read period and write period of each register to be equal. prevent overlap.

In the first mode, the driver IC 121 according to the present embodiment groups the output terminals OUT00 to OUT23 into groups of three terminals. That is, the driver IC 121 includes output terminals OUT00 to OUT02, output terminals OUT03 to OUT05, output terminals OUT06 to OUT08, output terminals OUT09 to OUT11, output terminals OUT12 to OUT14, output terminals OUT15 to OUT17, output terminals OUT18 to OUT20, and output terminals OUT21 to OUT23 are grouped into 8 groups of groups 0 to 7, each having a predetermined number of three terminals.

With this grouping, for example, when LEDs are connected to the output terminals that constitute each group, power is supplied to the LEDs from a plurality of output terminals. can be used (for example, see FIG. 18, FIG. 19, etc.).

As shown in FIG. 11B, in the first mode, the driver IC 121 starts outputting drive signals from group 0 to group 7 at intervals of fixed delay Tgd. The fixed delay Tgd is set according to the number of terminals forming the group.

Therefore, the fixed delay Tgd in this embodiment is set to the transmission time of 3 bytes of the serial signal. For example, assuming a serial signal clock of 10 MHz, the fixed delay is 2.4 μs. Thus, like the second mode, the driver IC 121 prevents the read period and the write period of each register from overlapping.

In FIG. 10, the driver IC 121 in this embodiment changes the states of all the output terminals OUT00 to OUT23 when a predetermined bit (7th bit, BIT6) of the internal setting register (address 00H) is 0. When the relevant bit is 1, all the output terminals OUT00 to OUT23 are enabled.

That is, when the predetermined bit (7th bit, BIT6) of the register for internal setting (address 00H) is set to 0, the driver IC 121 outputs the output terminals OUT00 to OUT23 with a duty ratio of 0%. Output the drive signal (stop the output of the drive signal). Therefore, when LEDs are connected to the output terminals OUT00 to OUT23, all the LEDs are in a non-light emitting (extinguishing) state.

When the driver IC 121 that functions as a master driver detects a pulse (active low pulse) of a certain time (200 ns in this embodiment) or more at the input terminal SCL_INn, the relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, Signals for initializing driver IC 122 and driver IC 127 directly connected to SDA_OUTn and drivers connected via driver IC 122 or driver IC 127 are output from relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, and SDA_OUTn.

Therefore, the sub CPU 120 can initialize all the other driver ICs 122 to 131 (see FIG. 9) by outputting an active low pulse of 200 ns or more to the input terminal SCL_INn of the driver IC 121 .

In the present embodiment, none of the LEDs are connected to the output terminals OUT00 to OUT23 of the driver IC 121. However, as described above, the output terminals OUT00 to OUT23 are open circuits that allow a larger current to flow than the constant current sink output. Since it is a drain output, for example, as shown in FIG.

<Lower Peripheral Connection Board and its Peripheral Board>
In FIG. 13, the lower peripheral connection board 82 includes, as described above, a driver IC 127 having a driver address of 01H, a driver IC 128 having a driver address of 02H, and a driver IC 129 having a driver address of 03H. and

Each driver IC 127, driver IC 128, and driver IC 129 are the same as the driver IC 121 described with reference to FIG. detailed description is omitted.

The driver IC 127 is set with 01H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 127 functions as a slave driver. Since drive data is input to the driver IC 127 from the driver IC 121 of the sub relay board 69 by two-wire serial LVDS, the input setting terminal MODE is set to Low (ground level).

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 127 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 121 of the sub relay board 69, respectively.

The driver IC 127 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. Output terminals OUT00 to OUT02 of driver IC 127 are connected to input/settlement unit 107 . The input/settlement unit 107 is provided with an LED module 107a that irradiates the MAX bet button DD8 with light from the back side. An LED module is an electronic component in which one or more LEDs are modularized, and is configured by a chip or a package.

The LED module 107a is a full-color LED having a red (R) LED, a green (G) LED, and a blue (B) LED, and each LED is supplied with a drive voltage VCC (+5 V) supplied from the sub relay board 69. It is Each LED emits light or goes out according to the duty ratio of each drive signal output from the output terminals OUT00 to OUT02 of the driver IC127.

Output terminals OUT03 to OUT11 of the driver IC 127 are connected to the stop button LED board 106. FIG. The stop button LED board 106 is provided with LED modules 106a, 106b, and 106c that irradiate the stop buttons DD7L, DD7C, and DD7R with light from the back side, respectively.

The LED module 106a has a red (R) LED, a green (G) LED, and a blue (B) LED, and each LED is supplied with the driving voltage VCC (+5V) supplied from the sub relay board 69. . Each LED emits light or goes out according to the duty ratio of each drive signal output from the output terminals OUT03 to OUT05 of the driver IC127.

The LED module 106b has a red (R) LED, a green (G) LED, and a blue (B) LED, and each LED is supplied with the driving voltage VCC (+5V) supplied from the sub relay board 69. . Each LED emits light or goes out according to the duty ratio of each drive signal output from the output terminals OUT06 to OUT08 of the driver IC127.

The LED module 106c has a red (R) LED, a green (G) LED, and a blue (B) LED, and each LED is supplied with the drive voltage VCC (+5V) supplied from the sub relay board 69. . Each LED emits light or goes out according to the duty ratio of each drive signal output from the output terminals OUT09 to OUT11 of the driver IC127.

The driver IC 128 is set with 02H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 128 functions as a slave driver. Since drive data is input from the driver IC 127 to the driver IC 128 via a two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to the Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 128 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 127, respectively.

The driver IC 128 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. Output terminals OUT00 to OUT08 of the driver IC 128 are connected to the navigation LED board 104. FIG.

The navigation LED board 104 is provided with LED modules 104a and 104b corresponding to the reels RL, LED modules 104c and 104d corresponding to the reels RC, and LED modules 104e and 104f corresponding to the reels RR.

The LED module 104a and the LED module 104b are full-color LEDs with red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 104a has an anode connected to a cathode of each LED of the LED module 104b, and a cathode connected to each output terminal OUT00 to OUT02 of the driver IC128.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 104b. Each LED of the LED module 104a and each LED of the LED module 104b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT00 to OUT02 of the driver IC128.

The LED module 104c and the LED module 104d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 104c has an anode connected to a cathode of each LED of the LED module 104d, and a cathode connected to each output terminal OUT03 to OUT05 of the driver IC128.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 104d. Each LED of the LED module 104c and each LED of the LED module 104d emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT03 to OUT05 of the driver IC128.

The LED module 104e and the LED module 104f are full-color LEDs with red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 104e has an anode connected to a cathode of each LED of the LED module 104f, and a cathode connected to each output terminal OUT06 to OUT08 of the driver IC128.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 104f. Each LED of the LED module 104e and each LED of the LED module 104f emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT06 to OUT08 of the driver IC128.

Output terminals OUT09 to OUT11 of the driver IC 128 are connected to the middle chance button unit 109. FIG. The middle chance button unit 109 is provided with LED modules 109a and 109b for irradiating the middle chance button 158 with light from the back side.

The LED module 109a and the LED module 109b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 109a has an anode connected to a cathode of each LED of the LED module 109b, and a cathode connected to each output terminal OUT09 to OUT11 of the driver IC128.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 109b. Each LED of the LED module 109a and each LED of the LED module 109b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT09 to OUT11 of the driver IC128.

Output terminals OUT12 to OUT14 of driver IC 128 are connected to right chance button unit 108 . The right chance button unit 108 is provided with LED modules 108a and 108b that irradiate the right chance button 157 with light from the back side.

The LED module 108a and the LED module 108b are full-color LEDs with red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 108a has an anode connected to a cathode of each LED of the LED module 108b, and a cathode connected to each output terminal OUT12 to OUT14 of the driver IC128.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 108b. Each LED of the LED module 108a and each LED of the LED module 108b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT12 to OUT14 of the driver IC128.

