JP2011011061A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine reducing the number of connecting lines for connecting a group integrated control means to a group unit control means, besides accurately resettable at a high speed even if a failure occurs in data transmission/reception between the group integrated control means and the group unit control means.SOLUTION: This game machine includes a plurality of performance devices which produce a special game state corresponding to the result of an assist game to be executed in a game area and execute performances related to the game, and, when determining that data transmission is failed, simultaneously commands the initialization to all the group unit control means controlled by the group integrated control means.

Description

  The present invention relates to a gaming machine including a plurality of group unit control means for controlling the effect devices divided into groups and a group overall control means for controlling the plurality of group unit control means, and more particularly to an initialization method for the group unit control means.

  As a gaming machine that can simplify the wiring between the sub-relay board and the illumination board, the top LED central board arranged in the center of the top illumination area is serially connected to the sub-relay board, and the top illumination A gaming machine having a configuration in which a top LED right substrate disposed on the right side of the region and a top LED left substrate disposed on the left side of the top illumination region are separated from the top LED central substrate and connected by wiring. . Thereby, the number of wirings from the sub relay board to the top illumination area can be reduced to simplify the wiring (for example, see Patent Document 1).

  In this gaming machine, as described in paragraph [0066] of Patent Document 1, a serial LED circuit is mounted on the top LED board, and terminals A0, A1, and A2 of the serial parallel converter circuit IC are mounted on the top LED board. Since the address of the top LED substrate is set according to the voltage to be connected, one of eight types of addresses can be set for each top LED substrate in total.

JP 2008-212271 A

  The gaming machine described in Patent Document 1 has a configuration in which a plurality of top LED boards are individually selected and transmitted to the effect control information by the sub-relay board, so that different effect control information is set for each top LED board. It can be configured.

  However, in the gaming machine described in Patent Document 1, the sub-relay board cannot select a plurality of top LED boards at the same time and give an instruction for initialization, so the sub-relay board cannot initialize the top LED board at high speed. There is a problem.

  A first aspect of the present invention is a gaming machine comprising a plurality of effect devices for generating a special game state corresponding to a result of an auxiliary game executed in a game area and performing effects related to a game, wherein the plurality of effect devices Group control means for controlling each of the plurality of group unit control means and providing group unit control means for controlling the effect devices belonging to the divided groups. And a timing signal line for transmitting a timing signal from the group overall control means to the group unit control means, and a data line for transmitting data between the group overall control means and the group unit control means, The group overall control means sets the signal level of the data line to a signal level corresponding to transmission data, and By repeatedly changing the signal level of the timing signal line, a transmission unit that sequentially transmits data to the group unit control unit and a plurality of group unit control units are simultaneously selected, and the group unit control is performed by the transmission unit. Effect control information transmission for individually selecting group initialization means for instructing means initialization and each group unit control means, and transmitting effect control information for specifying the output mode of the effect device by the transmitting means Means.

  According to a second aspect of the invention, the group initialization unit instructs initialization to the group unit control unit of the transmission destination by transmitting initialization instruction data to the group unit control unit, and the initialization instruction data and the effect Control information is transmitted to the plurality of group unit control means via the data line by the transmission means.

  According to the first invention, the effect control information transmitting means is configured to individually select a plurality of group unit control means and transmit the effect control information, so that the effect control information different for each group unit control means can be obtained. The configuration can be set. On the other hand, the group initializing means is configured to select a plurality of group unit control means at the same time and issue an initialization instruction, so that the plurality of group unit control means can be initialized at high speed.

  According to the second invention, since the initialization instruction data and the effect control information are both transmitted to the group unit control means via the same data line, the data line can be used effectively.

It is explanatory drawing of the game machine of the 1st Embodiment of this invention. It is a front view of the game board of the 1st embodiment of the present invention. It is a block diagram which shows the structure of the game machine of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the presentation control apparatus of the 1st Embodiment of this invention. It is explanatory drawing of the connection of the decoration control apparatus of the 1st Embodiment of this invention. It is a block diagram of the decoration control apparatus of the 1st Embodiment of this invention. 1 is a block diagram of an I ² CI / O expander according to a first embodiment of this invention. It is a circuit diagram around the I ² CI / O expander of the decoration control device that controls the decoration device of the first embodiment of the present invention. It is a circuit diagram around the I ² CI / O expander of the decoration control device that controls the accessory driving MOT and the accessory driving SOL of the first embodiment of the present invention. It is a circuit diagram of the connection line regarding the input / output of the relay board | substrate of the 1st Embodiment of this invention. It is a circuit diagram of the connection line regarding the input / output of the decoration control apparatus of the 1st Embodiment of this invention. It is explanatory drawing of the slave address contained in the data output to the decoration control apparatus from the presentation control apparatus of the 1st Embodiment of this invention. It is an explanatory view of I ² CI / O expander address table of the first embodiment of the present invention. It is a diagram for explaining a first embodiment of the I ² CI / O Aix work register assigned to the output setting register provided in expander of the present invention. It is explanatory drawing of the start condition and stop condition of the data which the master IC of the 1st Embodiment of this invention outputs via the connection line SDA and the connection line SCL. It is a timing chart which the decoration control apparatus into which the data output from the master IC of the 1st Embodiment of this invention was input outputs a reply signal. It is a timing chart of the signal level of the connection line SDA and the connection line SCL when the master IC of the first embodiment of the present invention outputs effect control data. When the master IC according to the first embodiment of the present invention designates the individual address of the slave and sets the effect control data in the decoration control device, the master IC is exchanged between the master IC and the I ² CI / O expander. It is a figure explaining the format of data. When the master IC according to the first embodiment of the present invention designates the individual address of the slave and sets the effect control data in the decoration control device, the master IC is exchanged between the master IC and the I ² CI / O expander. A specific numerical value is applied to the production control data. It is a figure explaining another form of presentation control data of a 1st embodiment of the present invention. When the master IC of the first embodiment of the present invention initializes the I ² CI / O expander, illustrating the data format of the initialization instruction data transmitted to I ² CI / O expander from the master IC FIG. It is a figure explaining the abnormality determination table of the 1st Embodiment of this invention. It is a flowchart of the process by the presentation control apparatus of the 1st Embodiment of this invention. It is a flowchart of the timer interruption process of the 1st Embodiment of this invention. It is a flowchart of the light emission control slave output process of the 1st Embodiment of this invention. It is a flowchart of the slave continuous processing of the 1st Embodiment of this invention. It is a flowchart of the slave reset process of the 1st Embodiment of this invention. It is a figure which shows the connection form of the decoration control apparatus 610 provided in the whole gaming machine of the 1st Embodiment of this invention. It is a figure explaining the 2nd Embodiment of this invention.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 is an explanatory diagram of a gaming machine 1 according to the first embodiment of this invention.

  A front frame (game frame) 3 of the gaming machine 1 is assembled to a main body frame (outer frame) 2 via a hinge 4 so as to be openable and closable on the front surface of the gaming machine 1. A game board 10 (see FIG. 2) is accommodated on the front side of the front frame 3. Further, a glass frame 18 provided with a cover glass (transparent member) covering the front surface of the game board 10 is attached to the front frame 3.

  A decorative member 9 that emits decorative light is provided around the cover glass of the glass frame 18. The decoration member 9 is provided with a decoration device 620 (see FIG. 4) made of a lamp, LED, or the like. The decoration device 620 emits light in a predetermined light emission mode, so that the decoration member 9 emits light in a predetermined light emission mode.

  Speakers 30 that emit sound (for example, sound effects) are provided on the left and right sides of the glass frame 18. An illumination unit 11 is provided above the glass frame 18. Inside the lighting unit 11, the above-described decoration device 620 is provided.

  On the right side of the lighting unit 11, an abnormality notification LED 29 for notifying that an abnormality has occurred in the gaming machine 1 is provided.

  The open / close panel 20 below the front frame 3 is provided with an upper tray 21 for supplying game balls to a not-shown ball hitting device, and the fixed panel 22 is provided with an ashtray 15, a lower plate 23, an operation unit 24 of the hit ball launching device, and the like. . The lower tray 23 is provided with a lower tray ball removing mechanism 16 for discharging the game balls stored in the lower tray 23. A key 25 for locking the glass frame 18 is provided on the lower right side of the front frame 3.

  Further, when the player turns the operation unit 24, the hitting ball launching device launches a game ball supplied from the upper plate 21.

  In addition, the upper edge portion of the upper plate 21 is provided with an effect button 17 for receiving an operation input from the player.

  When the player operates the effect button 17, the effect content of the special figure variation display game on the display device 53 (see FIG. 2) provided on the game board 10 is selected, and the special figure variation display game on the display device 53 is selected. In addition, it is possible to perform an effect in which the player's operation is intervened.

  In addition, in the special figure variation display game, the launched game ball is awarded to the first start winning opening 45 (see FIG. 2) provided in the game board 10 or the second starting winning opening of the normal variation winning apparatus 36 (see FIG. 2). It starts when you do. In the special figure fluctuation display game, a plurality of pieces of identification information are variably displayed on the display device 53. Then, when the identification information that has been variably displayed is stopped and the result mode of the stopped identification information is a specific result mode, the state of the gaming machine 1 is advantageous to the player (a state where a privilege is granted) Transition to a special gaming state.

  In the upper right portion of the upper plate 21, a ball lending button 26 that is operated when a player borrows a game ball and a discharge button 27 that is operated to discharge a prepaid card from a card unit (not shown) are provided. . Between these buttons 26 and 27, a balance display unit 28 for displaying the balance of the prepaid card is provided.

  FIG. 2 is a front view of the game board 10 according to the first embodiment of the present invention.

  The gaming machine 1 shown in FIG. 1 fires a game ball in an internal game area 10a (bounces it) to play a game, and a game area 10a is provided on the back side of the cover glass of the glass frame 18. The game board 10 which comprises is installed.

  The game board 10 includes a flat game board main body 10b (made of wood or synthetic resin) serving as a mounting base for various members, and has a game area 10a surrounded by a guide rail 32 on the front surface of the game board main body 10b. ing. Further, front structural members 33, 33,... Are attached to the front surface of the game board main body 10b and outside the guide rail 32. Then, a game ball (hit ball; game medium) is launched from the launching device into the game area 10a surrounded by the guide rail 32 to play a game.

  A center case 51 that forms a window 52 serving as a display area for a special figure variation display game is attached to the approximate center of the game area 10a. Behind the window portion 52 formed in the center case 51, a display device 53 is provided as an effect display device capable of executing an effect of a special figure variable display game that displays a plurality of identification information in a variable manner. ing. The display device 53 includes, for example, a liquid crystal display, and is arranged so that a display portion 53 a whose display contents can be changed is visible from the front side of the game board 10 through the window portion 52 of the center case 51. . Note that the display device 53 is not limited to a device including a liquid crystal display, and may include a display such as an EL or a CRT.

  Near the upper end of the window 52 of the center case 51, a movable accessory 60 that can be operated based on the gaming state is attached.

  In addition, the game board 10 is provided with a general map start gate 34, a general map storage display 47 for displaying the number of unprocessed times of the general map change display game, and a general map display 35 for displaying the general map change display game. ing. Further, in the game area 10a, a first start winning opening 45 forming a first start winning area and a normal variable winning apparatus 36 having a second starting winning opening forming a second start winning area are provided. ing. When the game ball has won the first start winning opening 45, the first special figure variation display game is executed as an auxiliary game, and when the game ball has won the normal variation prize winning device 36, the second game is performed as an auxiliary game. A special figure variation display game is executed.

  Further, the game board 10 is provided with a first special figure display 38 for displaying the first special figure fluctuation display game, and a second special figure display 39 for displaying the second special figure fluctuation display game. Yes. In addition, the first special figure storage display 48 for displaying the number of unprocessed times of the first special figure variation display game (first special figure start memory), and the number of unprocessed times of the second special figure fluctuation display game (second special figure). A second special figure memory display 49 for displaying (starting memory) is provided. It should be noted that the common figure memory display 47, the universal figure display 35, the first special figure display 38, the second special figure display 39, the first special figure storage display 48, and the second special figure storage display 49 are: Together with a game state display LED (not shown) representing the game state, it is integrally provided as a segment LED.

  Furthermore, the game area 10a has an attacker-type opening / closing door 42a that can be opened by rotating in a direction in which the upper end side is tilted toward the front side, and the first special figure variation display game and the second special figure variation display game. As a result, the special variable winning device 42 for converting the closed state (a disadvantageous state for the player) from the closed state (a disadvantageous state for the player) to the open state (a state advantageous for the player), and the game balls that have not won the winning point etc. An out-hole 43 to be collected is provided. In addition, the game area 10a is provided with general winning holes 44, 44,..., A windmill 46 as a batting direction changing member, a number of obstacle nails (not shown), and the like.

  A gate SW 34a (see FIG. 3) for detecting a game ball that has passed through the general chart start gate 34 is provided in the general chart start gate 34. Then, when the game ball that has been driven into the game area 10a passes through the usual figure start gate 34, a usual figure change display game is performed.

  In addition, when the game ball passes through the general chart start gate 34 in a state in which the normal map change display game cannot be started, if the general chart start memory number is less than the upper limit number, the general chart start memory number is incremented by one. One random number indicating whether or not the normal figure change display game is a win is stored as the normal figure start memory.

  The state in which the normal map variable display game cannot be started is, for example, a state in which the normal map variable display game has already been executed and the normal map variable display game has not ended, or the normal variable display game has been hit and the normal variable prize winning device This is a state where 36 is converted to an open state.

  In addition, the starting memory | storage number of a common figure change display game is displayed on the common figure memory | storage display 47 provided with LED.

  The normal map display game is executed by a general map display 35 provided on the game board 10. In addition, you may make it display a common figure change display game in a part of display area of the display apparatus 53, In this case, for example, a number, a symbol, a character design etc. are used as an identification design, and this identification design is predetermined. After the time variation display, the display is stopped.

  If the stop display of the normal fluctuation display game becomes a special result mode, the normal fluctuation display game is won and the opening / closing members 36a and 36a of the normal fluctuation winning device 36 are set for a predetermined time (for example, 0.5 seconds). ) Opened. Thereby, it becomes easy to win a game ball in the normal variation winning device 36, and the start of the second special figure variation display game is facilitated.

  The normal variation winning device 36 includes a pair of left and right opening / closing members 36 a and 36 a and is disposed below the first start winning port 45. The open / close members 36a, 36a always maintain a closed state (an unfavorable state for the player) with an interval of about the diameter of the game ball. When it becomes a mode (when a normal fluctuation display game is a win), it is opened in a reverse “C” shape by a solenoid (Fuden SOL 36b, see FIG. 3) as a driving device, and a normal fluctuation prize is won. The device 36 can be changed to a state in which a game ball easily flows into the device 36 (a state advantageous to the player).

  In addition, the gaming machine 1 according to the present embodiment, based on the result form of the special figure variation display game, as a gaming state, a short-time operation state (second operation state) that shortens the variation display time of the special figure variation display game on the display device 53. ) Can be generated. At this time, the short operation state (second operation state) is a state in which the operation state of the normal variation winning device 36 is more likely to be an open state than the normal operation state (first operation state).

  At this time, in the short operation state, the execution time of the above-mentioned general-purpose variable display game is controlled to be shorter than the long execution time in the normal operation state (for example, 10 seconds is 1 second). The number of times of opening of the normal variation winning device 36 is controlled to be substantially increased. Further, in the short-time operation state, when the normal variation winning game 36 is released as a result of the normal variation display game being won, the release time is controlled to be longer than the short release time of the normal operation state. (For example, 0.3 seconds is 1.8 seconds). Also, in the short-time operation state, the normal variation winning device 36 is opened a plurality of times (for example, two times) instead of once for the result of one hit of the normal-variation display game. Further, in the short-time operation state, the probability that the hit result of the normal-variable display game is higher than that in the normal operation state is controlled. That is, the number of times of opening of the normal variation winning device 36 is increased as compared to the normal operation state, and it becomes easier for the game ball to win the normal variation winning device 36, and the second special figure variation display game can be easily started.

  A first start opening SW45a (see FIG. 3) is provided in the first start winning opening 45, and based on detecting a game ball by the first start opening SW45a, a first special figure variation display as an auxiliary game is provided. A starting right to start the game is generated. Further, the normal variation winning device 36 is provided with a second start opening SW36d (see FIG. 3), and based on the detection of the game ball by the second start opening SW36d, the second special figure change as an auxiliary game is performed. A start right to start the display game is generated.

