JP2004202070A - Game table - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game table by which a limited storage capacity can efficiently be utilized by a simply realizing continuous performance by coordination operation of two control function parts provided at the game table. <P>SOLUTION: A sub control part A having received a command from a main control part acquires performance data according to a performance command from a performance order data table and acquires control data according to each performance data from a control data table. When the control data includes a sub control command, the command is transmitted to a sub control part B. The sub control part B acquires control data according to the sub control command from performance sequence/control data tables 1 and 2 in the order of performance to control a device for performance. When the control data includes an answer command, the command is transmitted to the sub control part A. The sub control part A acquires performance data according to the answer command from an answer command conversion table and converts it to control data for controlling the device for performance. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a gaming table represented by a slot machine.
[0002]
[Prior art]
A game console provided with two control means capable of two-way communication is known.
[0003]
[Patent Document 1]
JP-A-2002-263329
[0004]
In FIG. 17 of the above document, the sound control means and the lamp control means are connected to each other. For example, when the lamp control means fails to normally receive a command, reception error information is output to the sound control means and again. , A command is output to the lamp control means.
[0005]
[Problems to be solved by the invention]
However, the communication between the control means is performed by the conventional technology as described above, and, for example, when it is desired to output a specific sound after flashing a lamp for a predetermined time as a game effect, the following complicated processing is required. Must be performed.
[0006]
That is, after blinking the lamp for a predetermined time, as a sequence for performing a game effect of outputting a specific sound, first, a blinking instruction of the lamp is output from the symbol control means to the lamp control means and the sound control means, After the flashing process is completed, sound is output by the sound control unit.At this time, the sound control unit or the symbol control unit performs time measurement triggered by the timing of the flashing instruction, and after a predetermined time has elapsed. Accordingly, it is determined that the lamp blinking processing on the lamp control means side has been completed, and thereafter, processing such as performing sound output is required. In such a configuration, it is necessary to proceed with the design work while verifying each time so that the time required for the first effect and the start timing of the next effect can be completely synchronized. This would require enormous work time. In addition, not only the lamp control means, but also the sound control means and the symbol control means must store the effect time such as the blinking time of the lamp in advance, which wastes storage capacity.
[0007]
Therefore, an object of the present invention is to provide a game console that can easily realize a continuous effect by cooperative operation between two control function units provided in the game console and can efficiently use a limited storage capacity.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 includes a first control unit and a second control unit capable of performing bidirectional communication, and one or more first control units controlled by the first control unit. A game console including at least a control object and one or more second control objects controlled by the second control unit, wherein the second control unit transmits the control object from the first control unit. Operation processing means for operating the second control object based on the control signal to be transmitted; and transmission processing means for transmitting an answer signal to the first control unit based on the progress of the operation of the second control object. Wherein the first control unit includes: a transmission processing unit that transmits a control signal to the second control unit; and the first control object based on the answer signal transmitted from the second control unit. And operation processing means for operating. .
[0009]
According to a second aspect of the present invention, in the gaming table according to the first aspect, the transmission processing means of the second control unit is configured to execute a predetermined series of operations of the second control object in connection with an end. The answer signal is transmitted to the first control unit based on the determined transmission timing.
[0010]
According to a third aspect of the present invention, in the gaming table according to the first or second aspect, the transmission processing means of the first control unit is configured to perform a process based on an answer signal received from the second control unit. Further, it has a function of transmitting a new control signal to the second control unit.
[0011]
According to a fourth aspect of the present invention, in the gaming table according to any one of the first to third aspects, the transmission processing unit of the second control unit transmits a control signal from the first control unit. Based on the received signal, an acknowledgment signal corresponding to the control signal is transmitted to the first control unit, and then the answer signal is transmitted. If the answer signal is received after receiving the acknowledgment signal from the control unit, the first control object is operated based on the answer signal, and the acknowledgment signal from the second control unit is received. If the answer signal is received in a state where the answer is absent, the operation of the first control target based on the answer signal is canceled.
[0012]
Further, according to a fifth aspect of the present invention, in the gaming table according to any one of the first to fourth aspects, the first control unit includes an answer signal to be received for each predetermined game mode. A conversion table in which the contents of the operation of the first control object are associated with each other. When an answer signal is received from the second control unit, the received answer signal is referred to by referring to the conversion table. The content of the operation of the first control object corresponding to the signal is specified, and based on this, the operation processing means operates the first control object.