Output terminals OUT15 to OUT17 of the driver IC 128 are connected to the middle right LED board 103 . The central right LED board 103 is provided with LED modules 103a and 103b.

The LED module 103a and the LED module 103b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 103a has an anode connected to a cathode of each LED of the LED module 103b, and a cathode connected to each output terminal OUT15 to OUT17 of the driver IC128.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 103b. Each LED of the LED module 103a and each LED of the LED module 103b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT15 to OUT17 of the driver IC128.

The driver IC 129 is set with 03H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 129 functions as a slave driver. Since drive data is input from the driver IC 127 to the driver IC 129 via a two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to the Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 129 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 127, respectively.

The driver IC 129 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. Output terminals OUT00 to OUT02 of the driver IC 129 are connected to the first barrel backlight 110. FIG.

The first spinning drum backlight 110 includes LED modules 110a and 110b that irradiate the upper stage of the reel RL with light from the inside, 110c and 110d that irradiate the middle stage of the reel RL with light from the inside, and inner modules 110c and 110d that irradiate the lower stage of the reel RL with light. 110e and 110f for irradiating light from are provided.

LED module 110a and LED module 110b comprise transparent light LEDs. The LED of the LED module 110 a has an anode connected to the cathode of the LED of the LED module 110 b and a cathode connected to the output terminal OUT00 of the driver IC 129 .

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 110b. The LED of the LED module 110 a and the LED of the LED module 110 b emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT00 of the driver IC 129 .

LED module 110c and LED module 110d comprise transparent light LEDs. The LED of the LED module 110 c has an anode connected to the cathode of the LED of the LED module 110 d and a cathode connected to the output terminal OUT01 of the driver IC 129 .

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 110d. The LED of the LED module 110c and the LED of the LED module 110d emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT01 of the driver IC129.

LED module 110e and LED module 110f comprise transparent light LEDs. The LED of the LED module 110 e has an anode connected to the cathode of the LED of the LED module 110 f and a cathode connected to the output terminal OUT02 of the driver IC 129 .

A drive voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 110f. The LED of the LED module 110 e and the LED of the LED module 110 f emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT02 of the driver IC 129 .

Output terminals OUT03 to OUT05 of the driver IC 129 are connected to the second barrel backlight 111. FIG. The second spinning drum backlight 111 includes LED modules 111a and 111b that irradiate the upper stage of the reel RC with light from the inside, 111c and 111d that irradiate the middle stage of the reel RC with light from the inside, and inner LED modules that irradiate the lower stage of the reel RC with light. 111e and 111f for irradiating light from are provided.

The LED module 111a and the LED module 111b have transparent light LEDs. The LED of the LED module 111 a has an anode connected to the cathode of the LED of the LED module 111 b and a cathode connected to the output terminal OUT03 of the driver IC 129 .

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 111b. The LED of the LED module 111 a and the LED of the LED module 111 b emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT03 of the driver IC 129 .

The LED module 111c and the LED module 111d have transparent light LEDs. The LED of the LED module 111 c has an anode connected to the cathode of the LED of the LED module 111 d and a cathode connected to the output terminal OUT04 of the driver IC 129 .

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 111d. The LED of the LED module 111c and the LED of the LED module 111d emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT04 of the driver IC129.

LED module 111e and LED module 111f comprise transparent light LEDs. The LED of the LED module 111 e has an anode connected to the cathode of the LED of the LED module 111 f and a cathode connected to the output terminal OUT05 of the driver IC 129 .

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 111f. The LED of the LED module 111 e and the LED of the LED module 111 f emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT05 of the driver IC 129 .

Output terminals OUT06 to OUT08 of the driver IC 129 are connected to the third barrel backlight 112. FIG. The third reel backlight 112 includes LED modules 112a and 112b that irradiate the upper stage of the reel RR with light from the inside, 112c and 112d that irradiate the middle stage of the reel RR with light from the inside, and inner LED modules 112c and 112d that irradiate the middle stage of the reel RR with light from the inside. 112e and 112f are provided for irradiating light from.

LED module 112a and LED module 112b comprise transparent light LEDs. The LED of the LED module 112 a has an anode connected to the cathode of the LED of the LED module 112 b and a cathode connected to the output terminal OUT06 of the driver IC 129 .

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 112b. The LED of the LED module 112 a and the LED of the LED module 112 b emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT06 of the driver IC 129 .

LED module 112c and LED module 112d comprise transparent light LEDs. The LED of the LED module 112 c has an anode connected to the cathode of the LED of the LED module 112 d and a cathode connected to the output terminal OUT07 of the driver IC 129 .

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 112d. The LED of the LED module 112c and the LED of the LED module 112d emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT07 of the driver IC129.

LED module 112e and LED module 112f comprise transparent light LEDs. The LED of the LED module 112 e has an anode connected to the cathode of the LED of the LED module 112 f and a cathode connected to the output terminal OUT08 of the driver IC 129 .

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 112f. The LED of the LED module 112e and the LED of the LED module 112f emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT08 of the driver IC129.

Output terminals OUT 09 to OUT 11 of the driver IC 129 are connected to the reel illumination board 105 . The reel illumination board 105 includes LED modules 105a, 105b, and 105c that irradiate light to the reel RL from the outside, 105d, 105e, and 105f that irradiate light to the reel RC from the outside, and light to the reel RR from the outside. 105g, 105h, and 105j are provided.

LED module 105a and LED module 105b comprise transparent light LEDs. The LED module 105c has transparent light LEDs. The LED of the LED module 105 a has an anode connected to the cathode of the LED of the LED module 105 b and a cathode connected to the output terminal OUT09 of the driver IC 129 . The anode of the LED of the LED module 105b is connected to the cathode of the LED of the LED module 105c.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 105c. The LED of the LED module 105a, the LED of the LED module 105b, and the LED of the LED module 105c emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT09 of the driver IC129.

LED module 105d and LED module 105e comprise transparent light LEDs. The LED module 105f has transparent light LEDs. The LED of the LED module 105d has an anode connected to the cathode of the LED of the LED module 105e and a cathode connected to the output terminal OUT10 of the driver IC129. The anode of the LED of the LED module 105e is connected to the cathode of the LED of the LED module 105f.

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 105f. The LED of the LED module 105d, the LED of the LED module 105e, and the LED of the LED module 105f emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT10 of the driver IC129.

LED module 105g and LED module 105h comprise transparent light LEDs. The LED module 105j has transparent light LEDs. The LED of the LED module 105g has an anode connected to the cathode of the LED of the LED module 105h and a cathode connected to the output terminal OUT11 of the driver IC129. The LED of LED module 105h has its anode connected to the cathode of the LED of LED module 105j.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of the LED of the LED module 105j. The LED of the LED module 105g, the LED of the LED module 105h, and the LED of the LED module 105j emit light or go out according to the duty ratio of the drive signal output from the output terminal OUT11 of the driver IC129.

<Lower left LED board>
In FIG. 14, the lower left LED board 101 has the driver IC 130 with 04H set as the driver address as described above. Since the driver IC 130 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 130 is set with 04H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 130 functions as a slave driver. Since drive data is input to the driver IC 130 from the driver IC 128 of the lower peripheral connection board 82 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 130 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 128 of the lower peripheral connection board 82, respectively.

The driver IC 130 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. The lower left LED board 101 is provided with LED modules 130a, 130b, 130c, 130d, 130e, 130f, 130g, 130h, 130i, 130j, 130k, and 130m.

LED module 130a and LED module 130b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 130 a has an anode connected to a cathode of each LED of the LED module 130 b , and a cathode connected to each output terminal OUT00 to OUT02 of the driver IC 130 .

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 130b. Each LED of the LED module 130a and each LED of the LED module 130b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT00 to OUT02 of the driver IC130.

The LED module 130c and the LED module 130d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 130c has an anode connected to a cathode of each LED of the LED module 130d, and a cathode connected to each output terminal OUT03 to OUT05 of the driver IC130.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 130d. Each LED of the LED module 130c and each LED of the LED module 130d emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT03 to OUT05 of the driver IC130.