  The right to start the first special figure variation display game is stored as a first start memory (special figure 1 start memory) within a predetermined upper limit number (for example, 4). The first start memory number is displayed on the first special figure memory display 48. The start right for starting the second special figure variation display game is stored as the second start memory (special figure 2 start memory) within a predetermined upper limit number (for example, 4). The second start memory number is displayed on the second special figure memory display 49.

  When the first special figure variation display game can be started (the first start memory number and the second start memory number are 0) and the game ball wins the first start winning opening 45, the start right is generated. The random number extracted with is stored as the first start memory, the first start memory number is incremented by 1, and the first special figure variation display game is immediately started based on the first start memory, At this time, 1 is subtracted from the first start memory number.

  In addition, since the second special figure fluctuation display game is executed in preference to the first special figure fluctuation display game, even if the first start memory number is not zero, if the second start memory number is zero, When the game ball wins the normal variation winning device 36 that forms the second start winning opening, the random number extracted with the start right is stored as the second start memory, and the second start memory number is incremented by one. At the same time, the second special figure variation display game is started based on the second start memory immediately after the execution of the first special figure variation display game being executed, and at this time, the second start memory number is decremented by one.

  On the other hand, a state in which the first special figure fluctuation display game or the second special figure fluctuation display game cannot be started immediately, for example, the first special figure fluctuation display game or the second special figure fluctuation display game has already been performed, and the special figure fluctuation display. If a game ball is won in the first start winning opening 45 when the game is not finished or in a special game state, if the first start memory number is less than the upper limit number (for example, less than four) The first start memory number is incremented by 1, and one random number extracted at the timing when the game ball is won in the first start winning opening 45 is stored as the first start memory.

  Similarly, in this case, when a game ball wins the normal variation winning device 36 that forms the second starting winning opening, if the second starting stored number is less than the upper limit number (for example, less than four), the second starting stored number is 1 is added, and one random number extracted at the timing when the game ball wins the second start winning opening is stored as the second start storage.

  When the first special figure fluctuation display game or the second special figure fluctuation display game is ready to start, the first special figure fluctuation display game or the second special figure fluctuation display is based on the first start memory or the second start memory. The game starts. At this time, the first special figure fluctuation display game and the second special figure fluctuation display game are not executed simultaneously, and the second special figure fluctuation display game is executed with priority over the first special figure fluctuation display game. It is like that.

  That is, when there is a first start memory and a second start memory, the second special figure variation display game is executed.

  The first special figure change display game and the second special figure change display game as the auxiliary game are executed by the first special figure display 38 and the second special figure display 39 provided on the game board 10. After a plurality of pieces of identification information are variably displayed, a predetermined result mode is stopped and displayed. In addition, a special figure fluctuation display game is executed in which a plurality of types of identification information (for example, numbers, symbols, character designs, etc.) are variably displayed on the display device 53 corresponding to each special figure fluctuation display game. And as a result of this special figure fluctuation display game, when the display mode of the first special figure display 38 or the second special figure display 39 becomes a special result mode, it becomes a big hit and a special game state (so-called , Jackpot state). Correspondingly, the display mode of the display device 53 is also a special result mode (for example, any one of the numbers in the flat order such as “7, 7, 7”). The game machine may not be provided with the first special figure display 38 and the second special figure display 39, and the special figure variation display game may be executed only by the display device 53.

  In addition, the gaming machine 1 of the present embodiment can generate a probability variation state (second probability state) as a gaming state based on the result mode of the special figure variation display game. This probability variation state (second probability state) is a state in which the probability of a hit result in the special figure variation display game is higher than the normal probability state (first probability state). It should be noted that the first special figure fluctuation display game and the second special figure fluctuation regardless of whether the first special figure fluctuation display game or the second special figure fluctuation display game results in the result mode of the special figure fluctuation display game. Both display games are in a probable state. Further, the probability variation state and the above-described short-time operation state can be generated independently, and both can be generated simultaneously, or only one can be generated.

  FIG. 3 is a block diagram showing a configuration of the gaming machine 1 according to the first embodiment of the present invention.

  The gaming machine 1 includes a game control device 500 that controls the game in an integrated manner, an effect control device 550 that controls the display device 53 and the speaker 30 to perform various effects, and a payout motor (not shown) for paying out game balls. A payout control device 580 for controlling is provided.

  First, the game control device 500 will be described. In FIG. 4, the effect control device 550 will be described.

  The game control device 500 includes a game microcomputer 501, an input I / F (Interface) 505, an output I / F (Interface) 506, and an external communication terminal 507.

  The gaming microcomputer 501 includes a CPU 502, a ROM (Read Only Memory) 503, and a RAM (Random Access Memory) 504.

  The CPU 502 is a main control device that controls the game in an integrated manner, and controls the game. The ROM 503 stores invariant information (programs, data, etc.) for game control. The RAM 504 is used as a work area during game control.

  The external communication terminal 507 connects the game control device 500 to an external device such as an inspection device that inspects the setting information of the game control device 500.

  The CPU 502 receives various input devices (first start opening SW45a, second start opening SW36d, general winning opening SW44a, gate SW34a, count SW42d, glass frame opening SW18a, front frame opening SW3a, ball out SW54 via the input I / F 505. In response to the detection signals from the vibration sensor 55 and the magnetic sensor 56), various processes such as a big hit lottery are performed.

  The first start port SW 45 a is a switch that detects that a game ball has won the first start winning port 45. The second start port SW 36 d is a switch that detects that a game ball has won a second start winning port of the normal variation winning device 36.

  The general winning openings SWa 44 a to 44 n are switches that detect that a game ball has won the general winning opening 44. The gate SW 34a is a switch that detects that a game ball has passed through the usual start gate 34.

  The count SW 42d is a switch that detects that a game ball has won a special winning opening of the special variable winning device 42.

  The glass frame opening SW 18a is a switch that detects that the glass frame 18 has been opened. The front frame opening SW 3a is a switch for detecting that the front frame 3 is opened.

  The ball cut SW 54 is a switch that detects that the number of game balls stored in the gaming machine 1 and used for payout has become a predetermined number or less.

  The vibration sensor 55 is a sensor that detects a vibration applied to the gaming machine 1 and detects a fraud that improperly acquires a gaming ball by applying a vibration to the gaming machine 1. The magnetic sensor 56 is provided in the vicinity of the first start winning opening 45, the second starting winning opening of the normal variation winning apparatus 36, the general winning opening 44, the large winning opening of the special variable winning apparatus 42, and the normal start starting gate 34. It is a sensor that detects magnetic force. The magnetic sensor 93 detects a fraud that brings a magnet close to each winning hole and guides a game ball launched to the gaming area 10a to each winning hole.

  In addition, the CPU 502 receives the first special figure display 38, the first special figure storage display 48, the second special figure display 39, the second special figure storage display 49, and the common figure display via the output I / F 506. A command signal is transmitted to the device 35, the ordinary electric power SOL 36b, the special winning opening SOL 42b, the payout control device 580, and the effect control device 550 to control the game in an integrated manner.

  The first special figure display 38 displays a first special figure fluctuation display game that is executed as an auxiliary game when a game ball wins the first start winning opening 45. The first special figure memory display 48 displays a first start memory number that is a right to start the first special figure variable display game stored within a predetermined upper limit number range.

  The second special figure display 39 displays a second special figure fluctuation display game that is executed as an auxiliary game when a game ball wins a big winning opening of the normal fluctuation winning device 36. The second special figure memory display 49 displays a second start memory number that is a right to start the second special figure variable display game stored within a range of a predetermined upper limit number.

  The general map display 35 displays a general map change display game that is performed when the game ball passes the general map start gate 34.

  The general electric power SOL 36b opens the opening and closing members 36a, 36a when the stop display of the general variable display game executed on the general signal display 35 becomes a special result mode. Make the starting winning opening easy for the game ball to win.

  The special winning opening SOL42b opens the open / close door 42a of the special variable winning device 42 when the result of the first special figure fluctuation display game or the second special figure fluctuation display game becomes a special result mode and becomes a special game state. Then, the big winning opening is converted into a state in which the game ball is easy to win.

  In addition, the game control device 500 outputs the gaming machine data to a game hall management device (not shown) via an external information terminal 508 and an information collection terminal device (not shown). The gaming hall management device is a computer that collects and manages gaming data of the gaming machines 1 installed in the gaming hall.

  In addition, the payout control device 580 pays out the number of game balls corresponding to the winning winning opening when the gaming ball wins the general winning opening 44 or the big winning opening, or the ball lending button 26 is operated. When a payout command for paying out a predetermined number of game balls is received from the game control device 500, a payout motor (not shown) is controlled based on the received payout command. The payout command includes the number of game balls to be paid out.

  The game control device 500 uses a change start command, a customer waiting demo command, a fanfare command, a probability information command, an error designation command, and the like as game data indicating the game situation via the output I / F 506, and the effect control device 550. Send to.

  FIG. 4 is a block diagram showing a configuration of the effect control device 550 according to the first embodiment of the present invention.

  The effect control device 550 determines the contents of the effect based on the game data input from the game control device 500, controls the display device 53 and the speaker 30, and the decoration device 620 via the decoration control device 610. The accessory driving SOL 560 (solenoid) and the accessory driving MOT (motor) 561 are controlled. Although the details will be described later, a game effect is performed by the decoration device 620, the accessory driving SOL 560, and the accessory driving MOT 561 (generally referred to as an effect device). The effect control device 550 receives a signal indicating that the effect button 17 has been operated from the effect button 17.

  The effect control device 550 includes a CPU 551, a control ROM 552, a RAM 553, an image ROM 554, a sound ROM 555, a VDP 556, a sound LSI 557, an input / output I / F 558, a power-on detection circuit 559, a master IC 570, and a NOR gate circuit 590.

  The CPU 551 is connected to the game control device 500, receives a command signal from the game control device 500 as an interrupt signal (INT), and is a main control device that controls various effects based on the input command signal. The CPU 551 receives an interrupt signal from a controller 574 (described later) of the master IC 570 and an interrupt signal from the VDP 556.

  When an interrupt signal is input to the CPU 551, the CPU 551 interrupts the process currently being executed and executes a process corresponding to the input interrupt signal.

  The control ROM 552 stores invariant information (program, data, etc.) for effect control. The RAM 553 is used as a work area during production control.

  The image ROM 554 stores image data to be displayed on the display device 53, and the image ROM 554 is connected to the VDP 556. The sound ROM 555 stores sound data output from the speaker 30, and the sound ROM 555 is connected to the sound LSI 557.

  The VDP 556 is a processor that controls image output to the display device 53. The sound LSI 557 is a circuit that controls the sound output from the speaker 30.

  Note that the VDP 556 includes synchronization signal generation means for generating a synchronization signal that is synchronized with a cycle (33 ms cycle) for updating an image displayed on the display device 53. Every time the synchronization signal is generated, the synchronization signal generation means inputs the generated synchronization signal to the CPU 551 as an interrupt signal.

  The input / output I / F 558 is an interface connected to the effect button 17 and the NOR gate circuit 590, and transmits an operation signal from the effect button 17 to the CPU 551 and transmits a reset signal from the CPU 551 to the NOR gate circuit 590. .

  The effect button 17 is provided on the upper edge portion of the upper plate 21 and is operated by the player in an effect in the first special figure fluctuation display game or the second special figure fluctuation display game executed on the display device 53. .

  The CPU 551, VDP 556, RAM 553, control ROM 552, sound LSI 557, and input / output I / F 558 are connected via a bus 563.

  The power-on detection circuit 559 generates a reset signal that initializes a register (not shown) of the master IC 570 to a default state (all 0) when the presentation control device 550 is powered on, and the generated reset signal is NORed. Output to the gate circuit 590.

  The CPU 551 outputs a reset signal to the input / output I / F 558 via the bus 563 when a predetermined condition is satisfied, and the input / output I / F 558 outputs the input reset signal to the NOR gate circuit 590. .

  Note that the reset signal input from the power-on detection circuit 559 to the NOR gate circuit 590 and the reset signal input from the CPU 551 to the NOR gate circuit 590 via the input / output I / F 558 are in a low level state in any case. Function as a signal to command resetting. Therefore, if at least one of the power-on detection circuit 559 and the CPU 551 outputs a reset signal to the NOR gate circuit 590, the reset signal is input to the master IC 570 via the NOR gate circuit 590.

  Next, the master IC 570 will be described.

  Master IC 570 designates the address of decoration control device 610 of the rendering device to be controlled, and outputs the control content of the rendering device to decoration control device 610 at the designated address.

  The master IC 570 is connected to the relay board (decoration control device) 600 through five connection lines of the connection line Vcc, the connection line Vact, the connection line SDA, the connection line SCL, and the connection line GND (see FIG. 5). The

  The connection line Vcc is a connection line for supplying logic power to the relay board 600 and the decoration control device 610. The connection line Vact is a connection line for supplying a power source for driving the effect device (for example, a power source for causing the LED to emit light). The connection line SDA is a connection line for communicating data between the effect control device 550 and the decoration control device 610, and functions as a data line in the present embodiment. The connection line SCL is a connection line for inputting and outputting a clock signal used for data communication through the connection line SDA, and functions as a timing signal line in the present embodiment. The connection line GND shown in FIG. 5 is the ground of the power supplied by the connection line Vcc and the connection line Vact.

  The relay board 600 and the decoration control device 610 are connected to each other through the connection line Vcc, the connection line Vact, the connection line SDA, the connection line SCL, and the connection line GND, similarly to the master IC 570 and the relay board 600. The

  The master IC 570 and the decoration control device 610 perform two-line bidirectional communication using the connection line SDA and the connection SCL.

  When transmitting data to the relay board 600 and the decoration control device 610, the master IC 570 first changes the signal level of the connection line SDA from HIGH to LOW while maintaining the signal level of the connection line SCL at HIGH. Thus, a start condition for starting data output to the decoration control device 610 is established (a start condition is issued to the decoration control device 610).

  Thereafter, the master IC 570 changes the signal level of the connection line SCL to LOW, sets the signal level of the connection line SDA to the level of the first bit of the transmission data while the signal level of the connection line SCL is LOW, After a predetermined time, the signal level of the connection line SCL is changed from LOW to HIGH. When the signal level of the connection line SCL changes to HIGH, the decoration control device 610 takes in the signal level of the connection line SDA and recognizes it as the first bit of the transmission data. Next, the master IC 570 returns the signal level of the connection line SCL from HIGH to LOW.

  When this procedure is executed once, 1-bit data is transmitted from the master IC 570 to the decoration control device 610. Finally, this procedure is repeated eight times, so that all eight bits of transmission data are controlled from the master IC 570. It is transmitted to the device 610 (1 byte of data is transmitted).

  The master IC 570 releases the connection line SDA and returns the response signal from the decoration control device 610 when the signal level of the connection line SCL is returned from HIGH to LOW after the transmission of the last 8-bit data. It will be in the reception waiting state which waits to receive.

  In the reception standby state, the decoration control device 610 returns a 1-bit response signal (ACK or NACK described later) to the master IC 570 via the connection line SDA. Next, when the master IC 570 changes the signal level of the connection line SCL from LOW to HIGH to capture the level of the response signal, and after a predetermined time, changes the signal level of the connection line SCL from HIGH to LOW, the decoration control device 610 Release the connection line SDA.

  The master IC 570 alternately repeats the data transmission for 1 byte and the reception of the response signal for 1 bit, and continues until all the data to be output to the decoration control device 610 is output. When the output of the data to be output is completed, the master IC 570 changes the signal level of the connection line SDA from LOW to HIGH while maintaining the signal level of the connection line SCL at HIGH, thereby controlling the decoration control device 610. A stop condition for ending the data output to is established (a stop condition is issued to the decoration control device 610).

  The input BUF 571 is a storage device that temporarily stores data input from the decoration control device 610 via the connection line SDA.

  Specifically, when the master IC 570 is set to the input mode, data transmitted from the decoration control device 610 to the master IC 570 is temporarily stored in the input BUF 571 with noise removed by the filter 575A.

  The output BUF 572 temporarily stores data to be output to the decoration control device 610 via the connection line SDA.

  The reset REG 573 is connected to the bus 563 and receives a command from the CPU 551 and outputs a reset signal to the controller 574. The controller 574 comprehensively controls the master IC 570 and executes various processes.

  The filter 575A removes noise from data input from the connection line SDA. When the driver 576A outputs data from the connection line SDA, the driver 576A applies a voltage at which the transistor 578A can operate to the transistor 578A.