The LED module 130e and the LED module 130f are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 130 e has an anode connected to a cathode of each LED of the LED module 130 f and a cathode connected to each output terminal OUT06 to OUT08 of the driver IC 130 .

A drive voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 130f. Each LED of the LED module 130e and each LED of the LED module 130f emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT06 to OUT08 of the driver IC130.

The LED modules 130g and 130h are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 130g has an anode connected to a cathode of each LED of the LED module 130h, and a cathode connected to each output terminal OUT09 to OUT11 of the driver IC130.

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 130h. Each LED of the LED module 130g and each LED of the LED module 130h emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT09 to OUT11 of the driver IC130.

LED module 130i and LED module 130j are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 130i has an anode connected to a cathode of each LED of the LED module 130j, and a cathode connected to each output terminal OUT12 to OUT14 of the driver IC130.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 130j. Each LED of the LED module 130i and each LED of the LED module 130j emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT12 to OUT14 of the driver IC130.

The LED module 130k and the LED module 130m are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 130k has an anode connected to a cathode of each LED of the LED module 130m, and a cathode connected to each output terminal OUT15 to OUT17 of the driver IC130.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 130m. Each LED of the LED module 130k and each LED of the LED module 130m emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT15 to OUT17 of the driver IC130.

<Lower right LED board>
In FIG. 15, the lower right LED board 102 has the driver IC 131 with 05H set as the driver address as described above. Since the driver IC 131 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 131 is set with 05H as a driver address by the address setting terminals A0 to A5. Therefore, the driver IC 131 functions as a slave driver. Since drive data is input to the driver IC 131 from the driver IC 129 of the lower peripheral connection board 82 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 131 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 129 of the lower peripheral connection board 82, respectively.

The driver IC 131 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. The lower right LED board 102 is provided with LED modules 131a, 131b, 131c, 131d, 131e, 131f, 131g, 131h, 131i, 131j, 131k, and 131m.

The LED module 131a and the LED module 131b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 131a has an anode connected to a cathode of each LED of the LED module 131b, and a cathode connected to each output terminal OUT00 to OUT02 of the driver IC131.

A drive voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 131b. Each LED of the LED module 131a and each LED of the LED module 131b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT00 to OUT02 of the driver IC131.

The LED module 131c and the LED module 131d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 131c has an anode connected to a cathode of each LED of the LED module 131d, and a cathode connected to each output terminal OUT03 to OUT05 of the driver IC131.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 131d. Each LED of the LED module 131c and each LED of the LED module 131d emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT03 to OUT05 of the driver IC131.

The LED module 131e and the LED module 131f are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 131e has an anode connected to a cathode of each LED of the LED module 131f, and a cathode connected to each output terminal OUT06 to OUT08 of the driver IC131.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 131f. Each LED of the LED module 131e and each LED of the LED module 131f emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT06 to OUT08 of the driver IC131.

The LED modules 131g and 131h are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 131g has an anode connected to a cathode of each LED of the LED module 131h, and a cathode connected to each output terminal OUT09 to OUT11 of the driver IC131.

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 131h. Each LED of the LED module 131g and each LED of the LED module 131h emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT09 to OUT11 of the driver IC131.

The LED modules 131i and 131j are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 131i has an anode connected to a cathode of each LED of the LED module 131j, and a cathode connected to each output terminal OUT12 to OUT14 of the driver IC131.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 131j. Each LED of the LED module 131i and each LED of the LED module 131j emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT12 to OUT14 of the driver IC131.

The LED module 131k and the LED module 131m are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 131k has an anode connected to a cathode of each LED of the LED module 131m, and a cathode connected to each output terminal OUT15 to OUT17 of the driver IC131.

A drive voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 131m. Each LED of the LED module 131k and each LED of the LED module 131m emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT15 to OUT17 of the driver IC131.

<Upper relay board, side right LED board, top center LED board>
In FIG. 16, the upper relay board 81 has the driver IC 122 with 10H set as the driver address, as described above. Since the driver IC 122 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 122 is set with 10H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 122 functions as a slave driver. Since drive data is input to the driver IC 122 from the driver IC 121 of the sub-relay board 69 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to the Low level.

The input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 122 are connected to the relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 121 of the sub relay board 69, respectively.

The driver IC 122 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. Output terminals OUT00 to OUT20 of the driver IC 122 are connected to the side right LED board 91. FIG.

The right side LED board 91 is provided with LED modules 91a, 91b, 91c, 91d, 91e, 91f, 91g, 91h, 91i, 91j, 91k, 91m, 91n, and 91p.

The LED module 91a and the LED module 91b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91 a has an anode connected to a cathode of each LED of the LED module 91 b and a cathode connected to each output terminal OUT00 to OUT02 of the driver IC 122 .

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91b. Each LED of the LED module 91a and each LED of the LED module 91b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT00 to OUT02 of the driver IC122.

The LED module 91c and the LED module 91d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91c has an anode connected to a cathode of each LED of the LED module 91d, and a cathode connected to each output terminal OUT03 to OUT05 of the driver IC122.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91d. Each LED of the LED module 91c and each LED of the LED module 91d emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT03 to OUT05 of the driver IC122.

The LED module 91e and the LED module 91f are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91e has an anode connected to a cathode of each LED of the LED module 91f, and a cathode connected to each output terminal OUT06 to OUT08 of the driver IC122.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91f. Each LED of the LED module 91e and each LED of the LED module 91f emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT06 to OUT08 of the driver IC122.

The LED modules 91g and 91h are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91g has an anode connected to a cathode of each LED of the LED module 91h, and a cathode connected to each output terminal OUT09 to OUT11 of the driver IC122.

A drive voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91h. Each LED of the LED module 91g and each LED of the LED module 91h emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT09 to OUT11 of the driver IC122.

The LED modules 91i and 91j are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91i has an anode connected to a cathode of each LED of the LED module 91j, and a cathode connected to each output terminal OUT12 to OUT14 of the driver IC122.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91j. Each LED of the LED module 91i and each LED of the LED module 91j emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT12 to OUT14 of the driver IC122.

The LED module 91k and the LED module 91m are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91k has an anode connected to a cathode of each LED of the LED module 91m, and a cathode connected to each output terminal OUT15 to OUT17 of the driver IC122.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91m. Each LED of the LED module 91k and each LED of the LED module 91m emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT15 to OUT17 of the driver IC122.

The LED module 91n and the LED module 91p are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 91n has an anode connected to a cathode of each LED of the LED module 91p, and a cathode connected to each output terminal OUT18 to OUT20 of the driver IC122.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 91p. Each LED of the LED module 91n and each LED of the LED module 91p emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT18 to OUT20 of the driver IC122.

The top center LED board 90 has the driver IC 123 with 11H set as the driver address, as described above. Since the driver IC 123 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 123 is set with 11H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 123 functions as a slave driver. Since drive data is input from the driver IC 122 to the driver IC 123 via a two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to the Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 123 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 122, respectively.

The driver IC 123 is set to the first mode in which the output terminals OUT00 to OUT23 are grouped. The top central LED board 90 is provided with LED modules 123a, 123b, 123c, and 123d.

The LED module 123a and the LED module 123b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 123a has an anode connected to a cathode of each LED of the LED module 123b, and a cathode connected to each group 0 to 2 of the output terminals of the driver IC 123 (that is, the group of the output terminals OUT00 to OUT02, the output terminals OUT03 to OUT05 group, output terminals OUT06 to OUT08 group).

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 123b. Each LED of the LED module 123a and each LED of the LED module 123b emit light or go out according to the duty ratio of each drive signal output from each group 0 to 2 of the output terminals of the driver IC123.

The LED module 123c and the LED module 123d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 123c has an anode connected to a cathode of each LED of the LED module 123d, and a cathode connected to each group 3 to 5 of the output terminals of the driver IC 123 (that is, the group of the output terminals OUT09 to OUT11, the output terminals OUT12 to OUT14 group, output terminals OUT15 to OUT17 group).

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 123d. Each LED of the LED module 123c and each LED of the LED module 123d emit light or go out according to the duty ratio of each drive signal output from each group 3 to 5 of the output terminals of the driver IC123.

<Side left LED board>
In FIG. 17, the side left LED board 92 has the driver IC 126 with 14H set as the driver address as described above. Since the driver IC 126 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 126 is set with 14H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 126 functions as a slave driver. Since drive data is input to the driver IC 126 from the driver IC 122 of the upper relay board 81 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 126 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 122 of the upper relay board 81, respectively.

The driver IC 126 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped. The left side LED board 92 is provided with LED modules 126a, 126b, 126c, 126d, 126e, 126f, 126g, 126h, 126i, 126j, 126k, 126m, 126n, and 126p.

LED module 126a and LED module 126b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126a has an anode connected to a cathode of each LED of the LED module 126b, and a cathode connected to each output terminal OUT00 to OUT02 of the driver IC126.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126b. Each LED of the LED module 126a and each LED of the LED module 126b emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT00 to OUT02 of the driver IC126.

The LED module 126c and the LED module 126d are full-color LEDs with red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126c has an anode connected to a cathode of each LED of the LED module 126d, and a cathode connected to each output terminal OUT03 to OUT05 of the driver IC126.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126d. Each LED of the LED module 126c and each LED of the LED module 126d emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT03 to OUT05 of the driver IC126.

LED module 126e and LED module 126f are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126e has an anode connected to a cathode of each LED of the LED module 126f, and a cathode connected to each output terminal OUT06 to OUT08 of the driver IC126.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126f. Each LED of the LED module 126e and each LED of the LED module 126f emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT06 to OUT08 of the driver IC126.

The LED modules 126g and 126h are full-color LEDs with red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126g has an anode connected to a cathode of each LED of the LED module 126h, and a cathode connected to each output terminal OUT09 to OUT11 of the driver IC126.

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126h. Each LED of the LED module 126g and each LED of the LED module 126h emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT09 to OUT11 of the driver IC126.

LED module 126i and LED module 126j are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126i has an anode connected to a cathode of each LED of the LED module 126j, and a cathode connected to each output terminal OUT12 to OUT14 of the driver IC126.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126j. Each LED of the LED module 126i and each LED of the LED module 126j emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT12 to OUT14 of the driver IC126.

LED module 126k and LED module 126m are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126k has an anode connected to a cathode of each LED of the LED module 126m, and a cathode connected to each output terminal OUT15 to OUT17 of the driver IC126.

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126m. Each LED of the LED module 126k and each LED of the LED module 126m emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT15 to OUT17 of the driver IC126.

LED module 126n and LED module 126p are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 126n has an anode connected to a cathode of each LED of the LED module 126p, and a cathode connected to each output terminal OUT18 to OUT20 of the driver IC126.

A drive voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 126p. Each LED of the LED module 126n and each LED of the LED module 126p emit light or go out according to the duty ratio of each drive signal output from the output terminals OUT18 to OUT20 of the driver IC126.

<Top side left LED board>
In FIG. 18, the topside left LED board 94 has the driver IC 124 with 12H set as the driver address as described above. Since the driver IC 124 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 124 is set with 12H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 124 functions as a slave driver. Since drive data is input to the driver IC 124 from the driver IC 123 of the top central LED board 90 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to the Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 124 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 123 of the top central LED board 90, respectively.

The driver IC 124 is set to the first mode in which the output terminals OUT00 to OUT23 are grouped. The top-side left LED board 94 is provided with LED modules 124a, 124b, 124c, and 124d.

LED module 124a and LED module 124b are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 124a has an anode connected to a cathode of each LED of the LED module 124b, and a cathode connected to each group 0 to 2 of the output terminals of the driver IC 124 (that is, the group of output terminals OUT00 to OUT02, the output terminals OUT03 to OUT05 group, output terminals OUT06 to OUT08 group).

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 124b. Each LED of the LED module 124a and each LED of the LED module 124b emit light or go out according to the duty ratio of each drive signal output from each group 0-2 of the output terminals of the driver IC124.

The LED module 124c and the LED module 124d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 124c has an anode connected to the cathode of each LED of the LED module 124d, and a cathode connected to each group 3 to 5 of the output terminals of the driver IC 124 (that is, the group of the output terminals OUT09 to OUT11, the output terminals OUT12 to OUT14 group, output terminals OUT15 to OUT17 group).

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 124d. Each LED of the LED module 124 c and each LED of the LED module 124 d emit light or go out according to the duty ratio of each drive signal output from each group 3 to 5 of the output terminals of the driver IC 124 .

<Top side right LED board>
In FIG. 19, the topside right LED board 93 has the driver IC 125 with 13H set as the driver address as described above. Since the driver IC 125 has the same configuration as the driver IC 127 described with reference to FIG. 13, detailed description thereof will be omitted.

The driver IC 125 is set with 13H as a driver address by the address setting terminals A0 to A5. Therefore, driver IC 125 functions as a slave driver. Since drive data is input to the driver IC 125 from the driver IC 123 of the top center LED substrate 90 by two-wire serial LVDS, the input setting terminal MODE is connected to the ground line and set to the Low level.

Input terminals SCL_INp, SCL_INn, SDA_INp, SDA_INn of the driver IC 125 are connected to relay output terminals SCL_OUTp, SCL_OUTn, SDA_OUTp, SDA_OUTn of the driver IC 123 of the top central LED board 90, respectively.

The driver IC 125 is set to the first mode in which the output terminals OUT00 to OUT23 are grouped. The top-side right LED board 93 is provided with LED modules 125a, 125b, 125c, and 125d.

The LED module 125a and the LED module 125b are full-color LEDs with red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 125a has an anode connected to a cathode of each LED of the LED module 125b, and a cathode connected to each group 0 to 2 of the output terminals of the driver IC 125 (that is, the group of the output terminals OUT00 to OUT02, the output terminals OUT03 to OUT05 group, output terminals OUT06 to OUT08 group).

A driving voltage of 12 V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 125b. Each LED of the LED module 125a and each LED of the LED module 125b emit light or extinguish according to the duty ratio of each drive signal output from each group 0-2 of the output terminals of the driver IC125.

The LED module 125c and the LED module 125d are full-color LEDs having red (R) LEDs, green (G) LEDs, and blue (B) LEDs. Each LED of the LED module 125c has an anode connected to the cathode of each LED of the LED module 125d, and a cathode connected to each group 3 to 5 of the output terminals of the driver IC 125 (that is, the group of the output terminals OUT09 to OUT11, the output terminals OUT12 to OUT14 group, output terminals OUT15 to OUT17 group).

A driving voltage of 12V supplied from the sub relay board 69 is supplied to the anode of each LED of the LED module 125d. Each LED of the LED module 125 c and each LED of the LED module 125 d emit light or go out according to the duty ratio of each drive signal output from each group 3 to 5 of the output terminals of the driver IC 125 .

In this embodiment, the LEDs connected to the output terminals OUT00 to OUT23 of the master driver and the slave driver all adopt a static lighting method with little LED flickering. Also, in order to reduce the number of harnesses, a dynamic lighting method may be employed to drive and control the LEDs.

<Specific example of data output from the sub CPU to each driver>
Specific examples of data output from the sub CPU 120 to each driver will be described below with reference to FIGS. 20 to 23. FIG.

As described above, data including a driver address (first byte), a register address (second byte), and a register value (third and subsequent bytes) are serially input to each driver of the driver ICs 121 to 131 .

FIG. 20 shows the LED modules 126a, 126b, 126c, 126d, 126e, 126f, 126g, 126h, 126i, 126j, 126k, 126m, 126n, 126p connected to the driver IC 126 of the side left LED board 92 (see FIG. 17). shows a first example of data for controlling the .

In FIG. 20, the driver address 14H of the driver IC 126 is set in the first byte of the data. 00H is set as the register address in the second byte of the data.