  As shown in FIG. 9, a predetermined voltage is applied to the connection line SDA by the pull-up resistor R, and the connection line SDA is connected to the filter 575A and the transistor 578A.

  The transistor 578A uses a field effect transistor (FET) to reduce power consumption. The gate of the transistor 578A is connected to the driver 576A, and the drain is a connection line SDA to which a predetermined voltage is applied by the pull-up resistor R. And the source is grounded.

  If the voltage applied to the gate of the transistor 578A is smaller than a predetermined value for operating the transistor 578A, no current flows between the drain and the source, so that the voltage applied to the connection line SDA does not drop, and as a result The connection line SDA becomes HIGH level. On the other hand, when the voltage applied to the gate of the transistor 578A is equal to or higher than a predetermined value for operating the transistor 578A, a current flows from the drain to which the voltage of the predetermined value is applied to the grounded source. As a result, the connection line SDA becomes LOW level.

Note that the transistor 578A has a specification that does not break even when a current of about 10 milliamperes flows from the drain to the source. For this reason, it is possible to flow a current of about 10 milliamperes, which is much larger than the current value used when using a normal I ² C bus, to the connection line SDA, and the effect control device 550 and the decoration control device 610 The data transmission between them is configured to withstand failures due to noise.

  When the driver 576A outputs data from the connection line SDA, the driver 576A applies a voltage of a value that allows the transistor 578A to operate to the gate of the transistor 578A in order to pass a current between the drain and source of the transistor 578A. Then, the driver 576A outputs data from the connection line SDA by setting the voltage of the connection line SDA to HIGH level or LOW level.

  The filter 575B removes noise from data input from the connection line SCL. When the driver 576B outputs data from the connection line SCL, the driver 576B applies a voltage with which the transistor 578B can operate to the transistor 578B.

  As shown in FIG. 9, a predetermined voltage is applied to the connection line SCL by the pull-up resistor R, and the connection line SDA is connected to the filter 575B and the transistor 578B.

  The transistor 578B uses a field effect transistor (FET) to suppress power consumption, the gate of the transistor 578B is connected to the driver 576B, and the drain is a connection line SCL to which a predetermined voltage is applied by the pull-up resistor R. And the source is grounded.

  If the voltage applied to the gate of the transistor 578B is smaller than a predetermined value for operating the transistor 578B, no current flows between the drain and the source, so that the voltage applied to the connection line SCL does not drop, and as a result The connection line SCL becomes HIGH level. On the other hand, when the voltage applied to the gate of the transistor 578B is equal to or higher than a predetermined value for operating the transistor 578B, a current flows from the drain to which the predetermined voltage is applied to the grounded source, whereby the connection line SCL As a result, the connection line SCL becomes the LOW level.

Note that the transistor 578B has a specification that does not break even when a current of about 10 milliamperes flows from the drain to the source. Therefore, a current of about 10 milliamperes, which is much larger than the current value used when using the normal I ² C bus, can be passed through the connection line SCL, and between the effect control device 550 and the decoration control device 610. The data transmission is configured to withstand failures due to noise.

  When the driver 576B outputs a clock signal from the connection line SCL, the driver 576B applies a voltage with a value that allows the transistor 578B to operate to the gate of the transistor 578B in order to cause a current to flow between the drain and the source of the transistor 578B. Then, the driver 576B outputs a clock signal from the connection line SCL by repeatedly changing the voltage of the connection line SCL between a HIGH level and a LOW level.

  The power-on reset circuit 577 is used to set storage areas such as the input BUF 571 and the output BUF 572 to a default state when the master IC 570 is powered on and the voltage in the power-on reset circuit 577 reaches a predetermined value. Is output to the controller 574.

  Next, the relay board 600 and the decoration control device 610 will be described.

  The relay board 600 is directly connected to the master IC 570 in the decoration control device 610, that is, located on the most upstream side.

The decoration device 620 is a light-emitting device that is controlled by an I ² CI / O expander 615 (described later in FIG. 6) provided in the decoration control device 610 and flashes light when an electric current is passed. Etc. The accessory driving solenoid (SOL) 560 is a device that reciprocates when an electric current flows. The accessory driving solenoid (SOL) 560 moves an accessory for decoration (not shown) arranged on the game board 10 to produce an effect. The accessory driving motor (MOT) 561 is a device that rotates when an electric current flows, and produces an effect by moving the movable accessory 60. The accessory driving solenoid (SOL) 560 and the accessory driving motor (MOT) 561 are also controlled by the I ² CI / O expander 615 provided in the decoration control device 610.

  Note that the accessory driving SOL 560 may move the movable accessory 60, or the accessory driving MOT 561 may move an accessory not shown.

  The connection method between the effect control device 550 and the relay board 600 and the connection method between the relay board 600 and the decoration control device 610 other than the relay board 600 will be described in detail with reference to FIG. Details of the decoration control device 610 will be described with reference to FIGS.

  FIG. 5 is an explanatory diagram of connections of the decoration control devices 610A to 610F according to the first embodiment of this invention. In addition, for convenience of explanation, one relay board 600 and six decoration control devices 610A to 610F are illustrated as the decoration control device 610, but actually, it is necessary to correspond to the specifications of the gaming machine. A large number of decoration control devices 610 are connected.

  The effect control device 550 is connected to the effect control device 550 via the connection line Vcc, the connection line Vact, the connection line SDA, the connection line SCL, and the connection line GND (hereinafter, these five connection lines are referred to as one harness). Is done.

  Two decoration control devices 610A and 610D are connected to the relay board 600 in parallel by harnesses.

  The decoration control device 610B is connected to the decoration control device 610A via a harness, and the decoration control device 610C is connected to the decoration control device 610B via a harness.

  On the other hand, a decoration control device 610E is connected to the decoration control device 610D via a harness, and a decoration control device 610F is connected to the decoration control device 610E via a harness.

  Each decoration control device 610 includes a connector serving as an attachment port for connecting the harness to itself. Since this connector is common to each decoration control device 610, it is possible to prevent erroneous wiring in the connection order of the connection lines.

Here, a method of controlling the decoration device 620 by the I ² CI / O expander 615 (described later in FIG. 6) provided in the decoration control device 610 will be described.

The effect control device 550 determines the output mode of the effect device based on the game data input from the game control device 500. Then, the production control device 550 produces production control data (production control) including the individual address of the decoration control device 610 to be controlled (the individual address of the I ² CI / O expander 615) so that the determined output mode is obtained. Information) is output to the relay board 600. At this time, the effect control data is output from the connection line SDA to all the decoration control devices 610 connected to the effect control device 550 via the relay board 600. Therefore, the master IC 570 can control all the decoration control devices 610 connected to the master IC 570.

  In the present embodiment, a light emitting device such as an LED is exemplified as the effect device, and the light emission mode of the LED corresponds to the output mode of the effect device. In this case, lighting / flashing / extinguishing of the LED is instructed by the effect control data, and at the same time, the flashing cycle and the lighting brightness of the LED are instructed.

Each decoration control device 610 has a unique individual address set in advance, so that when the effect control data is input, the address included in the input effect control data matches the set individual address. It is determined whether or not. If it is determined that the address included in the input effect control data matches the set individual address, the I ² CI / O expander 615 of the decoration control device 610 captures the effect control data. Thus, the output mode of the corresponding decoration device 620 is controlled, and a response signal is output to the master IC 570 immediately after the 8th bit data is input.

Each decoration control device 610 is set with a reset address for initializing the I ² CI / O expander 615 of the decoration control device 610 in addition to the individual address. This reset address is an address provided in common to all the I ² CI / O expanders 615 and cannot be used as an individual address. Further, the value of the reset address cannot be changed (details will be described later).

When the effect control device 550 initializes the decoration control device 610 (more precisely, the I ² CI / O expander 615 of the decoration control device 610), the effect control device 550 receives the initialization instruction data including the common address for resetting. , Output to the relay board 600. At this time, the initialization instruction data effect control data is output from the connection line SDA to all the decoration control devices 610 connected to the effect control device 550 via the relay board 600.

Each decoration control device 610 has a preset common address for resetting, so it is determined whether or not the address included in the input data matches the preset common address for resetting. To do. When it is determined that the address included in the input data matches a preset common address for resetting, the I ² CI / O expander 615 of the decoration control device 610 transmits a response signal as a master. In addition to outputting to the IC 570, the input data is fetched as initialization instruction data, and the I ² CI / O expander 615 itself is initialized.

When the I ² CI / O expander 615 is initialized, the rendering device controlled by the initialized I ² CI / O expander 615 is turned off.

As described above, the decoration control device 610 performs control based on a command from the effect control device 550, and therefore, the master IC 570 of the effect control device 550 is the master of the relationship between the effect control device 550 and the decoration control device 610. The I ² CI / O expander 615 of the decoration control device 610 is a slave.

  Although the case where the decoration target of the decoration control device 610 is the decoration device 620 has been described with reference to FIG. 5, the control target of the decoration control device 610 may be the accessory driving SOL 560 or the accessory driving MOT 561. In this case, since the rendering device serves as a drive source such as a motor or a solenoid, the operation mode of these drive sources corresponds to the output mode of the rendering device. In this case, activation / deactivation of the drive source is instructed by the effect control data, and the operation speed is also instructed at the same time.

  FIG. 6 is a block diagram of the decoration control device 610 according to the first embodiment of this invention.

  In FIG. 6, the decoration control device 610 (the decoration control device 610 on the lower side in FIG. 6) including the decoration device 620 LED inside the decoration control device 610 and the decoration control device 610 connected to the external decoration device 620. (The decoration control device 610 in the center of FIG. 6) will be described.

  First, the decoration control device 610 provided with LEDs inside the decoration control device 610 will be described.

The decoration control device 610 on the lower side of FIG. 6 includes an I ² CI / O expander 615 and LEDs (decoration device 20). The connection line SDA and the connection line SCL are branched into two in the decoration control device 610, and one is output to the next decoration control device 610 as it is. The other is connected to the I ² CI / O expander 615.

In addition, a decoration device 620 to be controlled is connected to the output side of the I ² CI / O expander 615. The output side of the I ² CI / O expander 615 includes ports 0 to 15 described with reference to FIG. Furthermore, all the ports of the decoration control device 610 are connected to the internal LEDs via current limiting resistors R0 to R15 described later with reference to FIG. 8A. Note that the current control resistors R0 to R15 are also provided in the decoration control device 610.

As described above, the I ² CI / O expander 615 has an address included in the effect control data input from the effect control device 550 and an individual address set in the I ² CI / O expander 615. Only when they match, the decoration device 620 connected to the I ² CI / O expander 615 is controlled based on the decoration data included in the effect control data.

  The power source Vled in the figure corresponds to the power source (power source for causing the LED to emit light) supplied by the connection line Vact described above with reference to FIG.

  Next, the decoration control device 610 connected to the external decoration device 620 will be described.

The central decoration control device 610 in FIG. 6 includes an I ² CI / O expander 615 and an LED (decoration device 20), and allows current to flow through the LEDs provided on the decoration device substrate 625 connected to the outside of the decoration control device 610. The decoration control device 610 and the decoration device substrate 625 are connected to each other through a connection line for connecting the power supply voltage Vled to the LED of the decoration device substrate 625 and a connection wire grounded to the ground.

The decoration device substrate 625 does not include the I ² CI / O expander 615 but is a substrate including only LEDs. In this case, the current limiting resistor (FIG. 8A) connected to the LED provided on the decoration device board 625 is provided on the decoration device board 625, but the decoration control device provided with the I ² CI / O expander 615. 610 may be provided.

It should be noted that the number of connection lines for passing current to these LEDs to be passed from the decoration control device 610 to the decoration device substrate 625 is determined in accordance with the number of LEDs provided on the decoration device substrate 625. . For example, when the decoration device substrate 625 includes two LEDs, two control lines for connecting the port of the I ² CI / O expander 615 and the corresponding LED, and a power supply line for supplying Vled Is required at least.

The I ² CI / O expander 615 provided in the central decoration control device 610 is also set in the address included in the effect control data input from the effect control device 550 and the I ² CI / O expander 615. The decoration device 620 connected to the I ² CI / O expander 615 is controlled based on the decoration data included in the effect control data only when the individual address matches. In this case, both the decoration device 620 provided in the central decoration control device 610 and the decoration device 620 provided on the decoration device substrate 625 are controlled by the I ² CI / O expander 615.

In this way, by providing the decoration device substrate 625 and separating a part of the decoration devices (LEDs) from the decoration control device 610, even if the LEDs are arranged at remote locations, a common I ² CI / It can be controlled by the O expander 615.

  Note that the decoration control device 610 may connect and control the accessory driving SOL 560 and the accessory driving MOT 561 in place of the decoration device 620, but details will be described later with reference to FIG. 8B.

FIG. 7 is a block diagram of the I ² CI / O expander 615 according to the first embodiment of this invention.

The I ² CI / O expander 615 includes a transistor 630 connected to the connection line SDA, a filter 631 connected to the connection line SDA, a driver 632 connected to the connection line SDA, a filter 633 connected to the connection line SCL, Bus controller 634, output setting register 635, output controller 636, driver 637 connected to ports 0-15 on the output side of I ² CI / O expander 615, transistors 638A-638P connected to ports 0-15 , And a reset signal generation circuit 639.

  The filter 631 is connected to the connection line SDA, removes noise of data input from the connection line SDA, and outputs the data from which noise has been removed to the bus controller 634. When the driver 632 outputs a response signal from the connection line SDA, the driver 632 applies a voltage at which the transistor 630 can operate to the transistor 630.

  When the driver 632 outputs data (response signal) from the connection line SDA, the driver 632 applies a voltage at which the transistor 630 can operate to the transistor 630.

  The transistor 630 uses a field effect transistor (FET) to suppress power consumption, the gate of the transistor 630 is connected to the driver 632, and a predetermined voltage is applied to the drain by a pull-up resistor R (see FIG. 4). Connected to the connected connection line SDA, and the source is grounded.

  If the voltage applied to the gate of the transistor 630 is smaller than a predetermined value for operating the transistor 630, no current flows between the drain and the source. On the other hand, if the voltage applied to the gate of the transistor 630 is greater than or equal to a predetermined value that causes the transistor 630 to operate, a current flows from the drain to which the voltage of the predetermined value is applied to the grounded source. The voltage drops. Note that the transistor 630 has a specification that does not break even when a current of about 10 milliamperes flows from the drain to the source.

  When the driver 632 outputs data (response signal) from the connection line SDA, the driver 632 applies a voltage of a value that allows the transistor 630 to operate to the gate of the transistor 630 so that a current flows between the drain and the source. To do. The driver 632 outputs data from the connection line SDA by repeatedly changing the voltage of the connection line SDA from HIGH to LOW.

  The filter 633 is connected to the connection line SCL, removes noise of data input from the connection line SCL, and outputs the data from which noise has been removed to the bus controller 634.

In addition, the I ² CI / O expander 615, is set a unique address by the address setting terminals A0~A3 provided in the I ² CI / O expander 615 is input to the bus controller 634. Further, an address for resetting the I ² CI / O expander 615 is also set in advance.

The bus controller 634 determines whether or not the address of the data input from the connection line SDA matches the unique address set in the I ² CI / O expander 615. Capture as production control data.

Also, the bus controller 634 determines whether the address of the data input from the connection line SDA matches the reset address preset in the I ² CI / O expander 615, and determines whether the input data When the address and the reset address preset in the I ² CI / O expander 615 match, the data is fetched as initialization instruction data, and the I ² CI / O expander 615 is initialized. .

  In addition, the bus controller 634 changes the signal level of the SCL connection line from LOW to HIGH and takes in the 8th bit data, and then changes the signal level of the SCL connection line from HIGH to LOW. A response signal is output from the connection line SDA to the master IC 570. Further, it is confirmed that the signal level of the SCL connection line changes from LOW to HIGH, and when the signal level of the SCL connection line changes from HIGH to LOW again, the connection line SDA is released. That is, a response signal is output at a timing when the number of changes in the signal level of the SCL connection line from LOW to HIGH becomes nine.

In the output setting register 635, the operation mode of the I ² CI / O expander 615 and the output state of the ports 0 to 15 are set. When the bus controller 634 fetches the initialization instruction data from the connection line SDA and the I ² CI / O expander 615 is initialized, the output setting register 635 causes a current to flow to all the ports 0 to 15. It is set to the initial state so that there is no.

  Based on the data set in the output setting register 635, the output controller 636 causes the directing device connected to each of the ports 0 to 15 to actually output the output state of the directing device through the port driver 637. To control. When the bus controller 634 fetches the effect control data from the connection line SDA, this output state is updated to the contents specified in the fetched effect control data.

  When a current flows through a port, the driver 637 applies a voltage at which the transistors 638A to 638P connected to the port through which the current flows can operate.

  The gates of the transistors 638A to 638P are connected to the driver 637, the drain is connected to the port terminal connected to the connection line to which the voltage for operating the rendering device is applied as shown in FIGS. 8A and 8B, and the source is grounded Has been.

  If the voltage applied to the gates of the transistors 638A to 638P is smaller than a predetermined value for operating the transistors 638A to 638P, no current flows between the drain and the source. On the other hand, if the voltage applied to the gates of 638A to 638P is equal to or higher than a predetermined value for operating the transistor 638, the power supply Vled shown in FIG. 8A or the power supply Vmot or the power supply Vsol shown in FIG. Current flows to the source grounded through the drain of the transistor 638, so that the output state of the effect device connected to the port terminal can be controlled.

Further, the I ² CI / O expander 615 of the decoration control device 610 can control all the rendering devices connected to the port terminals of the I ² CI / O expander 615 at the same time. ² One rendering device connected to the port terminal of the CI / O expander 615 can be controlled as one group.

Since the I ² CI / O expanders 615 included in each decoration control device 610 are assigned different individual addresses, the rendering device is divided into a plurality of groups. In other words, the I ² CI / O expander 615 included in each decoration control device 610 is configured as a group unit control unit that can control the effect device in units of groups.

  Therefore, the effect control device 550 that controls the decoration control device 610 functions as a group control unit that controls the group unit control unit.

The reset signal generation circuit 639 is connected to a Vcc terminal connected to a connection line Vcc that supplies power to the I ² CI / O expander 615 and a RESET terminal that receives an external reset signal.

The reset signal generation circuit 639 generates a reset signal when the I ² CI / O expander 615 is turned on and the voltage rises to a predetermined value, and the generated reset signal is sent to the bus controller 634 and the output setting register 635. , And the output controller 636.

  Note that when a LOW level reset signal is input from the outside, the reset signal generation circuit 639 outputs a reset signal, and therefore, from the CPU 551 of the effect control device 550 via the NOR gate circuit 5590, from the RESET terminal. A reset signal may be input. When the RESET terminal is not used, the RESET terminal may be pulled up to HIGH as shown in FIGS. 8A and 8B.

FIG. 8A is a circuit diagram around the I ² CI / O expander 615 of the decoration control device 610 that controls the decoration device 620 according to the first embodiment of the present invention.

The I ² CI / O expander 615 includes an NC terminal, a RESET terminal, an SCL terminal, an SDA terminal, a Vcc terminal, an A0 to A3 terminal, and a GND terminal as input terminals, and includes PORT0 to PORT15 as output terminals.

A power source supplied to the I ² CI / O expander 615 is connected to the RESET terminal via a pull-up resistor R. For this reason, the voltage applied to the reset terminal is always maintained HIGH.

  The SCL terminal is connected to the connection line SCL, and the SDA terminal is connected to the connection line SDA.

A power supply supplied to the I ² CI / O expander 615 is connected to the Vcc terminal. Further, a capacitor CP for removing power supply noise is connected to the Vcc terminal.

The A0 to A3 terminals are terminals for setting unique addresses for the I ² CI / O expander 615. Note that the address of the normal I ² CI / O expander 615 is represented by 4 bits. When the power of the I ² CI / O expander 615 is applied to this terminal, “1” is displayed in the bus controller 634. When this terminal is connected to the ground, “0” is set in the bus controller 634.

Therefore, the address of the I ² CI / O expander 615 shown in FIG. 8A is “0100”, and the address of the I ² CI / O expander 615 shown in FIG. 8B is “0110”. The GND terminal is a terminal for grounding a voltage.

  Each PORT0 terminal to PORT15 terminal is connected to a decoration device 620 including each LED0 to LED15 via current limiting resistors R0 to R15. Note that one LED may be connected to one port as in PORT0, but a plurality of LEDs may be connected to one port as in PORT1-15.

When one LED is provided for all the ports, a maximum of 16 LEDs can be controlled by one I ² CI / O expander 615. If the number of LEDs connected to each port is different, assuming that all LEDs connected in series to one port are one type of LED, one I ² CI / O expander is used. By 615, up to 16 kinds of LEDs can be controlled.

  When a voltage is applied from the driver 637 to the gates of the transistors 638A to 638P (see FIG. 7) connected to the PORT0 terminal to the PORT15 terminal, a current flows from the drain to the source of the transistors 638A to 638P to which the voltage is applied. Thus, a current flows through the LED0 to LED15 connected to the PORT0 terminal to the PORT15 terminal, and each of the LED0 to LED15 lights up.

  On the other hand, if the driver 637 does not apply a voltage to the gates of the transistors 638A to 638P, no current flows through each LED0 to LED15, and each LED0 to LED15 is not lit.

In addition, since it is possible to connect a motor or a solenoid to the PORT0 terminal to the PORT15 terminal of the I ² CI / O expander 615 instead of the LED, the motor is used by using the I ² CI / O expander 615. A case where a solenoid is driven will be described.

FIG. 8B is a circuit diagram around the I ² CI / O expander 615 of the decoration control device 610 that controls the accessory driving MOT 561 and the accessory driving SOL 560 according to the first embodiment of this invention.

  The accessory driving MOT 561 is composed of a stepping motor, and rotates by sequentially applying a predetermined voltage to signal terminals of respective phases that drive the stepping motor. In the present embodiment, the signal terminals of the respective phases of the accessory driving MOT 561 are connected to the PORT0 terminal to the PORT3 terminal.

  When a voltage is applied from the driver 637 to any one of the gates of the transistors 638A to 638D connected to the PORT0 terminal to the PORT3 terminal connected to the accessory driving MOT561, the transistors 638A to 638D to which the voltage is applied are applied. The current can flow from the drain to the source, the current flows to the accessory driving MOT 561 connected to the PORT0 terminal to the PORT3 terminal, and the accessory driving MOT561 is driven.

  The connection lines connecting the PORT0 terminal to the PORT3 terminal and the accessory driving MOT 561 are branched, and one of the branched connection lines is connected to the power supplied to the accessory driving MOT 561 via the diode D and the Zener diode ZD. Connected.

  The PORT terminal 15 is connected to the accessory driving SOL 560. When a voltage is applied from the driver 637 to the gate of the transistor 638P connected to the PORT15 terminal connected to the accessory drive SOL560, a current can flow from the drain to the source of the transistor 638P to which the voltage is applied. Thus, a current flows through the accessory driving SOL 560 connected to the PORT 15 terminal, and the accessory driving SOL 560 is driven.

In FIG. 8B, with respect to I ² CI / O Aix although both character object drive MOT561 and character object drive SOL560 Panda 615 are connected, one I ² CI / O expander 615, the character object drive A configuration in which at least one of the MOT 561 and the accessory driving SOL 560 is connected may be used.

For example, an I ² CI / O expander 615 as a group that controls only the stepping motor may be provided exclusively, or an I ² CI / O expander 615 as a group that controls only the solenoid may be provided exclusively. . With such a configuration, it is possible to control the rendering devices belonging to the same group at the same timing, and therefore it becomes possible to group and control only the rendering devices that require high-speed processing.

  FIG. 9 is a circuit diagram of connection lines related to input / output of the relay board 600 according to the first embodiment of the present invention.

The relay board 600 includes an upstream connector 601, two downstream connectors 602A and 602B, and an I ² CI / O expander 615.

  The upstream connector 601 is a connector connected to the master IC 570 upstream of the relay board 600, and the connectors 602 A and 602 B are connected to the decoration control device 610 downstream of the relay board 600.

  In order to connect the connection line SDA to the two downstream connectors 602A and 602B, the internal connection line SDA911 extending from the upstream connector 601 branches at a branch 901 into a first connection line SDA921 and a second connection line SDA931. The first connection line SDA921 is connected to the downstream connector 602A, and the second connection line SDA931 is connected to the downstream connector 602B.

  Similarly, the internal connection line SCL912 extending from the upstream connector 601 branches at a branch 902 into a first connection line SCL922 and a second connection line SCL932. The first connection line SCL922 is connected to the downstream connector 602A, and the second connection line SCL932 is connected to the downstream connector 602B.

In order to connect the connection line SDA to the I ² CI / O expander 615, the second connection line SDA931 branches at the branch 903, and the branched second connection line SDA931 is the I ² CI / O expander 615 in FIG. It is connected to the SDA terminal shown in FIG. Further, in order to connect the connection line SCL to the I ² CI / O expander 615, the second connection line SCL 932 branches at the branch 904, and the branched second connection line SCL 932 is a diagram of the I ² CI / O expander 615. 8A and the SCL terminal shown in FIG. 8B.

Note that the I ² CI / O expander 615 is supplied with a voltage Vcc that is a power supply voltage of the I ² CI / O expander 615. Although not shown in FIG. 9, from the I ² CI / O expander 615, signal lines of ports 0 to 15 for driving LEDs (decoration device 200) provided on the relay board 600 (see FIG. 8A). Is output.

Further, although the I ² CI / O expander 615 is connected to the second connection line SDA931 and the second connection line SCL932, it may be connected to the first connection line SDA921 and the first connection line SCL922.

I ² CI / O Aix input expander 615 via the connection line SDA signal is output via the connection line SDA upstream of the master IC570, and from the upstream of the master IC570 to I ² CI / O expander 615 of the relay board 600 The Zener diode ZD941 is connected to the internal connection line SDA911 in order to remove the noise of the generated signal.

  Specifically, the internal connection line SDA911 branches at the branch 905, the branched internal connection line SDA911 is connected to the cathode side of the Zener diode ZD941, and the anode side of the Zener diode ZD941 is grounded.

  For this reason, a voltage (for example, a pulsed noise signal) higher than a predetermined voltage applied to the internal connection line SDA911 is released by the Zener diode ZD941.

In addition, a Zener diode ZD942 is connected to the internal connection line SCL912 in order to remove noise of a signal input from the upstream master IC 570 to the I ² CI / O expander 615 of the relay board 600 via the connection line SCL. ing.

  Specifically, the internal connection line SCL912 branches at a branch 906, the branched internal connection line SCL912 is connected to the cathode side of the Zener diode ZD942, and the anode side of the Zener diode ZD942 is grounded.

  For this reason, a voltage (for example, a pulsed noise signal) applied to the internal connection line SCL912 is released by the Zener diode ZD942.

A signal output from the I ² CI / O expander 615 of the relay board 600 via the connection line SDA to the decoration control device 610 connected to the downstream connector 602A, and the relay board from the decoration control device 610 connected to the downstream connector 602A. A Zener diode ZD943 is connected to the first connection line SDA921 in order to remove noise of a signal input to the 600 I ² CI / O expander 615 via the connection line SDA.

  Specifically, the first connection line SDA921 branches at a branch 907, the branched first connection line SDA921 is connected to the cathode side of the Zener diode ZD943, and the anode side of the Zener diode ZD943 is grounded.

  Therefore, a voltage (for example, a pulsed noise signal) higher than a predetermined voltage applied to the internal connection line SDA921 is released by the Zener diode ZD943.

  Similarly to the Zener diode ZD943 connected to the first connection line SDA921, the Zener diode 945 is also connected to the second connection line SDA931.

The first connection line SCL922 is used to remove noise of a signal input from the I ² CI / O expander 615 of the relay board 600 to the decoration control device 610 connected to the downstream connector 602A via the connection line SCL. Is connected to a Zener diode ZD944.

  Specifically, the first connection line SCL922 branches at a branch 908, the branched first connection line SCL922 is connected to the cathode side of the Zener diode ZD944, and the anode side of the Zener diode ZD944 is grounded.

  For this reason, a voltage (for example, a pulse noise signal) of a predetermined level or higher applied to the internal connection line SCL922 is released by the Zener diode ZD944.

  Similarly to the Zener diode ZD944 connected to the first connection line SCL922, the Zener diode ZD946 is also connected to the second connection line SCL932.

  In addition, a pull-up resistor R951 for pulling up the voltage of the upstream connection line SDA connected to the master IC 570 and the downstream connection line SDA connected to the decoration control device 610 is provided in the first connection line SDA921. Connected. Similarly, a pull-up resistor R952 for pulling up the voltage of the upstream connection line SCL connected to the master IC 570 and the downstream connection line SCL connected to the decoration control device 610 is provided in the first connection line SDA922. Connected.

  Specifically, the first connection line SDA921 branches at the branch 909, and the branched first connection line SDA921 is connected to the pull-up resistor R951. Similarly, the first connection line SCL922 branches at a branch 910, and the branched first connection line SCL922 is connected to a pull-up resistor R952.

  Note that the pull-up resistors 951 and 952 for pulling up the voltages of the connection line SDA and the connection line SCL may not be included in the relay substrate 600, may be included in the master IC 570, or a decoration control device other than the relay substrate 600. 610 may be provided. In short, it may be anywhere as long as the voltage Vcc can be supplied to the drain terminals of the transistors that drive the connection line SDA and the connection line SCL.

The internal connection line Vcc971 extending from the Vcc terminal of the upstream connector 601 connected to the connection line Vcc for supplying the power supply voltage to the I ² CI / O expander 615 of the relay board 600 and the GND terminal of the upstream connector 601 are grounded. The internal connection line GND972 is connected via a smoothing capacitor C961 and a bypass capacitor 962.

  The smoothing capacitor C961 is a capacitor for smoothing the voltage waveform of the power supply, and the bypass capacitor CP962 is a capacitor for removing noise of the power supply voltage.

For this reason, the power supply voltage supplied to the I ² CI / O expander 615 of the relay board 600 is smoothed by the smoothing capacitor C961, and noise is removed by the bypass capacitor 962, so that the I ² CI / O expander is removed. 615 is supplied.

  Similarly, the internal connection line Vcc973 extending from the Vcc terminal of the downstream connectors 602A and 602B and the internal connection line GND974 extending from the GND terminal are connected via a smoothing capacitor C961 and a bypass capacitor 962. As a result, the smoothed and noise-free voltage is applied to the connection line Vcc connected to the downstream decoration control device 610.

  FIG. 10 is a circuit diagram of connection lines related to input / output of the decoration control device 610 according to the first embodiment of this invention.

The decoration control device 610 includes an upstream connector 611, an I ² CI / O expander 615, and a downstream connector 612.

  A bus is connected to the upstream connector 611 from the relay board 600 or the decoration control device 610 on the upstream side. The downstream connector 612 is connected to a bus connected to the decoration control device 610 on the downstream side.

  The SDA terminal of the upstream connector 611 and the SDA terminal of the downstream connector 612 are connected by an internal connection line SDA1011. The SCL terminal of the upstream connector 611 and the SCL terminal of the downstream connector 612 are connected by an internal connection line SCL1012.

In order to connect the connection line SDA to the I ² CI / O expander 615, the internal connection line SDA1011 branches at the branch 1001, and the branched internal connection line SDA1011 is the I ² CI / O expander 615 shown in FIGS. To the SDA terminal shown in FIG. Further, in order to connect the connection line SCL to the I ² CI / O expander 615, the internal connection line SCL 1012 branches at the branch 1002, and the branched internal connection line SCL 1012 is the I ² CI / O expander 615 shown in FIG. It is connected to the SCL terminal shown in FIG. 8B.

Note that the I ² CI / O expander 615 is supplied with a voltage Vcc that is a power supply voltage of the I ² CI / O expander 615. Although not shown in FIG. 10, the I ² CI / O expander 615 provides signal lines for the ports 0 to 15 for driving the LEDs (decoration device 200) related to the decoration control device 610 (see FIG. 8A). ) Is output.

The signal output from the I ² CI / O expander 615 of the decoration control device 610 shown in FIG. 10 to the upstream decoration control device 610 connected to the upstream connector 611 or the relay board 600 via the connection line SDA, and the upstream connector 611 In order to remove the noise of the signal input via the connection line SDA from the upstream decoration control device 610 or relay board 600 connected to the I ² CI / O expander 615 of the decoration control device 610 shown in FIG. The zener diode ZD1041 is connected to the internal connection line SDA1011.

  Specifically, the internal connection line SDA1011 branches at a branch 1003, the branched internal connection line SDA1011 is connected to the cathode side of the Zener diode ZD1041, and the anode side of the Zener diode ZD1041 is grounded.

  For this reason, a voltage (for example, a pulsed noise signal) higher than a predetermined voltage applied to the internal connection line SDA1011 is released by the Zener diode ZD1041.