Therefore, the third byte of the data contains the register value of the register at the register address 00H (hereinafter, the register specified by the register address is referred to as "register 00H", etc.), and the fourth and subsequent bytes of the data contains the register Register values after 01H are set respectively.

With this data, B0H is set in the register 00H. Therefore, a predetermined bit (7th bit, BIT6) of the internal setting register 00H is set to 1, so that all the output terminals OUT00 to OUT23 of the driver IC 126 are enabled.

Also, since a predetermined bit (8th bit, BIT7) of the internal setting register 00H is set to 0, the driver IC 126 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped.

This data also sets registers 01H-03H, 07H-09H, 0DH-0FH and 13H-15H to 00H, and registers 04H-06H, 0AH-0CH and 10H-12H to FFH.

That is, according to this data, drive signals with a duty ratio of 0% are output from the output terminals OUT00 to OUT02, OUT06 to OUT08, OUT12 to OUT14, and OUT18 to OUT20 of the driver IC 126 (the output of the drive signals is stopped). Driving signals having a duty ratio of 100% are output from the output terminals OUT03 to OUT05, OUT09 to OUT11 and OUT15 to OUT17.

As a result, the LED modules 126a, 126b, 126e, 126f, 126i, 126j, 126n, 126p are turned off and the LED modules 126c, 126d, 126g, 126h, 126k, 126m are turned on with the highest brightness.

FIG. 21 shows the LED modules 126a, 126b, 126c, 126d, 126e, 126f, 126g, 126h, 126i, 126j, 126k, 126m, 126n, 126p connected to the driver IC 126 of the side left LED board 92 (see FIG. 17). shows a second example of data for controlling the .

In FIG. 21, the driver address 14H of the driver IC 126 is set in the first byte of the data. 00H is set as the register address in the second byte of the data. Therefore, the register value of register 00H is set in the third byte of data, and the register value of register 01H and subsequent bytes is set in the fourth and subsequent bytes of data.

With this data, B0H is set in the register 00H. Therefore, a predetermined bit (7th bit, BIT6) of the internal setting register 00H is set to 1, so that all the output terminals OUT00 to OUT23 of the driver IC 126 are enabled.

Also, since a predetermined bit (8th bit, BIT7) of the internal setting register 00H is set to 0, the driver IC 126 is set to the second mode in which the output terminals OUT00 to OUT23 are not grouped.

This data also sets registers 02H, 03H, 05H, 06H, 08H, 09H, 0BH, 0CH, 0EH, 0FH, 11H, 12H, 14H and 15H to 00H and registers 01H, 04H, 07H, 10H and 13H. , 0AH, 0DH, 10H and 13H are set to FFH.

That is, according to this data, drive signals with a duty ratio of 0% are output from the output terminals OUT01, OUT02, OUT04, OUT05, OUT07, OUT08, OUT10, OUT11, OUT13, OUT14, OUT16, OUT17, OUT19, and OUT20 of the driver IC 126 ( output of the drive signal is stopped), and a drive signal having a duty ratio of 100% is output from the output terminals OUT00, OUT03, OUT06, OUT09, OUT12, OUT15, and OUT18 of the driver IC 126 .

As a result, each LED module 126b, 126d, 126f, 126h, 126j, 126m, 126p has a green (G) LED and a blue (B) LED connected to each of these green (G) LEDs and a blue (B) LED. The green (G) and blue (B) LEDs of each LED module 126a, 126c, 126e, 126g, 126i, 126k, 126n are extinguished.

Red (R) LEDs of the LED modules 126b, 126d, 126f, 126h, 126j, 126m, and 126p, and LED modules 126a, 126c, 126e, 126g, 126i, and 126k connected to these red (R) LEDs. , 126n red (R) LEDs light up with the highest brightness.

22 shows the LED modules 126a, 126b, 126c, 126d, 126e, 126f, 126g, 126h, 126i, 126j, 126k, 126m, 126n, 126p connected to the driver IC 126 of the side left LED board 92 (see FIG. 17). shows a third example of data for controlling the .

In FIG. 22, the driver address 14H of the driver IC 126 is set in the first byte of the data. 10H is set as the register address in the second byte of the data. Therefore, the register value of the register 10H is set in the 3rd byte of the data, and the register value of the register 11H and the subsequent bytes is set in the 4th and subsequent bytes of the data.

This data also sets register 10H to 00H, register 11H to FFH, and register 12H to 00H. The values of other registers, including register 00H for internal settings, are maintained.

That is, according to this data, a drive signal with a duty ratio of 0% is output from the output terminals OUT15 and OUT17 of the driver IC 126 (same state as the drive signal is OFF), and a drive signal with a duty ratio of 100% is output from the output terminal OUT16 of the driver IC 126. A drive signal is output.

As a result, the red (R) and blue (B) LEDs of LED module 126m and the red (R) and blue (B) LEDs of LED module 126k connected to each of these red (R) and blue (B) LEDs. LED goes out.

Also, the green (R) LED of the LED module 126m and the green (R) LED of the LED module 126k connected to this green (R) light up with the highest luminance. The lighting state of each LED of the LED modules other than the LED modules 126k and 126m is maintained.

23 shows the LED modules 126a, 126b, 126c, 126d, 126e, 126f, 126g, 126h, 126i, 126j, 126k, 126m, 126n, 126p connected to the driver IC 126 of the side left LED board 92 (see FIG. 17). 4 shows a fourth example of data controlling the .

In FIG. 23, the driver address 14H of the driver IC 126 is set in the first byte of the data. 00H is set as the register address in the second byte of the data.

Therefore, the register value of register 00H is set in the third byte of the data. With this data, 00H is set in the register 00H. Therefore, a predetermined bit (7th bit, BIT6) of the internal setting register 00H is set to 0, so that all the output terminals OUT00 to OUT23 of the driver IC 126 are disabled.

Therefore, according to this data, all the output terminals OUT00 to OUT23 of the driver IC 126 are turned off (the same state as when a drive signal with a duty ratio of 0% is output), and the LED modules 126a, 126b, 126c and 126d are turned off. , 126e, 126f, 126g, 126h, 126i, 126j, 126k, 126m, 126n, 126p are extinguished.

In the present embodiment, an example of outputting drive data from the sub CPU 120 to the master driver in a three-wire serial manner, outputting the drive data from the master driver to the slave driver, and outputting the drive data from the slave driver to another slave driver. As described above, the drive data may be output from the sub CPU 120 to the master driver using a two-wire serial LVDS, and the drive data from the master driver to the slave driver and the drive data from the slave driver to another slave driver. It may be output by 3-line serial.

<Various effects>
As described above, the gaming machine 1 according to the embodiment of the present invention has a plurality of output terminals in order to reduce the switching noise emitted from each of the driver ICs 121 to 122 and 126 to 131 set to the second mode. In order to prevent the drive signals from interfering between the plurality of output terminals OUT00 to OUT23 by starting to output drive signals from the plurality of output terminals OUT00 to OUT23 with different phases sequentially from OUT00 to OUT23, light emission is performed. It is possible to prevent the light emission of each LED as a body from flickering.

In addition, in the gaming machine 1 according to the embodiment of the present invention, in order to reduce switching noise emitted from each of the driver ICs 123 to 125 set to the first mode, a group of the plurality of output terminals OUT00 to OUT23 sequentially phases. By starting to output the driving signal from the plurality of output terminals OUT00 to OUT23 with different values, the light emission of each LED flickers in order to prevent the driving signal from interfering between the groups of the plurality of output terminals OUT00 to OUT23. can be prevented.

Further, in the gaming machine 1 according to the embodiment of the present invention, when the plurality of LEDs connected to the plurality of output terminals OUT00 to OUT23 of the respective driver ICs 121 to 131 are set to a non-light emitting (extinction) state, each LED without controlling the driver ICs 121 to 131 with the driving data to put the . Since each of the driver ICs 121 to 131 can be controlled by drive data of 0, control by the sub CPU 120 can be simplified.