Further, noise of a signal input from the upstream decoration control device 610 or the relay board 600 connected to the upstream connector 611 to the I ² CI / O expander 615 of the decoration control device 610 shown in FIG. 10 via the connection line SCL. In order to eliminate this, a Zener diode ZD942 is connected to the internal connection line SCL1012.

  Specifically, the internal connection line SCL1012 branches at a branch 1004, the branched internal connection line SCL1012 is connected to the cathode side of the Zener diode ZD1042, and the anode side of the Zener diode ZD1042 is grounded.

  For this reason, a voltage (for example, a pulsed noise signal) applied to the internal connection line SCL 1012 at a predetermined level or more is released by the Zener diode ZD1042.

The I ² CI / O expander 615 of the decoration control device 610 shown in FIG. 10 is connected to the downstream decoration control device 610 connected to the downstream connector 612 via the connection line SDA and to the downstream connector 612. In order to remove noise from the signal input via the connection line SDA from the downstream decoration control device 610 to the I ² CI / O expander 615 of the decoration control device shown in FIG. ZD1043 is connected.

  Specifically, the internal connection line SDA1011 branches at a branch 1005, the branched internal connection line SDA1011 is connected to the cathode side of the Zener diode ZD1043, and the anode side of the Zener diode ZD1043 is grounded.

  For this reason, a voltage (for example, a pulse noise signal) of a predetermined level or more applied to the internal connection line SDA1011 is released by the Zener diode ZD1043.

Further, in order to remove noise of a signal input via the connection line SCL from the I ² CI / O expander 615 of the decoration control device 610 shown in FIG. 10 to the downstream decoration control device 610 connected to the downstream connector 612. In addition, a Zener diode ZD1044 is connected to the internal connection line SCL1012.

  Specifically, the internal connection line SCL1012 branches at a branch 1006, the branched internal connection line SCL1012 is connected to the cathode side of the Zener diode ZD1044, and the anode side of the Zener diode ZD1044 is grounded.

  For this reason, a voltage (for example, a pulse noise signal) applied to the internal connection line SCL 1012 is more than a predetermined voltage and is released by the Zener diode ZD1044.

The internal connection line Vcc1071 extending from the Vcc terminal of the upstream connector 611 connected to the connection line Vcc for supplying the power supply voltage to the I ² CI / O expander 615 of the decoration control device 610, and the GND terminal of the upstream connector 611 extending to the ground The internal connection line GND 1072 is connected via a smoothing capacitor C 1061 and a bypass capacitor 1062.

  The smoothing capacitor C1061 is the same capacitor as the smoothing capacitor C961 shown in FIG. 9, and the bypass capacitor CP1062 is the same capacitor as the bypass capacitor 962 shown in FIG.

  Further, the internal connection line Vcc 1073 extending from the Vcc terminal of the downstream connector 612 and the internal connection line GND 1074 extending from the GND terminal are connected via a smoothing capacitor C 1061 and a bypass capacitor 1062.

  FIG. 11 is an explanatory diagram of the slave address 1100 included in the data output from the presentation control device 550 to the decoration control device 610 according to the first embodiment of this invention.

  The slave address 1100 includes a fixed address part 1101 consisting of upper 3 bits and a variable address part 1102 consisting of lower 5 bits.

The fixed address portion 1101 is an address that is preset with “110” and cannot be changed by the I ² CI / O expander 615.

Variable address portion 1102 is a configurable address I ² CI / O expander 615, corresponding to a pattern that is set to A0~A3 terminal of I ² CI / O expander 615 to be controlled 4 A bit I ² CI / O expander address 1103 and 1-bit R / W identification data 1104 indicating whether the data is a read request or a write request are included.

  Since the effect control data output from the effect control device 550 to the decoration control device 610 is a write request, “0” is normally registered in the R / W identification data 1104.

FIG. 12 is an explanatory diagram of the I ² CI / O expander address table 1200 according to the first embodiment of this invention.

The I ² CI / O expander address table 1200 is a table managed by the master IC 570. The I ² CI / O expander address table 1200 shows the correspondence between the slave address 1201 and the I ² CI / O expander address 1202.

The slave address 1201 stores the slave address of the decoration control device 610 specified by the effect control device 550 as a transmission / reception target. As described above with reference to FIG. 13, the slave address is configured by combining a fixed address portion composed of upper 3 bits, a 4-bit I ² CI / O expander address, and 1-bit R / W identification data. .

In the I ² CI / O expander address 1202, a 4-bit I ² CI / O expander address corresponding to each slave address is registered as described above with reference to FIGS. 8A and 8B.

However, among the I ² CI / O expander addresses, the address “1000” and the address “1011” cannot be used as unique addresses for identifying the I ² CI / O expanders 615 from each other.

  “1000” is used as a default value at the time of power-on of an address (all call address) specified when outputting commands to all the decoration control devices 610. “1011” is a common address used when all the decoration control devices 610 connected to the master IC 570 are unconditionally reset by software.

As described above, since there are 14 unique addresses that can be set in the I ² CI / O expander 615 of the decoration control device 610, the effect control device 550 controls the 14 I ² CI / O expanders 615. it can. In addition, since one decoration control device 610 includes PORT0 to PORT15, it can control 16 (in other words, 16 types) LEDs. Therefore, the production control device 550 can control 224 (in other words, 224 types) LEDs.

FIG. 13 is a diagram for explaining a work register assigned to the output setting register 635 (see FIG. 7) included in the I ² CI / O expander 615 according to the first embodiment of this invention.

A work register (device register) and a control register (control register) are assigned to the output setting register 635 of the I ² CI / O expander 615. Work register, and information for setting the predefined relative I ² CI / O Expander 615, the output of the effect device connected to the I ² CI / O expander 615 (e.g., LED) Information for specifying an aspect is stored. The control register also stores information defining the procedure for writing data to the work register.

  As shown in FIG. 13, the work register has a configuration in which a plurality of pieces of information are distributed and stored in different storage areas, and different register numbers are assigned to the respective storage areas.

A register name “MODE1” is assigned to the storage area with the register number “00h”, and a register name “MODE2” is assigned to the storage area with the register number “01h”. Yes. When values are written in the storage areas of the register numbers “00h” and “01h”, the I ² CI / O expander 615 is initialized based on the written values.

Register names “PWM0” to “PWM15” are assigned to storage areas having register numbers “02h” to “11h”. When a value is written in any of the storage areas of register numbers “02h” to “11h”, the value is written out of the 16 LEDs constituting the light emitting device connected to the I ² CI / O expander 615. The luminance of the LED corresponding to the register number is adjusted based on the written value. For example, when a value is written in the storage area of the register number “02h”, the luminance of the LED 0 connected to the port 0 shown in FIG. 8A is adjusted.

When the accessory driving SOL 560 is connected to the I ² CI / O expander 615, the accessory driving SOL 560 is energized in the storage area of the register number corresponding to the port to which the accessory driving SOL 560 is connected. A value indicating whether to operate or not to energize is written.

When the accessory driving MOT 561 is connected to the I ² CI / O expander 615, the target rotation of the accessory driving MOT 561 is stored in the storage area of the register number corresponding to the port to which the accessory driving MOT 561 is connected. A value indicating the position is written.

  A register name “GRPPWM” is assigned to the storage area with the register number “12h”, and a register name “GRPFREQ” is assigned to the storage area with the register number “13h”. When a value is written in the storage areas of the register numbers “12h” and “13h”, a blinking pattern of all LEDs (16 LEDs) is set based on the written value.

  Specifically, when a value is written in the storage area of the register number “12h”, the duty cycle that is the on / off ratio of the entire LED is set, and the value is stored in the storage area of the register number “13h”. When written, the blinking cycle of the entire LED is set.

  A register name “LEDOUT0” is given to the storage area where the register number is “14h”. When a value is written in the storage area of the register number “14h”, the output states of the LEDs 0 to LED3 are set based on the written value.

  A register name “LEDOUT1” is given to the storage area where the register number is “15h”. When a value is written in the storage area of the register number “15h”, the output states of the LEDs 4 to 7 are set based on the written value.

  A register name “LEDOUT2” is assigned to the storage area where the register number is “16h”. When a value is written in the storage area of the register number “16h”, the output states of the LEDs 8 to 11 are set based on the written value.

  A register name “LEDOUT3” is given to the storage area where the register number is “17h”. When a value is written in the storage area of the register number “17h”, the output states of the LEDs 12 to 15 are set based on the written value.

  Register names “SUBADR1” to “SUBADR3” are assigned to storage areas having register numbers “18h” to “1Ah”. When values are written in the storage areas of the register numbers “18h” to “1Ah”, the first subaddress to the third subaddress are set based on the written values.

  A register name “ALLCALLADR” is given to the storage area whose register number is “1Bh”. When a value is written in the storage area of the register number “1Bh”, an all-call address is set based on the written value.

  FIG. 14 is an explanatory diagram of a start condition and a stop condition for data output from the master IC 570 according to the first embodiment of this invention via the connection line SDA and the connection line SCL.

  The signal level of the connection line SCL is HIGH when data is not transmitted, and the master IC 570 changes the signal level of the connection line SCL from LOW to HIGH when outputting data to the decoration control device 610. Control device 610 acts as a strobe signal for taking in data on connection line SDA.

  The signal level of the connection line SDA is HIGH when data is not transmitted, and data is output from the connection line SDA in accordance with the clock signal of the connection line SCL.

  Master IC 570 changes the signal level of connection line SDA from HIGH to LOW while maintaining the signal level of connection line SCL at HIGH, and outputs a signal that is a start condition indicating that data output starts. .

The I ² CI / O expander 615 of the decoration control device 610 recognizes that data output starts when a signal serving as a start condition is input from the connection line SDA and the connection line SCL.

  The master IC 570 changes the signal level of the connection line SDA from LOW to HIGH while maintaining the signal level of the connection line SCL at HIGH, and outputs a signal indicating a stop condition indicating that data output is completed. .

The I ² CI / O expander 615 of the decoration control device 610 grasps that the output of data ends when the stop condition is input.

  FIG. 15 is a timing chart at which the decoration control device 610 to which the data output from the master IC 570 according to the first embodiment of the present invention is input outputs a response signal.

  The decoration control device 610 counts the number of changes in the signal level of the connection line SCL after the start condition is satisfied, and takes in data input from the connection line SDA in accordance with the clock signal of the connection line SCL.

  Then, the decoration control device 610 outputs a response signal to the master IC 570 via the connection line SDA immediately after the start condition is satisfied and immediately before the signal line change number of the connection line SCL reaches nine. In other words, the decoration control device 610 receives a response signal via the connection line SDA when the signal level of the connection line SCL changes from HIGH to LOW after taking the 8th bit data from the connection line SDA. Output.

  As shown in the figure, a response signal (ACK response signal) indicating that data reception was successful is indicated by a LOW level, and a response signal (NACK response signal, FIG. (Corresponding to no ACK output) is indicated by a HIGH level.

  Further, when the signal level of the connection line SCL changes eight times after the start condition is satisfied, the master IC 570 waits for a response signal from the decoration control device 610 by releasing the connection line SDA. Then, the master IC 570 changes the signal level of the connection line SCL while releasing the connection line SDA, and takes in the response signal from the decoration control device 610.

  FIG. 16 is a timing chart of signal levels of the connection line SDA and the connection line SCL when the master IC 570 according to the first embodiment of the present invention outputs effect control data.

  First, when starting output of data, the master IC 570 changes the signal level of the connection line SDA from HIGH to LOW while maintaining the signal level of the connection line SCL at HIGH, thereby indicating a start condition signal. And the decoration control device 610 is notified that data will be output.

  Next, the master IC 570 outputs the slave address of the decoration control device 610 to be controlled consisting of 7 bits in total. Next, the master IC 570 outputs data indicating whether the write request is a read request to the eighth bit.

  The master IC 570 receives a response signal from the decoration control device 610 when the signal level of the connection line SCL becomes HIGH for the ninth time. Therefore, if the response signal is an ACK response signal, the signal level of the connection line SDA is LOW. If the response signal is NACK, the signal level of the connection line SDA changes to HIGH.

  Next, after outputting the address data, the master IC 570 outputs the data in the number of bits that is a multiple of 8. After outputting the eighth bit of data, master IC 570 outputs the ninth bit of data after waiting for an ACK response signal to be input. Thereafter, when data of a bit corresponding to a multiple of 8 is output, after confirming that an ACK response signal is input, a (multiple of 8 + 1) th bit is output and all data is output. Repeat until.

  If the master IC 570 outputs a bit that is a multiple of 8 after the data has been output and the ACK response signal is not received after a predetermined time, the master IC 570 assumes that the data transmission has failed and starts again. Send the condition. Next, the address data is output again via the connection line SDA, and the data is output again from the first bit while confirming the ACK response signal.

  The master IC 570 outputs the signal indicating the stop condition after outputting the data of the last bit of the data and waiting for the ACK response signal to be input.

  In FIG. 16, a total of 24 bits (slave address 8 bits, data 16 bits) are output from the time when the signal indicating the start condition is output until the time when the signal indicating the stop condition is output. , 24 bits or more, or 24 bits or less.

FIG. 17 shows the master IC 570 and the I ² CI / O expander 615 when the master IC 570 of the first embodiment of the present invention sets the effect control data in the decoration control device 610 by designating the slave individual address. It is a figure explaining the format of the data transmitted / received between.

The 8-bit data 1801 that is output first includes an address “A0 to A6” of the decoration control device 610 that is the target of data transmission, and a 1-bit R that indicates whether the data is a read request or a write request. / W identification data. Among the addresses “A0 to A6”, “A4 to A6” are fixed address portions having a value “110”, and “A0 to A3” are set to terminals A0 to A3 of the I ² CI / O expander 615. This corresponds to the address that has been set (see FIG. 8). The data 1801 corresponds to “ADDRESS” and “R / W” in FIG.

Next, the output 8-bit data 1802 includes setting data for the control register assigned to the output setting register 635 (see FIG. 7) of the I ² CI / O expander 615. This data 1802 corresponds to “DATA” transmitted first in FIG.

  Here, the control register will be described. The control register consists of 8 bits, and the upper 3 bits “AI0 to AI2” are automatic write parameters for designating the writing or reading method to the work register of the output setting register 635, and the lower 5 bits “D0 to D4” are the work. This is a register address that specifies an access start position (a start position at which writing starts or a start position at which reading starts) in the register.

  The automatic write parameter is accessed by the master IC 570 including only the area at the access start position specified by the register address (auto-increment is prohibited) or including the area adjacent to the area at the access start position specified. (Specifically, “000”, “100”, “101”, “110”, “111”) can be set.

  When a value of “000” is set in the automatic write parameter, auto-increment is prohibited, and only the area at the access start position specified by the register address is accessed, and the area other than the start position is not accessed. For example, if the register address is “10100”, only the storage area with the register number “14h” is accessed, and the other storage areas are not accessed.

  When the value of “100” is set in the auto-write parameter, auto-increment is permitted, and after accessing the area at the access start position specified by the register address, the area is accessed in order while moving the area in the direction of increasing the register number. repeat. Then, after accessing the storage area where the register number is “1Bh” at the end, the storage area where the register number is “00h” is accessed and accessed again sequentially while moving the area in the direction in which the register number increases. repeat. For example, if the register address is “10100”, after accessing the storage area where the register number is “14h”, the register number is “15h” → “16h” →→→ “1Bh” → “00h” → “01h” →... (Ie, all areas) are repeatedly accessed.

  When the value of “101” is set in the automatic write parameter, the register number is set after accessing the area of the access start position specified by the register address, as in the case of setting the value of “100” in the automatic write parameter. Access is repeated in order while moving the area in the direction of increasing. However, once the storage area where the register number is “11h” is accessed, the storage area where the register number is “02h” is accessed, and thereafter the section where the register numbers are “02h” to “11h”. The recording area (area related to LED brightness adjustment) is repeatedly accessed. For example, if the register address is “10100”, after accessing the storage area where the register number is “14h”, the register number is “15h” → “16h” →→→ “1Bh” → “00h” → “01h” →... After accessing the storage area where the register number is “11h”, the area where the register number is “02h” → “03h” → ··· “11h” → “02h” → “03h” → ··· , Repeatedly access.

  When the value “110” is set in the automatic write parameter, the register number is set after accessing the area of the access start position specified by the register address, as in the case where the value “100” is set in the automatic write parameter. Access is repeated in order while moving the area in the direction of increasing. However, once the storage area where the register number is “13h” is accessed, the storage area where the register number is “12h” is accessed, and thereafter the section where the register numbers are “12h” to “13h”. The recording area (area related to the LED blinking cycle) is repeatedly accessed. For example, if the register address is “10100”, after accessing the storage area where the register number is “14h”, the register number is “15h” → “16h” →→→ “1Bh” → “00h” → “01h” →... Then, after accessing the storage area where the register number is “13h”, the area where the register number is “12h” → “13h” → “12h” → “13h” →.

  When the value of “111” is set in the automatic write parameter, the register number is set after accessing the area of the access start position specified by the register address, as in the case of setting the value of “100” in the automatic write parameter. Access is repeated in order while moving the area in the direction of increasing. However, once the storage area where the register number is “13h” is accessed, the storage area where the register number is “02h” is accessed, and thereafter the section where the register numbers are “02h” to “13h”. The recording area (area related to the LED brightness and blinking cycle) is repeatedly accessed. For example, if the register address is “10100”, after accessing the storage area where the register number is “14h”, the register number is “15h” → “16h” →→→ “1Bh” → “00h” → “01h” →... After accessing the storage area where the register number is “13h”, the area where the register number is “02h” → “03h” → ··· “13h” → “02h” → “03h” → ··· , Repeatedly access.

  Returning to FIG. 17, the setting data 1803 to the work register is output following the setting data 1802 to the control register. This setting data 1803 corresponds to “DATA” transmitted after the second in FIG.

  When the automatic write parameter is “000”, the setting data 1803 is 8-bit data necessary for updating one storage area designated by the register address. When the automatic writing parameter is set to a value other than “000”, the setting data 1803 is a multiple of 8 necessary for repeatedly updating a plurality of areas starting from the storage area specified by the register address. Bit data.

FIG. 18 shows the master IC 570 and the I ² CI / O expander 615 when the master IC 570 according to the first embodiment of the present invention designates the slave individual address and sets the effect control data in the decoration control device 610. Specific numerical values are applied to the production control data exchanged with the. This figure illustrates the presentation control data that prohibits auto-increment and updates only one storage area of the work register, and is connected to the PORT0 terminal to the PORT3 terminal of the I ² CI / O expander 615. The case where the light emission state of LED is updated is assumed.

First, “1101100” indicating the slave address of the I ² CI / O expander 615 of the destination decoration control device 610 is assigned to the 8-bit data 1901 output first.

The 8-bit data 1902 to be output next is set in the control register of the output setting register 635 of the I ² CI / O expander 615 assigned to set the automatic writing parameter and LED output data. Value to be included.

Here, since the light emission state of the LED connected to the PORT0 terminal to the PORT3 terminal of the I ² CI / O expander 615 is set, LEDOUT0 (address = 10100) is designated as the register address.

  Note that “000” is designated in the auto-write parameter to prohibit auto-increment.

Next, the output 8-bit data 1903 includes data for setting the light emission mode of the decoration device 620 controlled by the destination decoration control device 610. Specifically, data set in the LEDOUT0 register is assigned. As a result, the light emission state (lighting, extinguishing, blinking, etc.) of the LED connected to the PORT0 terminal to the PORT3 terminal of the I ² CI / O expander 615 is designated, and the LED emits light in the designated state.

In this way, the light emission state of the LED PORT0 terminal ~PORT3 terminal I ² CI / O expander 615 is controlled, the other PORT terminal I ² CI / O expander 615 (PORT4~PORT15) also Control can be performed by specifying the value of the control register data 1902 and setting the output data 1903. Even if a motor or solenoid is connected to the PORT terminal, the same control is performed.

  FIG. 19 is a diagram illustrating another form of effect control data according to the first embodiment of this invention. In this figure, it is assumed that auto-increment is permitted and all storage areas of the work register are updated, and the transmission order of each data included in the presentation control data is defined.

  First, the master IC 570 transmits 8-bit data (data having the same format as the data 1901 in FIG. 18) that can specify the individual address of the decoration control device 610 to be controlled.

Next, the master IC 570 transmits data (data having the same format as the data 1902 in FIG. 18) set in the control register of the output setting register 635 of the I ² CI / O expander 615 to be controlled. In this figure, since the auto-increment is permitted and all the storage areas of the work register are updated, “100” is designated as the automatic write parameter, and the register address that designates the write destination or the read start position is designated. “00h” which is the head area of the work register is designated.

For this reason, in the I ² CI / O expander 615 of the decoration control device 610 to be controlled after receiving the control register setting value, the storage area (MODE1 register) with the register number “00h” is updated first. Will be.

Next, after transmitting the control register set value, the master IC 570 transmits a value (total of 8 bits) to be written to the MODE1 register. When the I ² CI / O expander 615 receives the write value, it updates the value of the MODE 1 register, increments the register number, and prepares to update the next “01h” storage area (MODE 2 register). .

Next, the master IC 570 transmits values to be written to the MODE2 register (8 bits in total), and thereafter transmits the set values in order to the remaining storage area registers whose register numbers are “02h” to “1Bh”. . Each time the I ² CI / O expander 615 receives the write value, the I ² CI / O expander 615 updates the value of the corresponding register, increments the register number, and repeats the preparation for updating the next storage area. The values of all the registers “00h” to “1Bh” assigned to are updated.

When the I ² CI / O expander 615 updates the storage area of “1Bh”, which is the last of the work registers, the register number is changed to “00h” and waits for the update of the MODE1 register.

20, when the master IC570 of the first embodiment of the present invention initializes the I ² CI / O expander 615, initialization instruction data transmitted from the master IC570 to I ² CI / O expander 615 It is a figure explaining the data format of.

  When the CPU 551 of the effect control device 550 instructs the master IC 570 to initialize the decoration control device 610, the master IC 570 transmits initialization instruction data to all the decoration control devices 610 connected thereto. .

  First, the 8-bit data 2001 output includes a fixed address “110” shown in FIG. 18 and a reset address “1011” (see FIG. 12), which is a common address. This data 2001 corresponds to “ADDRESS” in FIG. 16, and “0” indicating writing is set in the bit of “R / W”.

  In the next 8-bit data 2002 to be output, the first predetermined value “10100101” is output, and in the next 8-bit data 2003 to be output, the second predetermined value “01011010” is output. The data 2002 corresponds to “DATA” transmitted first in FIG. 16, and the data 2003 corresponds to “DATA” transmitted second in FIG.

When all the I ² CI / O expanders 615 connected to the master IC 570 receive initialization instruction data including a reset address, a first predetermined value, and a second predetermined value, the I ² CI / O expander 615 initializes itself.

After the output of the reset address, to that outputs a first predetermined value and second predetermined value, even though the master IC570 is not sending a reset address "1011", the influence such as noise, I ² This is to prevent the CI / O expander 615 from erroneously fetching the reset address “1011” and performing initialization at an incorrect timing.

Further, the reset address is an address common to all (in other words, a plurality) I ² CI / O expanders 615, unlike the individual address. Therefore, only transmit once initialization instruction data including the reset address, it means that initialize Select I ² CI / O expander 615 all (plural), I ² CI / O Aix Compared with the method of individually selecting the panda 615 and instructing initialization, it is possible to instruct initialization at high speed.

  In FIG. 20, the first predetermined value and the second predetermined value are different from each other, but may be the same value. Further, either the first predetermined value or the second predetermined value may be transmitted once.

  FIG. 21 is a diagram illustrating the abnormality determination table 2100 according to the first embodiment of this invention.

The abnormality determination table 2100 is stored in the RAM 553 of the effect control device 550. The abnormality determination table 2100 monitors the connection state between the master IC 570 of the production control device 550 and the I ² CI / O expander 615 connected to the master IC 570, and corresponds to the connection state confirmation result, An error flag 2105 described later corresponding to the corresponding I ² CI / O expander 615 is set.

  The abnormality determination table 2100 includes an I / O expander address 2101, a slave address 2102, an error counter 2103, a comparison value 2104, and an error flag 2105.

The I / O expander address 2101 corresponds to the address (see FIG. 8) set at the terminals A0 to A3 of the I ² CI / O expander 615 connected to the master IC 570.

In the slave address 2102, the slave address registered in the I ² CI / O expander address table 1200 shown in FIG. 12 is registered.

When the error counter 2103 monitors whether or not the ACK from the I ² CI / O expander 615 has been received in response to the transmission of the effect control data from the master IC 570 to the I ² CI / O expander 615, It is incremented when it fails to receive this ACK twice in succession.

A predetermined value is registered in the comparison value 2104. In the error flag 2105, an error flag indicating whether or not an abnormality has occurred in the connection state of the entry with the I ² CI / O expander 615 is registered.

Specifically, when the incremented value of the error counter 2103 reaches a predetermined value registered in the comparison value 2104, the error flag 2105 is set to ON, and the I ² CI / O expander 615 of the entry. It is registered that an error has occurred.

Note that the “0110” I ² CI / O expander 615 registered in the I / O expander address 2101 controls movable devices such as the accessory driving SOL 560 and the accessory driving MOT 561 as shown in FIG. 8B. Yes. Therefore, the decoration control device 510 including the I ² CI / O expander 615 is referred to as a movable control device (movable group unit control means).

On the other hand, the I ² CI / O expander 615 other than “0110” registered in the I / O expander address 2101 controls a light emitting device such as an LED as shown in FIG. 8A. For this reason, the decoration control device 510 including the I ² CI / O expander 615 is referred to as a light emission control device (light emission group unit control means) in order to distinguish it from the aforementioned movable control device.

  In FIG. 21, the predetermined value registered in the comparison value 2104 of the entry of the movable control device (the value registered in the I / O expander address 2101 is “0110”) is “100”. This is different from the predetermined value “300” registered in the comparison value 2104 of the entry. That is, the comparison value 2104 of the movable control device is set to a value lower than the comparison value 2104 of the light emission control device.

  This is because, when an abnormality occurs in the movable control device, the accessory driving MOT 561 rotates too much and the movable accessory 60 moves beyond the operable range. This is because it is intended to make an abnormality determination in as short a time as possible in order to prevent the member near the accessory from being damaged.

  Specifically, in this embodiment, as will be described later, the data output process (see FIG. 22) of the light emission control device is executed in synchronization with the VDP interrupt (approximately 33.3 ms cycle), and is movable. The data output process of the control device is executed in synchronization with the timer interrupt (2 ms cycle).

As described above, if the ACK from the I ² CI / O expander 615 cannot be received for the ^second transmission of the presentation control data from the master IC 570 to the I ² CI / O expander 615, the error counter 2103 Is incremented.

  Therefore, when an abnormality has occurred in the movable control device, the execution period of the data output process is 2 ms and the comparison value 2104 is “100”, so the abnormality is detected in the movable control device in 2 ms × 100 = 0.2 s. Can be detected. If an abnormality has occurred in the light emission control device, the execution period of the data output process is 33 ms and the comparison value 2104 is “300”. Therefore, the light emission control device is abnormal in 33.3 ms × 300≈10 s. Detect that occurred.

  For this reason, the error determination of the movable control device is performed more frequently than the error determination of the light emission control device, and it is possible to detect that an abnormality has occurred in the movable control device earlier than the abnormality in the light emission control device. Therefore, it is possible to prevent the movable accessory 60 from moving beyond the operable range and damaging the movable accessory 60 and members in the vicinity of the movable accessory.

  On the other hand, a light emitting device such as an LED is less likely to be damaged due to a malfunction, and therefore no problem occurs even if it takes time to determine an abnormality related to the light emission control device.

  Therefore, the determination cycle is shortened only for the decoration control device 510 that needs to perform the abnormality determination in a short time, and the abnormality determination of the other decoration control devices 510 is performed with a sufficient period, so that the processing load is balanced. It is possible to execute the abnormality determination process in consideration.

  FIG. 22 is a flowchart of processing by the effect control device 550 according to the first embodiment of this invention.

  The processing of the effect control device 550 shown in FIG. 22 is executed by the CPU 551 of the effect control device 550.

  When the production control device 550 is turned on, the production control device 550 first executes the processing of steps 2201 to 2203, and the synchronization signal (for example, the 33 ms second cycle) synchronized with the image update cycle from the VDP 556 in the processing of step 2204. (The synchronization signal) is input to the CPU 551 as an interrupt signal. Thereafter, each time the synchronization signal synchronized with the image update cycle is input from the VDP 556 to the CPU 551 as an interrupt signal, the processing in steps 2205 to 2214 is repeatedly executed.

  First, the effect control device 550 initializes the RAM 553 of the effect control device 550 (2201).

  Then, the effect control device 550 inputs a reset pulse to the master IC 570 via the input / output I / F 558 and the NOR gate circuit 590, and initializes the master IC 570 in hardware (2202).

Then, the effect control device 550 performs slave reset processing for outputting initialization instruction data from the master IC 570 in order to initialize the I ² CI / O expander 615 of all the decoration control devices 610 connected to the master IC 570. Execute (2203). The slave reset process will be described in detail with reference to FIG.

  Next, the effect control device 550 permits the reception of a synchronization signal (VDP interrupt) synchronized with the image update cycle from the VDP 556 (2204). At this time, the acceptance of the timer interrupt is also permitted.

  Then, in order to display the image on the display device 53, the effect control device 550 outputs data serving as a command for displaying the image on the VDP 556 (2205), and outputs the sound from the speaker 30 according to the gaming state. The sound control data is output to the sound LSI 557, and the sound LSI 557 is caused to output sound from the speaker 30 based on the sound control data (2206).

  Next, the effect control device 550 executes light emission control slave output processing for outputting effect control data from the master IC 570 to the light emission control device 550 (2207). Details of the light emission control slave output processing will be described with reference to FIG.

  Then, the production control device 550 edits data to be output next to the VDP 556 (2208), edits sound control data to be output to the sound LSI 557 (2209), and is then output to the light emission control device of each group. The production control data is edited (2210).

  Next, the production control device 550 refers to the abnormality determination table 2100 and executes error determination processing (2211).

  Specifically, the effect control device 550 determines whether or not the error flag 2105 of the entry corresponding to the movable control device in the abnormality determination table 2100 is ON, that is, whether or not an abnormality has occurred in the movable control device. judge.

  When it is determined that no abnormality has occurred in the movable control device, the effect control device 550 refers to the abnormality determination table 2100 and turns on the error flags 2105 (preliminary determination results) of all the light emission control devices. That is, it is determined whether or not an abnormality has occurred in all the light emission control devices. In other words, it is determined whether or not there is even one light emission control device in which the error flag 2105 is OFF.

  Next, the effect control device 550 determines whether or not the reset condition is satisfied in the determination result of the processing in step 2211 (2212).

  Specifically, when the error flag of the movable control device is ON at the time of the process of step 2211, it is considered that the reset condition is satisfied in the process of step 2212. Alternatively, when all the error flags are ON at the time of the processing of step 2211 (when there is no light emission control device in which the error flag 2105 is OFF), the reset condition is satisfied in the processing of step 2212. Is considered. In other cases, it is considered that the reset condition is not satisfied in step 2212.

When it is determined that the reset condition is satisfied in the process of step 2212, the effect control device 550 initializes the master IC 570 (2213), and transfers from the master IC 570 to all the I ² CI / O expanders 615 connected to the master IC 570. At the same time, a slave reset process for outputting initialization instruction data is executed (2214), and thereafter, the process waits until a synchronization signal is input from the VDP 556 to the CPU 551.

As described above, when it is determined that the reset condition is satisfied, in the process of step 2214, all the I ² CI / O expanders 615 connected to the master IC 570 are instructed to initialize at the same time. In other words, since all the I ² CI / O expanders 615 are selected and initialized at the same time, it is compared with a method of individually selecting the I ² CI / O expanders 615 and instructing initialization. Initialization can be performed at high speed, and the I ² CI / O expander 615 can be returned to a normal state at high speed.

Note that the RESET terminal (see FIG. 7) input to all the I ² CI / O expanders 615 is electrically connected to the CPU 551, and the RESET of all the I ² CI / O expanders 615 is performed simultaneously from the CPU 551. Even when the reset signal is transmitted to the terminal, it is possible to simultaneously select and initialize all the I ² CI / O expanders 615.

  If it is considered that the reset condition is satisfied in the process of step 2212, it is considered that an abnormality has occurred in the master IC 570. Therefore, the master IC 570 is also initialized in the process of step 2213.

  Since the master IC 570 functions as a signal level control means for controlling the signal levels of the connection line SDA and the connection line SCL according to a command from the CPU 551, an abnormality related to data transmission has occurred in all the light emission control devices. In this case, it may be considered that an abnormality has occurred in the master IC 570 itself.