In addition, the gaming machine 1 according to the embodiment of the present invention transfers the drive data between the driver ICs 121 to 131 by the two-wire serial LVDS, which is a differential signal that is more resistant to noise than a general serial signal. In order to prevent noise from being mixed in the line that transmits the drive data between the driver ICs 121 to 131, it is necessary to prevent each LED from emitting light in a light emission pattern different from the light emission pattern represented by the drive data (so-called malfunction). can be done.

Further, in the gaming machine 1 according to the embodiment of the present invention, since the drive circuit of the master driver IC 121 is an open drain output, it is possible to secure the expandability of the functions, and the drive circuits of the slave driver ICs 122 to 131 can be fixed. Since it is a current sink output, current consumption can be suppressed.

In addition, the game machine 1 according to the embodiment of the present invention transfers the drive data between the driver ICs 121 to 131 by the data positive and data negative pair lines that are more noise-resistant than the single-end system, and the clock signal is more noise-resistant than the single-end system. Since the drive data synchronization clock is transferred between the driver ICs 121 to 131 on positive and clock negative pair lines, it is possible to prevent noise from entering each line that transmits drive data and clocks between the driver ICs 121 to 131. Therefore, it is possible to prevent each LED from emitting light in a light emission pattern different from the light emission pattern represented by the drive data.

In addition, in the game machine according to the present invention, each of the driver ICs 121 to 131 outputs drive data by one-way communication, so the load on the sub CPU 120 and the driver of the relay destination to return a response signal such as ACK is reduced. be able to.

Further, in the gaming machine according to the present invention, when all the slave driver ICs 122 to 131 are initialized, the master driver ICs 122 to 131 are not controlled by the data for initializing the slave driver ICs 122 to 131. All the slave driver ICs 122 to 131 can be initialized by inputting a pulse of 200 ns or more to the input terminal SCL_INn (chip select input) of the IC 121, so that the control at the time of driver initialization by the sub CPU 120 can be simplified. can be done.

Although the case where the embodiment of the present invention is applied to a pachislot machine has been described above, the present invention can also be applied to other gaming machines (for example, pachinko machines, slot machines, etc.).

[Other expandability of the gaming machine according to the present invention]
In the pachi-slot (gaming machine 1) of the above embodiment, the medal insertion operation of the player (that is, the operation of inserting the medals on hand into the medal insertion slot DD5, or the credited medals are pushed to the MAX bet button DD8 or A game is started by operating a 1-bet button to insert a bet, and if medals are to be paid out at the end of the game, the hopper device HP is driven to pay out the medals from the medal payout opening DD14. Alternatively, although a form of credit has been described, the present invention is not limited to this.

For example, for all forms in which a player inserts game media necessary for a game, a game is played based on it, and a privilege is awarded (for example, medals are paid out) based on the result of the game, The present invention can be applied. In other words, not only is the game medium inserted (played) and paid out by the player's physical actions, but also the main control circuit (main control board 71) itself receives the game medium held by the player. It may be managed electromagnetically and may be played without medals. In this case, it is the game medium management device mounted (connected) to the main control circuit (main control board 71) and managing the game medium that electromagnetically manages the game medium held by the player. good too.

In this case, the game medium management device has ROM and RWM (or RAM), is provided in the game machine, and is capable of two-way communication with an external game medium handling device (not shown) via a predetermined interface. is connected to the game medium lending operation (that is, the action of providing the necessary game medium when the player performs the operation of inserting the game medium) or winning a prize related to the payout of the game medium (the relevant game media payout operation (that is, the operation of acquiring the game media necessary for paying out the game media to the player) in the case where the combination is established), or the game media used for the game are electromagnetically generated. It is sufficient that the operation of recording can be performed in real time. The game medium management device not only manages the actual number of game media, but also displays the number of owned game media (not shown) for displaying the number of game media owned, for example, based on the management result of the number of game media. may be provided on the front surface of the pachi-slot (gaming machine 1) to manage the number of game media displayed on the display device for the number of owned game media. In other words, the game media management device may record and display the total number of game media that a player can use for games by an electromagnetic method.

In this case, the game medium management device may have a performance (function) that allows the player to freely transmit a signal indicating the number of recorded game media to an external game medium handling device. desirable. In addition, it is desirable that the game medium management device has a performance that does not allow the number of recorded game mediums to be reduced except when directly operated by the player. Also, if an external connection terminal board (not shown) is provided between the game medium management device and the external game medium handling device, the game medium management device can It is desirable for a player to have the ability to not send a signal indicating the number of game media recorded.

In addition to the above, the game machine is provided with lending operation means, return (settlement) operation means, and an external connection terminal board that can be operated by the player. Slots for recording media (e.g. IC cards), non-contact communication antennas for depositing electronic money, etc., from mobile terminals, various operation means such as lending operation means, return operation means, etc., and external connections on the game media handling device side A terminal board may be provided (neither shown).

As a game flow at that time, for example, the player deposits valuable value into the game medium handling device by any of the above methods, and a predetermined number of valuable values is subtracted, and the game media corresponding to the subtracted valuable value are increased from the game media handling device to the game media management device. Then, the player plays the game, and repeats the above operation when the game medium is required. After that, as a result of the game, a predetermined number of game media are obtained, and when the game is finished, the game media management device sends the game media handling device the number of game media by operating one of the return operation means. , and the game medium handling device ejects the recording medium recording the number of game media. Also, when the game medium management device transmits the number of game media, it clears the number of game media stored in itself. The player takes the ejected recording medium to a prize counter or the like to exchange for prizes, or moves the game machine to play a game on another game machine based on the recorded game medium.

In the above example, the total number of game media was transmitted from the game media management device to the game media handling device. The game media possessed by the player may be divided and processed. Also, in the above example, the game medium handling device ejects the recording medium, but cash or cash equivalents may be ejected, or may be stored in a portable terminal or the like. Further, the game medium handling device may be configured so that the member recording medium of the game parlor can be inserted, the game medium is stored in the member recording medium, and the stored game medium can be used to play again at a later date. .

Also, in the game machine or the game medium handling device, by operating a predetermined operation means (not shown), it is possible to perform a lock operation to lock the game medium or valuable value data communication to the game medium handling device or the game medium management device. may be In this case, information that only the player can know, such as a one-time password, may be set, or the player may be stored by imaging means provided in the game machine or game medium handling device.

As described above, the game medium management device may allow the game to be played only without medals, or the game medium may be inserted (played) by a physical action of the player, and the game medium may be released. The game may be played in both a payout mode and a mode in which the game can be played without medals. In the latter case, the game medium management device may adopt a method of directly controlling the medal selector 46 and the hopper device HP described above, or these may be controlled by the main control circuit (main control board 71). It is also possible to employ a system that can electromagnetically record and display the total number of game media that a player can use for a game based on the transmission of the control result.

Further, in the above example, the game medium management device is applied to pachislot, but for example, a slot machine using game balls or a sealed game machine may be provided with a game medium management device in the same way, and a player can use the game medium management device. of game media can be managed.

When the above-described game medium management device is provided, the number of devices such as the medal selector 46 and the hopper device HP inside the game machine can be reduced compared to the case where the game media are physically provided for the game. Not only can the cost and manufacturing cost of the machine be reduced, the player can be prevented from directly contacting the game medium, the game environment can be improved, the noise can be reduced, and the number of devices can be reduced. It is also possible to reduce the power consumption of the machine. Further, when the above-described game medium management device is provided, it is possible to prevent fraudulent actions through the game medium or the slot for inserting or paying out the game medium. That is, when the game medium management device described above is provided, it is possible to provide a gaming machine capable of improving various environments surrounding the gaming machine.

[Summary of Invention]
<Summary 1>
Japanese Patent Application Laid-Open No. 2007-282925 proposes that LED lighting control is performed in accordance with an image or a sound effect by setting a duty ratio for a drive signal for a performance LED and performing PWM control.