  Therefore, when an abnormality relating to data transmission occurs in all the decoration control devices 610, the master IC 570 is initialized by the CPU 551 (arithmetic processing means) just in case. Accordingly, even if an abnormality occurs in the master IC 570, the master IC 570 can be reliably controlled.

  In this case, the CPU 551 inputs a reset pulse to the master IC 570 via the input / output I / F 558 and the NOR gate circuit 590 to reset the master IC 570 in hardware. Note that the master IC 570 may be reset in software by writing information from the CPU 551 to the reset register 573 via the bus 563.

  On the other hand, if it is determined in step 2212 that the reset condition is not satisfied, steps 2213 and 2214 are not executed, and the process waits until a synchronization signal is input from the VDP 556 to the CPU 551.

In this way, in the process of FIG. 22, the effect control data is sent from the master IC 570 of the effect control device 550 to the I ² CI / O expander 615 of the decoration control device 610 in synchronization with the cycle of updating the image of the display device 53. The I ² CI / O expander 615 controls the effect device 620 based on the received effect control data, so that the effect on the display device 53 and the effect on the effect device 620 are harmonized, giving the player a sense of incongruity. Because there is no, it can raise interest.

Also, whenever the decoration control device 610 receives the effect control data transmitted from the master IC 570 in synchronization with the cycle of updating the image on the display device 53, the I ² CI / O expander 615 updates the work register. The value is updated. Therefore, since the value of the work register is updated to the latest state every time, even if the value of the work register is destroyed due to noise or the like, it can be restored to a normal value.

  In addition, since the error determination process executed in the process of step 2211 is executed in synchronization with the cycle of updating the image of the display device 53, the error determination execution frequency can be made appropriate, that is, the error determination process execution frequency. If there is too much, the processing load of the CPU 551 of the effect control device 550 increases, and conversely, if the error determination processing is executed too little, it will not be possible to properly detect that an abnormality has occurred. Therefore, processing errors can be prevented by performing error determination at an appropriate frequency.

  FIG. 23 is a flowchart of timer interrupt processing according to the first embodiment of this invention.

  The timer interrupt process is executed in such a manner that the CPU 551 interrupts the process of FIG. 22 when the CPU 551 accepts a timer interrupt generated at a cycle of 2 ms under the condition that the timer interrupt is permitted.

  First, the effect control device 550 selects a movable control device (2301), and executes a slave continuous output process for outputting data from the master IC 570 to the movable control device selected in step 2301 (2302). The slave continuous output process will be described in detail with reference to FIG.

  Then, the effect control device 550 edits data to be output next to the movable control device (2303), and ends the timer interrupt process.

  FIG. 24 is a flowchart of light emission control slave output processing according to the first embodiment of this invention.

  The light emission control slave output process is the process of step 2207 shown in FIG.

  The effect control device 550 selects one light emission control device from a plurality of light emission control devices (2401), and executes slave continuous processing for outputting data from the master IC 570 to the light emission control device selected in the processing of step 2401. (2402).

  Then, the effect control device 550 determines whether or not the data has been output to all the light emission control devices (2403).

  If it is determined in step 2403 that data has not been output to all the light emission control devices, the next light emission decoration control device is selected (2404), and the light emission control device selected in step 2404 is mastered. Slave continuous processing for outputting data from the IC 570 is executed (2402).

  On the other hand, if it is determined in step 2403 that data has been output to all the light emission control devices, the light emission control slave output process is terminated, and the process proceeds to step 2208 shown in FIG.

  FIG. 25 is a flowchart of slave continuous processing according to the first embodiment of this invention.

  First, the effect control device 550 sets 0 to an ACK counter that counts that reception of an ACK response signal has failed (2501).

  Next, the effect control device 550 generates data to be output to the selected decoration control device 610 (2502).

  Then, the effect control device 550 executes a buffer setting process for setting the data generated in the process of step 2502 in the output BUF 572 (2503).

  Then, the master IC 570 changes the signal levels of the connection line SDA and the connection line SCL to a signal level indicating a start condition (2504).

  Specifically, the master IC 570 outputs a signal indicating a start condition by changing the signal level of the connection line SDA from HIGH to LOW while maintaining the signal level of the connection line SCL at HIGH.

  Note that, after outputting a signal indicating the start condition, the master IC 570 changes the level of the connection line SCL to LOW in order to send data to the decoration control device 610 to be controlled.

  Then, the master IC 570 converts the 8-bit data of the slave address of the decoration control device 610 to be controlled from the data stored in the output BUF 572 while changing the signal level of the connection line SCL. (2505).

  Since the address data output in the process of step 2505 is an 8-bit data string, the address data is output in one output process (output while the connection line SCL changes to HIGH for 8 times).

When the address data output in the process of step 2505 is input to the decoration control device 610, the I ² CI / O expander 615 of the decoration control device 610 receives the input address data and the address set in itself. It is determined whether or not.

The I ² CI / O expander 615 in which an address that matches the input address data is set immediately after the connection line SCL is changed from LOW to HIGH for the eighth time, A response signal is output from the connection line SDA to the master IC 570 when the connected connection line SCL changes to the LOW level.

  Next, the master IC 570 confirms whether or not an ACK response signal is input to the master IC 570 within a predetermined time after the address data is output in the processing of step 2505 (2506).

  Next, the master IC 570 determines whether or not an ACK response signal is input within a predetermined time after the address data is output in the process of step 2502 based on the confirmation result of the process of step 2506 (2507). ).

  If it is determined in step 2507 that an ACK response signal has not been input within a predetermined time after address data is output in step 2505, master IC 570 generates an interrupt (2508). ), The CPU 551 is informed that an ACK response signal has not been input.

  When the CPU 551 receives the interrupt generated in the processing of step 2508, it determines whether or not the ACK counter is 0 (2509).

  If it is determined in step 2509 that the ACK counter is 0, the ACK counter is updated by +1 to count that the reception of the ACK response signal has failed (2510), and the same data is again transmitted to the decoration control. Return to the processing of step 2502 for transmission to the device 610.

On the other hand, when it is determined in step 2509 that the ACK counter is not 0 (that is, when the ACK signal cannot be received twice in succession), the CPU 551, among the entries registered in the abnormality determination table 2100, The entry that matches the address of the I ² CI / O expander 615 of the decoration control device 610 in which the I / O expander address 2101 is selected is selected, and the error counter 2103 of the selected entry is incremented (2511).

  Then, the CPU 551 determines whether or not the value of the error counter 2103 incremented in the process of step 2511 has reached the comparison value 2104 (2512).

  If the error counter 2103 incremented in the process of step 2511 has reached the comparison value 2104 and is determined in the process of step 2512, the CPU 551 selects the entry registered in the abnormality determination table 2100. The error flag of the entry of the decoration control device 610 is set to ON (2513), and the master IC 570 changes the signal level of the connection line SDA and the connection line SCL to a signal level indicating a stop condition (2514). End the output process.

  On the other hand, if the value of the error counter 2103 incremented in step 2511 does not reach the comparison value 2104, if it is determined in step 2512, the process proceeds to step 2514, and the connection line SDA and connection line SCL. The signal level is changed to a signal level indicating a stop condition, and the slave continuous output process is terminated.

  On the other hand, if it is determined in step 2507 that an ACK response signal is input within a predetermined time after the address data is output in step 2502, the master IC 570 is stored in the output BUF 572. It is determined whether all the data that have been output have been output (2515).

  If it is determined in step 2515 that all data stored in the output BUF 572 has not been output, the master IC 570 outputs the next 1-byte data to the selected decoration control device 610. (2516), the process proceeds to step 2506.

Note that the I ² CI / O expander 615 of the decoration control device 610 whose address data output in the process of step 2505 matches the address set to itself is used as the connection line. A response signal is output from the connection line SDA to the master IC 570 when the SCL changes from LOW to HIGH and then the connection line SCL changes from HIGH to LOW.

  On the other hand, if it is determined in step 2515 that all data stored in the output BUF 572 has been output, the master IC 570 generates an interrupt (2517) and is stored in the output BUF 572. The CPU 551 is notified that all the data is output.

  The CPU 551 clears the error counter 2103 of the entry of the selected decoration control device 610 among the entries registered in the abnormality determination table 2100 (2518), and sets the error flag 2105 of the entry to off (2519). ), The process proceeds to step 2514, the master IC 570 outputs a signal indicating the stop condition, and the slave continuous output process ends.

  In the processing according to FIG. 25, the master IC 570 determines the success or failure of the data transfer by fetching the response signal from the decoration control device 610 after outputting the 8-bit data, and if the data transfer has failed (that is, When the NACK response signal is input to the master IC 570), the output data is output again only once, so that the data can be output to the decoration control device 610 as reliably as possible, and the malfunction of the rendering device is prevented. it can. Further, by outputting the output data once again, it is possible to prevent the data transmission time from becoming longer than necessary.

  In the process of FIG. 25, when the master IC 570 transmits the start condition in the process of step 2504, the connection line SDA needs to be HIGH, but the connection line SDA is LOW due to the influence of noise or the like. There may be a case where the state remains unchanged.

In the present embodiment, only the slave address that the master IC 570 transmits to the I ² CI / O expander 615 of the decoration control device 610 has R / W identification data “0” (means writing). (Refer to FIG. 11), but may be transmitted to the I ² CI / O expander 615 when the R / W identification data is “1” (meaning reading) due to the influence of noise or the like. is there.

In this case, the I ² CI / O expander 615 enters the read mode, and the connection line SDA is transferred from the I ² CI / O expander 615 to the master IC 570 in response to the signal level of the connection line SCL being changed by the master IC 570. A process for transmitting data bit by bit through the network is performed.

At this time, each time the I ² CI / O expander 615 transmits 8-bit data, the I ² CI / O expander 615 performs a process of receiving an acknowledge signal from the master IC 570 via the connection line SDA. The data transmission is performed, and thereafter, the 8-bit data transmission and the acknowledge signal confirmation are repeated. During this time, the connection line SDA is occupied by the I ² CI / O expander 615.

On the other hand, if the I ² CI / O expander 615 cannot receive an acknowledge signal from the master IC 570 via the connection line SDA after 8-bit data transmission, the I ² CI / O expander 615 releases the connection line SDA and stops data transmission. When the I ² CI / O expander 615 receives an acknowledge signal from the master IC 570 via the connection line SDA, the I ² CI / O expander 615 interprets that the acknowledge signal is received if the connection line SDA is at the LOW level. If SDA is HIGH, it is interpreted that no acknowledge signal is received.

Therefore, when the data from the master IC 570 changes due to the influence of noise or the like, and the I ² CI / O expander 615 that receives the changed data and enters the read mode is generated, the connection line SDA is changed. It will not be released forever.

In such a case, the signal level of the connection line SDA remains LOW, and the master IC 570 and the I ² CI / O expander 615 of the decoration control device 610 originally intended for transmission Cannot communicate with each other via the connection line SDA.

  Therefore, the master IC 570 determines whether the signal level of the connection line SDA is HIGH in order to determine whether or not data can be output from the connection line SDA before outputting the signal indicating the start condition in the processing of step 2504. It is determined whether or not.

  When it is determined that the signal level of the connection line SDA is not HIGH, data cannot be output from the connection line SDA. Therefore, the driver 576A does not apply an operable voltage to the transistor 578A without turning on the transistor 578A (connection line With the SDA released, the signal level of the connection SCL is changed at least nine times.

By performing such processing, the I ² CI / O expander 615 that has entered the read mode outputs data to the connection line SDA in accordance with the change in the signal level of the connection SCL. The timing for confirming the acknowledge signal from the master IC 570 is generated while the change is made at least nine times. At this time, since the connection line SDA is released, it becomes HIGH level, and the I ² CI / O expander 615 that has entered the read mode determines that it has not received an acknowledge signal, so it stops data transmission and disconnects the connection line SDA. Will be released.

  Note that this processing may be performed not only before the signal indicating the start condition is output but also before the master IC 570 outputs data to the decoration control device 610. Specifically, it may be executed before the processing of steps 1702, 1707, and 1713.

In this way, the connection line SDA is forcibly released from the I ² CI / O expander 615 of the decoration control device 610 in the read mode, so that the signal level of the connection line SDA is maintained at HIGH. .

  FIG. 26 is a flowchart of slave reset processing according to the first embodiment of this invention.

  The slave reset process is executed in the process of step 2203 or 2214 shown in FIG.

  First, the master IC 570 changes the signal levels of the connection line SDA and the connection line SCL to a signal level indicating a start condition (2601).

  Next, the master IC 570 transmits 1 byte of data indicating the reset address (see FIG. 20) via the connection line SDA while changing the signal level of the connection line SCL (2602).

  Next, the master IC 570 checks whether or not an ACK response signal is input to the master IC 570 within a predetermined time after the data is output (2603).

  Next, the master IC 570 determines whether or not an ACK response signal is input within a predetermined time after the data is output based on the confirmation result of the processing in step 2603 (2604).

If it is determined in step 2604 that an ACK response signal has not been input within a predetermined time after data is output, master IC 570 generates an interrupt (2605) and outputs data from master IC 570. After that, it is notified that an ACK response signal has not been input within a predetermined time, and the processing returns to step 2601 to output again data for initializing the I ² CI / O expander 615.

  If it is determined in step 2604 that an ACK response signal is input within a predetermined time after the data is output, the master IC 570 generates an interrupt (2606) and outputs the data from the master IC 570. That an ACK response signal is input within a predetermined time.

  Then, the master IC 570 has three types of data constituting the initialization instruction data (data 2001 including a reset address, data 2002 having a first predetermined value, and data 2003 having a second predetermined value shown in FIG. 20). It is determined whether or not all have been output (2607). Since the output order of these data is predetermined, it is only necessary to determine whether or not it is immediately after the data 2003 having the second predetermined value is output.

  If it is determined in step 2607 that all the data constituting the initialization instruction data has not been output, the master IC 570 transmits the first predetermined value (first predetermined value) shown in FIG. If the transmission of the value is successful, data indicating the second predetermined value) is output (2608), and the process proceeds to step 2603.

  On the other hand, if it is determined in step 2607 that all the data constituting the initialization instruction data has been output, that is, if the data indicating the second predetermined value shown in FIG. The master IC 570 changes the signal levels of the connection line SDA and the connection line SCL to a signal level indicating a stop condition (2609), and ends the slave reset force process.

When all the I ² CI / O expanders 615 connected to the master IC 570 receive the reset signal composed of the reset address, the first predetermined value, and the second predetermined value, the I ² CI / O expander 615 Initialize registers.

Therefore, the master IC 570 instructs all the I ² CI / O expanders 615 connected to the master IC 570 to perform initialization at the same time.

As described above, since the I ² CI / O expander 615 needs to be initialized when an abnormality occurs in the I ² CI / O expander 615, the initialization of the I ² CI / O expander 615 is performed. Fast initialization is required. For this reason, in this embodiment, since all the I ² CI / O expanders 615 connected to the master IC 570 are initialized at the same time, high-speed initialization can be realized.

  FIG. 27 is a diagram illustrating a connection form of the decoration control device 610 provided in the entire gaming machine according to the first embodiment of the present invention, and is a diagram illustrating the decoration control device 610 provided in the front frame 3 in particular.

  The decoration control device 610 is mainly attached to the game board 10 and the front frame 3. The LED controlled by the decoration control device 610 attached to the front frame 3 irradiates the decoration member 9, the illumination unit 11, and the abnormality notification LED 29.

  The gaming machine has a plurality of specifications, and there are a normal version gaming machine 1 and a low price gaming machine 1. The normal version gaming machine 1 includes a front frame 3 (normal version front frame) including a decorative member 9 of standard specifications. The low-priced gaming machine 1 includes a front frame 3 (low-priced front frame) including a decorative member 9 ′ configured at a lower cost than a standard decorative member 9.

  The number of the decoration control devices 610 attached to irradiate the decorative member 9 is different between the normal plate front frame 3 and the inexpensive plate front frame 3. Specifically, the decoration member 9 of the normal plate front frame 3 is irradiated by four decoration control devices 610, and the decoration member 9 ′ of the inexpensive plate front frame 3 is irradiated by two decoration control devices 610. The decoration member 9 is illuminated by a maximum of 60 LEDs, whereas the decoration member 9 'is illuminated by a maximum of 30 LEDs, so that the decoration member 9 is brighter than the decoration member 9'. For this reason, the control of the decoration control device 610 when the normal plate front frame 3 is attached is different from the control of the decoration control device 610 when the inexpensive plate front frame 3 is attached.