In PWM control, switching noise occurs when ON/OFF control is performed on the output signal output from the output terminal of the LED driver IC. Therefore, when a plurality of output terminals are ON/OFF-controlled simultaneously, output signals may interfere with each other due to switching noise emitted from the respective terminals, causing flickering of light emitted from a light emitter such as a performance LED.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a game machine capable of preventing flickering of light emitted from a light emitter.

The game machine according to the present invention is
a plurality of light emitters (each LED of each LED module);
Drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs driving data to the driver and controls it,
The driver is
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
a plurality of output terminals (OUT00 to OUT23) for driving the light emitter;
PWM control means (drivers 121 to 131) for PWM-controlling drive signals output from each of the plurality of output terminals based on drive data input to the input terminals;
and a delay means (drivers 121 to 131) capable of delaying the drive signal PWM-controlled by the PWM control means,
The delay means has a configuration capable of starting to output the drive signal from the plurality of output terminals with different phases among the plurality of output terminals.

With this configuration, the amusement machine according to the present invention sequentially changes the phase between the plurality of output terminals in order to reduce the switching noise emitted from the driver that drives the light emitter, and outputs the drive signal from the plurality of output terminals. By starting , it is possible to prevent the light emission of the light emitter from flickering because the drive signals are prevented from interfering between the plurality of output terminals.

According to the present invention, it is possible to provide a game machine capable of preventing flickering of light emitted from a light emitter.

<Summary 2>
In order to solve the same problem as in Summary 1, the gaming machine according to the present invention
a plurality of light emitters (each LED of each LED module);
Drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs driving data to the driver and controls it,
The driver is
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
a plurality of output terminals (OUT00 to OUT23) for driving the light emitter;
PWM control means (drivers 121 to 131) for PWM-controlling drive signals output from each of the plurality of output terminals based on drive data input to the input terminals;
delay means (drivers 121 to 131) capable of delaying the drive signal PWM-controlled by the PWM control means;
mode setting means capable of setting the delay means to either a first mode in which the plurality of output terminals are grouped into groups of a predetermined number of terminals or a second mode in which the plurality of output terminals are not grouped; Each driver 121 to 131), and
The delay means is
In the first mode, it is possible to start outputting the drive signals from the plurality of output terminals with different phases between the groups,
In the second mode, the driving signal can be started to be output from the plurality of output terminals with different phases among the plurality of output terminals.

With this configuration, when the delay means is in the second mode, the gaming machine according to the present invention sequentially shifts the phase between the plurality of output terminals in order to reduce switching noise emitted from the driver that drives the light emitter. By starting to output drive signals from a plurality of output terminals differently, it is possible to prevent the drive signals from interfering with each other between the plurality of output terminals, thereby preventing flickering of light emitted from the light emitter.

Further, in the gaming machine according to the present invention, when the delay means is in the first mode, phases are sequentially shifted between groups of the plurality of output terminals in order to reduce switching noise emitted from the driver that drives the light emitter. By starting to output drive signals from different output terminals, it is possible to prevent the drive signals from interfering between the groups of output terminals, thereby preventing flickering of light emitted from the light emitter. .

According to the present invention, it is possible to provide a game machine capable of preventing flickering of light emitted from a light emitter.

<Summary 3>
In order to solve the same problem as in Summary 1, the gaming machine according to the present invention
a plurality of light emitters (e.g., each LED of each LED module);
Drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs driving data to the driver and controls it,
The driver is
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
a plurality of output terminals (OUT00 to OUT23) for driving the light emitter;
PWM control means (drivers 121 to 131) for PWM-controlling drive signals output from each of the plurality of output terminals based on drive data input to the input terminals;
and a delay means (drivers 121 to 131) capable of delaying the drive signal PWM-controlled by the PWM control means,
The delay means can start outputting the drive signal from the plurality of output terminals with different phases among the plurality of output terminals,
The driver has a predetermined value (0) at a predetermined position (a position corresponding to a predetermined bit (7th bit, BIT6) of an internal setting register (address 00H)) of the drive data input to the input terminal. , the configuration is such that the plurality of light emitters connected to the plurality of output terminals are brought into a non-light emitting state.

With this configuration, the amusement machine according to the present invention sequentially changes the phase between the plurality of output terminals in order to reduce the switching noise emitted from the driver that drives the light emitter, and outputs the drive signal from the plurality of output terminals. By starting , it is possible to prevent the light emission of the light emitter from flickering because the drive signals are prevented from interfering between the plurality of output terminals.

In addition, the gaming machine according to the present invention controls the driver by driving data that causes each light emitter to be in a non-light-emitting state when the plurality of light-emitting bodies connected to the plurality of output terminals of the driver are brought into a non-light-emitting state. Since the driver can be controlled by the drive data in which the value of the predetermined position is the predetermined value, the control by the control unit can be simplified.

According to the present invention, it is possible to provide a game machine capable of preventing flickering of light emitted from a light emitter.

<Summary 4>
As a game machine of this type, Japanese Patent Application Laid-Open No. 2017-143854 proposes a game machine in which an LED driver IC connected to a sub-controller through serial communication drives a performance LED under the control of the sub-controller.

In general, serial communication is susceptible to noise, and when driving data for light emitters such as LEDs for performance is transmitted over a serial line, noise mixed in the serial line causes the LED driver IC to malfunction, resulting in a light emission pattern represented by the drive data. In some cases, the problem of driving the light emitter with a different light emission pattern may occur.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a game machine capable of preventing light emitters from emitting light in a light emission pattern different from the light emission pattern represented by drive data. do.

The game machine according to the present invention is
a plurality of light emitters (LEDs of an LED module);
a plurality of drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs drive data for driving the light emitter to the driver and controls it,
The driver is composed of a master driver (driver 121) connected to the control unit and a plurality of slave drivers (drivers 122 to 131),
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
address setting terminals (A0 to A5) capable of setting driver addresses;
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
an input setting terminal (MODE) capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit (drivers 121 to 131) that outputs drive data input to the input terminals as differential signals;
and a drive circuit (each driver 121 to 131) for driving the light emitter,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. A drive signal for driving the light emitter is output from the circuit.

With this configuration, the gaming machine according to the present invention transfers the drive data between the drivers using a differential signal that is more resistant to noise than a general serial signal. In order to prevent the mixing, it is possible to prevent the light emitter from emitting light in a light emission pattern different from the light emission pattern represented by the drive data.

According to the present invention, it is possible to provide a game machine capable of preventing a light emitter from emitting light in a light emission pattern different from the light emission pattern represented by drive data.

<Summary 5>
In order to solve the same problem as the gist 4, the gaming machine according to the present invention
a plurality of light emitters (LEDs of an LED module);
a plurality of drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs drive data for driving the light emitter to the driver and controls it,
The driver is composed of a master driver (driver 121) connected to the control unit and a plurality of slave drivers (for example, drivers 122 to 131),
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
address setting terminals (A0 to A5) capable of setting driver addresses;
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
an input setting terminal (MODE) capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit (drivers 121 to 131) that outputs drive data input to the input terminals as differential signals;
A drive circuit (for example, each driver 121 to 131) for driving the light emitter,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. outputting a drive signal for driving the light emitter from the circuit;
the drive circuit of the master driver has an open drain output;
The drive circuit of the slave driver has a constant current sink output configuration.

With this configuration, the gaming machine according to the present invention transfers the drive data between the drivers using a differential signal that is more resistant to noise than a general serial signal. In order to prevent the mixing, it is possible to prevent the light emitter from emitting light in a light emission pattern different from the light emission pattern represented by the drive data.

Further, in the gaming machine according to the present invention, since the driving circuit of the master driver is an open-drain output, it is possible to ensure expandability of functions, and since the driving circuit of the slave driver is a constant-current sink output, can be suppressed.

According to the present invention, it is possible to provide a game machine capable of preventing a light emitter from emitting light in a light emission pattern different from the light emission pattern represented by drive data.

<Summary 6>
In order to solve the same problem as the gist 4, the gaming machine according to the present invention
a plurality of light emitters (LEDs of an LED module);
a plurality of drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs drive data for driving the light emitter to the driver and controls it,
The driver is composed of a master driver (driver 121) connected to the control unit and a plurality of slave drivers (for example, drivers 122 to 131),
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
address setting terminals (A0 to A5) capable of setting driver addresses;
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
an input setting terminal (MODE) capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit (drivers 121 to 131) that outputs drive data input to the input terminals as differential signals;
A drive circuit (for example, each driver 121 to 131) for driving the light emitter,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. outputting a drive signal for driving the light emitter from the circuit;
Between each driver of the master driver and the slave driver,
a data positive and data negative pair line for transmitting the driving data;
It is connected by a clock positive and clock negative pair line for transmitting a synchronization clock for driving data transmitted by the data positive and data negative pair lines.

With this configuration, the gaming machine according to the present invention transfers the drive data between the drivers using a differential signal that is more resistant to noise than a general serial signal. In order to prevent the mixing, it is possible to prevent the light emitter from emitting light in a light emission pattern different from the light emission pattern represented by the drive data.

In addition, the gaming machine according to the present invention transfers drive data between drivers using data positive and data negative pair lines that are more resistant to noise than the single-end system, and transfers drive data using the pair lines of clock positive and clock negative that are resistant to noise. In order to transfer the synchronizing clock of the drive data between the drivers, in order to prevent noise from entering each line that transmits the drive data and the clock between the drivers, a light emission pattern different from the light emission pattern indicated by the drive data is used. It is possible to prevent the light emitter from emitting light.

According to the present invention, it is possible to provide a game machine capable of preventing a light emitter from emitting light in a light emission pattern different from the light emission pattern represented by drive data.

<Summary 7>
In order to solve the same problem as the gist 4, the gaming machine according to the present invention
a plurality of light emitters (LEDs of an LED module);
a plurality of drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs drive data for driving the light emitter to the driver and controls it,
The driver is composed of a master driver (driver 121) connected to the control unit and a plurality of slave drivers (for example, drivers 122 to 131),
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
address setting terminals (A0 to A5) capable of setting driver addresses;
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
an input setting terminal (MODE) capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit (drivers 121 to 131) that outputs drive data input to the input terminals as differential signals;
A drive circuit (for example, each driver 121 to 131) for driving the light emitter,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. outputting a drive signal for driving the light emitter from the circuit;
The output circuit of each driver of the master driver and the slave driver is configured to output drive data input to the input terminal through one-way communication.

With this configuration, the gaming machine according to the present invention transfers the drive data between the drivers using a differential signal that is more resistant to noise than a general serial signal, thereby eliminating noise in the lines that transmit the drive data between the drivers. In order to prevent the mixing, it is possible to prevent the light emitter from emitting light in a light emission pattern different from the light emission pattern represented by the drive data.

In addition, in the gaming machine according to the present invention, the output circuit of each driver outputs the driving data by one-way communication, so that it is possible to reduce the load required for returning a response signal such as ACK to the relay destination driver. .

According to the present invention, it is possible to provide a game machine capable of preventing a light emitter from emitting light in a light emission pattern different from the light emission pattern represented by drive data.

<Summary 8>
In order to solve the same problem as the gist 4, the gaming machine according to the present invention
a plurality of light emitters (LEDs of an LED module);
a plurality of drivers (drivers 121 to 131) for driving the light emitters;
A control unit (sub CPU 120) that outputs drive data for driving the light emitter to the driver and controls it,
The driver is composed of a master driver (driver 121) connected to the control unit and a plurality of slave drivers (for example, drivers 122 to 131),
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
address setting terminals (A0 to A5) capable of setting driver addresses;
input terminals (SCL_INp, SCL_INn, SDA_INp, SDA_INn) for inputting the drive data by serial communication;
an input setting terminal (MODE) capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit (drivers 121 to 131) that outputs drive data input to the input terminals as differential signals;
A drive circuit (for example, each driver 121 to 131) for driving the light emitter,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. outputting a drive signal for driving the light emitter from the circuit;
Among data input (SDA_INp), clock input (SCL_INp), and chip select input (SCL_INn) included in the three-wire serial input, the master driver controls the chip select input for a certain time (for example, 200 ns) or more. When a pulse is input, the output circuit outputs a signal for initializing a slave driver connected directly to the output circuit or via another slave driver.

With this configuration, the gaming machine according to the present invention transfers the drive data between the drivers using a differential signal that is more resistant to noise than a general serial signal. In order to prevent the mixing, it is possible to prevent the light emitter from emitting light in a light emission pattern different from the light emission pattern represented by the drive data.

Further, in the gaming machine according to the present invention, when all the slave drivers are initialized, the chip select input of the master driver is not controlled by the data for initializing each slave driver, and the chip select input of the master driver is kept for a predetermined time or longer. Since all the slave drivers can be initialized by inputting the pulse, the control at the time of driver initialization by the controller can be simplified.

According to the present invention, it is possible to provide a game machine capable of preventing a light emitter from emitting light in a light emission pattern different from the light emission pattern represented by drive data.

1 Gaming machine 91a-91p, 103a, 103b, 104a-104f, 105a-105j, 106a-106c, 107a, 108a, 108b, 109a, 109b, 110a-110f, 111a-111f, 112a-112f, 123a-123d, 124a ~124d, 125a~125d, 126a~126p, 130a~130m, 131a~131m LED module 120 Sub CPU (control unit)
121 driver IC (driver, master driver)
122 to 131 driver IC (driver, slave driver)
A0 to A5 Address setting terminal MODE Input setting terminal OUT00 to OUT23 (output terminal)
SCL_INp input terminal (clock input)
SCL_INn input terminal (chip select input)
SDA_INp Input terminal (data input)
SDA_INn input terminal

Claims (1)

a plurality of light emitters;
a plurality of drivers for driving the light emitters;
a control unit that outputs drive data for driving the light emitter to the driver and controls the driver;
The driver is composed of a master driver connected to the control unit and a plurality of slave drivers,
the plurality of slave drivers are connected to the master driver directly or via other slave drivers;
Each driver of the master driver and the slave driver,
an address setting terminal capable of setting a driver address;
an input terminal for inputting the driving data by serial communication;
an input setting terminal capable of setting whether to input the drive data to the input terminal as a differential signal or as a three-wire serial;
an output circuit that outputs drive data input to the input terminal as a differential signal;
and a drive circuit for driving the light emitter,
The drive circuit is
a plurality of output terminals;
PWM control means for PWM-controlling the drive signal output from each of the plurality of output terminals based on the drive data input to the input terminal;
a delay means capable of delaying the drive signal PWM-controlled by the PWM control means;
mode setting means capable of setting the delay means to either a first mode in which the plurality of output terminals are grouped into groups of a predetermined number of terminals or a second mode in which the plurality of output terminals are not grouped; , and
The delay means is
In the first mode, it is possible to start outputting the drive signals from the plurality of output terminals with different phases between the groups,
In the second mode, it is possible to start outputting the drive signal from the plurality of output terminals with different phases among the plurality of output terminals,
The control unit outputs the drive data to the master driver by the three-wire serial method,
the input setting terminal of the master driver is set so as to input the drive data to the input terminal in a three-wire serial manner;
wherein the input setting terminals of the slave driver are set so as to input the drive data to the input terminals as differential signals;
Each driver of the master driver and the slave driver performs the driving based on the driving data when the driver address of the driving data input to the input terminal matches the driver address set by the address setting terminal. outputting a drive signal for driving the light emitter from the circuit;
Between each driver of the master driver and the slave driver,
a data positive and data negative pair line for transmitting the driving data;
connected by a clock positive and clock negative pair line for transmitting a synchronization clock for driving data transmitted by the data positive and data negative pair lines ;
Each driver of the master driver and the slave driver is configured to change the value of the driving data input to the input terminal to a value other than the predetermined position when the value of the driving data input to the input terminal is a predetermined value at the predetermined position. Regardless, the plurality of light emitters respectively connected to the plurality of output terminals are set to a non-light emitting state.
A gaming machine characterized by:

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