The address of the I ² CI / O expander 615 of the decoration control device 610 attached to the normal plate front frame 3 and the unique address of the I ² CI / O expander 615 of the decoration control device 610 attached to the inexpensive plate front frame 3 are If it is the same, the production control device 550 for the normal version that performs control when the front plate 3 is attached to the normal version, and the production control device for the low price version that performs control when the front plate 3 is attached to the low cost version. 550 and the production control device 550 must be replaced in accordance with the front frame 3 to be attached. Therefore, when the manufacturer ships the gaming machine 1, the production control device 550 for the normal version and the production control device 550 for the low-priced version must be prepared, which increases the manufacturing cost.

For this reason, in this embodiment, different addresses are assigned to the individual addresses of the I ² CI / O expander 615 of the decoration control device 550 whose control is different between the normal version front frame 3 and the cheap version front frame 3. The production control device 550 can perform control for the normal version and control for the inexpensive version. Thereby, it is not necessary to prepare the production control device 550 for the normal version and the production control device 550 for the inexpensive version, and the manufacturing cost can be reduced.

Specifically, the I ² CI / O expander 615 of the four decoration control devices 610 (first specification-dependent group unit control means) connected to the LEDs that irradiate the decoration member 9 of the normal plate front frame 3. “1001”, “1010”, “1100”, and “1101” are assigned to the unique addresses.

On the other hand, the address of the I ² CI / O expander 615 (second specification-dependent group unit control means) of the two decoration control devices 610 connected to the LEDs that irradiate the decoration member 9 ′ of the low-priced front frame 3 is used. Are assigned “1110” and “1111”, which are different from the unique addresses of the I ² CI / O expanders 615 of the four decoration control devices 610 connected to the LEDs that irradiate the decoration member 9 of the front plate 3 of the normal plate.

Then, regardless of whether it is used for the normal version front frame 3 or the cheap version front frame 3, the effect control device 550 assigns it to the I ² CI / O expander 615 of the decoration members 9, 9 ′. The effect control data including all the unique addresses “1001”, “1010”, “1100”, “1101”, “1110”, and “1111” are transmitted to the decoration control device 610.

  Therefore, the decoration control device 610 of the normal plate front frame 3 and the decoration control device 610 for the low cost version can be controlled by one production control device 550 that can perform the control for the normal version and the control for the low cost version. Manufacturing cost can be reduced.

In addition, the I ² CI / O expander 615 of the decoration control device 610 connected to the illumination unit 11 that performs the same control in the normal version front frame 3 and the inexpensive version front frame 3 and the LED that emits the abnormality notification LED 29 includes: It is not necessary to use different addresses for the normal version front frame 3 and the low cost version front frame 3, and the same address is assigned.

The low price front frame 3 does not use the I ² CI / O expander 615 with the unique addresses “1001”, “1010”, “1100”, “1101”. The I ² CI / O expander 615 with addresses “1110” and “1111” is not used. For this reason, there is an unconnected I ² CI / O expander 615 in the abnormality determination table 2100 (FIG. 21) regardless of the front frame 3 of any specification. If data transmission / reception is performed between one of the I ² CI / O expanders 615 registered in 2100 and the master IC 570, the data is processed as a normal state, and there is no problem.

(Second Embodiment)
The second embodiment of the present invention will be described below.

  FIG. 28 is a diagram for explaining a second embodiment of the present invention. In the second embodiment, the production control device 550 includes a plurality of master ICs 570.

  In FIG. 28, the effect control device 550 includes three master ICs 570A to 570C.

  The master IC 570A is connected to the relay board 600A, and the relay board 600A is connected in series to the decoration control devices 610A to 610C and is connected in series to the decoration control devices 610D to 610F.

  The master IC 570B is connected to the relay board 600B, and the relay board 600B is connected in series to the decoration control devices 610G to 610I and is connected in series to the decoration control devices 610J to 610L.

  The master IC 570C is connected to the relay board 600C, and the relay board 600C is connected in series to the decoration control devices 610M to 610O and is connected in series to the decoration control devices 610P to 610R.

  Here, the decoration control device 610 group connected to one master IC 570 is referred to as a system. Specifically, in the case of the master IC 570A, the system is the relay board 600A and the decoration control devices 610A to 610F.

  Since the master IC 570 can output data to the connected decoration control device 610, the master IC 570 can control the connected decoration control device 610.

With such a configuration, the number of I ² CI / O expanders 615 that can be controlled by one master IC 570 is eliminated (up to 14 as shown in FIG. 12), and a variety of presentation control is possible. Can be expected to do.

Also in this embodiment, data transmission / reception is performed between one I ² CI / O expander 615 and the master IC 570 among the I ² CI / O expanders 615 registered in the abnormality determination table 2100 (FIG. 21). For example, the process is performed in a normal state, but the abnormality determination and the initialization process of the I ² CI / O expander 615 and the master IC 570 are performed independently for each system in the first embodiment. Is different.

  In the present embodiment, an abnormality determination table 2100 is prepared for each system. Specifically, a first abnormality determination table for determining, for each decoration control device, data transmission / reception abnormality performed between the master IC 570A and the decoration control devices 610A to 610F, the master IC 570B, and the decoration control devices 610G to 610L. A second abnormality determination table for determining an abnormality in data transmission / reception performed between each of the decoration control devices, and an abnormality in data transmission / reception performed between the master IC 570C and the decoration control devices 610M to 610R for each decoration control device. There are three types of tables, a third abnormality determination table to be determined.

If it is determined in any abnormality determination table that a data transmission / reception abnormality has occurred with respect to all I ² CI / O expanders 615, all the decoration control devices 610 belonging to the abnormality determination table are initialized. At the same time, the corresponding master IC 570 is also initialized. However, the decoration control device 610 and the master IC 570 belonging to other abnormality determination tables are not initialized.

For example, if it is determined in the first abnormality determination table described above that data transmission / reception abnormality has occurred with respect to all the I ² CI / O expanders 615, only the master IC 570A and the decoration control devices 610A to 610F are initialized. The other master ICs 570B and 570C and the decoration control devices 610G to 610R are not initialized.

  As a method for initializing the master ICs 570A to 570C, there are a soft reset and a hard reset.

  In the soft reset, the CPU 551 initializes one of the master ICs 570A to 570C. Specifically, each of the master ICs 570A to 570C includes a reset register (the reset register 573 in FIG. 4). When the CPU 551 writes a specific value to the reset register via the bus 563, the specific value is written. Only the master IC provided with the reset register is initialized.

  In the hard reset, the RESET terminals of the master ICs 570A to 570C are connected to the input / output I / F 558. When the voltage applied to the input / output I / F 558 is held low for a predetermined time, it is applied to the RESET terminal. The voltage is also held low for a predetermined time, and all the master ICs 570A to 570C are initialized.

In this embodiment, when the power is turned on, all the master ICs 570A to 570C are initialized by hardware reset, and the corresponding decoration control device 610 is initialized. If any abnormality determination table determines that a data transmission / reception abnormality has occurred with respect to all the I ² CI / O expanders 615, only the master IC belonging to the abnormality determination table is initialized by a soft reset. At the same time, the corresponding decoration control device 610 is initialized, but the other master IC and decoration control device 610 are not reset.

  As described above, when the production control device 550 includes a plurality of master ICs 570, only the master IC in which an abnormality has occurred is reset, so that the decoration of the entire gaming machine 1 does not pause and the player feels uncomfortable. Can be suppressed. Further, when all the master ICs 570 are to be simultaneously reset at a high speed, the reset can be performed by a hard reset, so that various types of reset processing can be performed.

  The embodiment disclosed this time is illustrative in all points and is not restrictive. The scope of the present invention is shown not by the above description of the invention but by the scope of claims, and is intended to include all modifications within the scope and meaning equivalent to the scope of claims.

  The following are typical examples of aspects of the present invention other than those described in the claims.

  (1) In a gaming machine comprising game control means for comprehensively controlling a game, and effect control means for controlling a plurality of effect devices for effecting a game in response to a command from the game control means, The plurality of effect devices are divided into a plurality of groups, group unit control means for controlling the effect devices belonging to the divided groups is provided for each group, and the effect control means is a plurality of the group unit control means. A group overall control means for overall control, a timing signal line for transmitting a timing signal from the group overall control means to the group unit control means, and between the group overall control means and the group unit control means The group control unit and the group unit control unit are connected by a data line for communicating data in the group, and the group Data communication is enabled between the overall control means and each group unit control means, and the group overall control means sets the signal level of the data line to a signal level corresponding to transmission data while By repeatedly changing the signal level of the signal line, a transmission unit that sequentially transmits data to the group unit control unit, and a response signal capturing that receives a response signal from the group unit control unit after data transmission by the transmission unit. A determination unit for determining success or failure of data transmission based on the response signal acquired by the response signal acquisition unit, and the group unit control unit when the determination unit determines that the data transmission has failed. Group initialization means for instructing the initialization of each of the group unit control means and the group unit control means. Effect control information transmitting means for transmitting the effect control information for specifying the output mode of the apparatus, wherein the group unit control means sends the response signal via the data line to which the transmitting means has transmitted data. A response signal output means for outputting to the group overall control means, wherein the effect control information transmitting means individually selects a plurality of group unit control means to perform data transmission, and the group initialization means includes a plurality of groups A gaming machine characterized by simultaneously selecting unit control means and instructing initialization.

  (2) The group initialization means instructs initialization to the group unit control means of the transmission destination by transmitting initialization instruction data to the group unit control means, and the initialization instruction data, the effect control information, Is transmitted to the plurality of group unit control means via the data line by the transmission means. The gaming machine according to (1),

  (3) Each group unit control means is pre-assigned a common address that is common among a plurality of group unit control means, and individual addresses that are different among the group unit control means, and the group initialization The means causes the transmission means to transmit initialization instruction data including the common address, and the effect control information transmitting means transmits the effect control information to the individual effect control information when transmitting the effect control information. The group unit control means of the transmission destination is specified by including an address, and the group unit control means includes an address determination means for determining the content of the address included in the data transmitted by the transmission means, and the address If the determining means determines that the address is an individual address addressed to itself, The received data is fetched as effect control information, the output mode of the effect device is controlled based on the effect control information, and when the address determining means determines that the address is a common address, it is transmitted. The gaming machine as set forth in (2), wherein the data is taken in as initialization instruction data and is initialized based on the initialization instruction data.

  (4) The group unit control means includes first and second specification-dependent group unit control means assigned with different individual addresses, and the gaming machine includes the first and second specification units. One of the two specification-dependent group unit control means is selectively provided, and the effect control information transmitting means includes any of the first and second specification-dependent group unit control means. Even so, the transmission means transmits the presentation control information including the individual addresses of the first and second specification-dependent group unit control means. .

  (5) The determination means determines success or failure of data transmission for all group unit control means controlled by the group overall control means, and the group initialization means includes all group control means controlled by the group overall control means. When the determination unit determines that the data transmission to the group unit control unit has failed, all the group unit control units controlled by the group overall control unit are simultaneously instructed to initialize. The gaming machine according to any one of (1) to (4).

  (6) The group overall control unit controls the signal level of the data line and the timing signal line based on a calculation processing unit that performs a calculation process related to the control of the rendering device and a command from the calculation processing unit. And when the group initialization unit instructs the group unit control unit to perform initialization simultaneously, the signal level control unit is initialized by the arithmetic processing unit. The gaming machine according to any one of (1) to (5), characterized in that:

  (7) The group overall control unit controls the signal level of the data line and the timing signal line based on a calculation processing unit that performs a calculation process related to the control of the rendering device and a command from the calculation processing unit. A plurality of signal level control means, wherein the group unit control means is connected to each of the plurality of signal level control means, and the determination means is all group units controlled by the group overall control means. The group initialization is performed by determining whether or not the data transmission is successful with respect to the control means, and determining whether or not there is a signal level control means in which data transmission has failed in all connected group unit control means. The means determines whether there is a signal level control means in which data transmission has failed in all connected group unit control means. If all the group unit control means connected to the signal level control means are instructed to initialize at the same time, the signal level control means is also initialized (1). The gaming machine according to any one of (4) to (4).

  According to the invention described in (1), when data is transmitted from the group control unit to the group unit control unit, a response signal is transmitted from the group unit control unit to the group control unit, so it is confirmed whether data transmission has been performed. It becomes the structure which can be performed and can prevent a malfunction. At this time, the group overall control means transmits data to the group unit control means via one data line, and a response signal is also sent from the group unit control means to the group overall control means via the same data line. The wiring between the substrates can be reduced. Also, immediately after data is transmitted from the group overall control means to the group unit control means, a response signal is sent from the group unit control means to the group overall control means, so that high-speed data communication is possible.

  Further, the effect control information transmitting means is configured to individually select a plurality of group unit control means and transmit the effect control information, so that different effect control information can be set for each group unit control means. . On the other hand, the group initialization unit is configured to select a plurality of group unit control units at the same time to instruct initialization, so that there is a problem in data transmission / reception between the group overall control unit and the group unit control unit. Even if it occurs, a plurality of group unit control means can be returned at high speed.

  According to the invention described in (2), the initialization instruction data to be initialized and the effect control information are both transmitted to the group unit control means via the same data line, so that the data line is effectively utilized. be able to.

  According to the invention described in (3), each group unit control means accepts data from the group overall control means via the data line, and the accepted data corresponds to a common address or individual address assigned to itself. Therefore, both the initialization instruction data and the effect control information can be reliably acquired from the data line.

  According to the invention described in (4), regardless of whether the gaming machine is provided with either the first or second specification-dependent group unit control means, the production control information from the group overall control means is made common. Therefore, it is not necessary to replace the production control means according to the specifications of the gaming machine, and the manufacturing cost can be reduced.

  According to the invention described in (5), when data transmission fails for all the group unit control means controlled by the group overall control means, the initialization is instructed to all the group unit control means. If at least one group unit control means operates normally, the initialization is not performed. Therefore, even if not all the group unit control means are connected to the group overall control means, the operation can be continued without being initialized. Therefore, when the group unit control means is connected to the group overall control means as a single unit and inspected. In addition, unnecessary initialization operations are not performed.

  According to the invention described in (6), when the transmission of data to all the group unit control means connected to the signal level control means fails, the signal level control means itself may be abnormal. Since it is assumed, control can be made more reliably by initializing the signal level control means.

  According to the invention described in (7), when data transmission fails to all the group unit control means connected to the specific signal level control means, an abnormality occurs in the corresponding signal level control means itself. Therefore, it is possible to control more reliably by initializing the signal level control means. At this time, since the minimum necessary initialization is performed without initializing other signal level control means, it is possible to suppress the player from feeling uncomfortable.

  As described above, the present invention can be applied to a gaming machine in which an effect control device controls a decoration control device.

1 gaming machine 2 body frame (outer frame)
3 Front frame 4 Hinge 10 Game board 11 Illumination unit 17 Production button 18 Glass frame 34 Regular start gate 36 Regular variation prize device 42 Special variation prize device 44 General prize opening 45 First start prize opening 51 Center case 52 Window 53 Display Device 55 Vibration sensor 60 Movable accessory 500 Game control device 550 Production control device 560 Actor drive SOL
561 Actor Drive MOT
570 Master IC
580 Dispensing control device 600 Relay board (decoration control device)
610 decoration device 620 decoration device 2100 abnormality determination table

Claims (2)

In a gaming machine comprising a plurality of effect devices for generating effects related to a game while generating a special game state corresponding to the result of an auxiliary game executed in the game area,
Dividing the plurality of effect devices into a plurality of groups, and providing group unit control means for controlling the effect devices belonging to the divided groups for each group,
Group overall control means for overall control of the plurality of group unit control means;
A timing signal line for transmitting a timing signal from the group overall control means to the group unit control means;
A data line for transmitting data between the group overall control means and the group unit control means,
The group overall control means is:
Transmitting means for sequentially transmitting data to the group unit control means by repeatedly changing the signal level of the timing signal line while setting the signal level of the data line to a signal level corresponding to transmission data;
A group initializing means for simultaneously selecting a plurality of group unit control means and instructing the initialization of each group unit control means by the transmission means;
Production control information transmitting means for individually selecting each group unit control means and transmitting production control information for specifying an output mode of the production device by the transmission means;
A gaming machine characterized by comprising: The group initialization means instructs initialization to the group unit control means of the transmission destination by transmitting initialization instruction data to the group unit control means,
2. The gaming machine according to claim 1, wherein the initialization instruction data and the effect control information are transmitted to the plurality of group unit control means via the data line by the transmission means.

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