[0013]
According to a sixth aspect of the present invention, in the gaming machine according to any one of the first to fifth aspects, the gaming machine comprises: a plurality of reels on which a plurality of types of patterns are provided; A start switch for starting rotation of the reels, a stop switch provided for each of the reels, for individually stopping the rotation of the reels, and a predetermined winning combination of internal winning of a winning combination are determined by lottery. In the case where it is determined that the winning combination is internally won, and the combination of the patterns displayed by the reels at the time of stop is a combination of the patterns predetermined corresponding to the internally won winning combination, A main control unit that determines that the winning combination has been won, wherein the first control unit specifies information relating to each operation of the first control target object with respect to a signal sent from the main control unit. The first The first table defines at least data indicating the control signal to be transmitted to the second control unit, and the second control unit transmits the received control signal and the second control object A second table defining information relating to each operation of the object, wherein the second table stores at least data indicating the answer signal, and wherein the first control unit transmits the data from the main control unit to When the signal is transmitted, the first control object is operated with reference to the first table, and the control signal stored in the first table is transmitted to the second control unit. The second control unit having received the control signal refers to the second table, operates the second control target, and transmits an answer signal stored in the second table to the first control unit. To do Characterized in that it was.
[0014]
According to a seventh aspect of the present invention, in the gaming machine according to any one of the first to fifth aspects, the gaming machine comprises: a plurality of reels on which a plurality of types of patterns are provided; A start switch for starting rotation of the reels, a stop switch provided for each of the reels, for individually stopping the rotation of the reels, and a predetermined winning combination of internal winning of a winning combination are determined by lottery. In the case where it is determined that the winning combination is internally won, and the combination of the patterns displayed by the reels at the time of stop is a combination of the patterns predetermined corresponding to the internally won winning combination, A main control unit that determines that the winning combination has been won, wherein the first control unit is configured to execute the first control object and the operation content of the first control object with respect to a signal sent from the main control unit. Target And a control data table defining details of each operation content of the order table, and the control data table should be transmitted to at least the second control unit. The data indicating the control signal is defined, and the second control unit defines the received control signal, the operation sequence of the second control object, and the details of the operation of each of the second control objects. The order and control data table, the order and control data table stores at least data indicating the answer signal, the first control unit, when the signal is sent from the main control unit Operates the first control object with reference to the order table and the control data table, and transmits a control signal stored in the control data table. The second control unit, which has transmitted to the second control unit and received the control signal, refers to the order / control data table, operates the second control object, and stores the control / control data in the control data table. The answer signal is transmitted to the first control unit.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the present embodiment, a slot machine, which is a specific example of a game console, will be described as an example, but the present invention is also applicable to other game consoles such as, for example, pachinko machines.
[0016]
FIG. 1 is a front view of a slot machine 100 according to the embodiment of the present invention. As shown in FIG. 1, three reels (a left reel 110, a middle reel 111, and a right reel 112) each having a plurality of types of patterns arranged on an outer peripheral surface are housed in the center of the main body 101 of the slot machine 100. The slot machine 100 is configured to be rotatable inside. In the present embodiment, each picture is printed on the belt-shaped member at an equal interval in an appropriate number (for example, 21 pictures), and is attached to each of the reels 110 to 112.
[0017]
When viewed from the player, three symbols on each of the reels 110 to 112 are displayed in the vertical direction from the symbol display window 113, so that a total of nine symbols can be seen. By rotating each of the reels 110 to 112, the combination of pictures seen by the player changes. In this embodiment, three reels are provided in the center of the slot machine 100. However, the number of reels and the installation positions of the reels are not limited to these.
[0018]
On the back of each of the reels 110 to 112, a backlight (not shown) for illuminating each picture displayed on the picture display window 113 is arranged. It is desirable that the backlight be shielded for each picture so that each picture can be irradiated evenly.
[0019]
An optical sensor including a light projecting unit and a light receiving unit is provided in the vicinity of each of the reels 110 to 112 inside the slot machine. A reel is connected between the light projecting unit and the light receiving unit of the optical sensor. Are arranged so that the light-shielding pieces of a certain length provided in the light-receiving portion pass therethrough. Based on the detection result of the optical sensor, the position of the pattern on the reel in the rotation direction is determined, and control is performed to stop the reels 110 to 112 so that the target pattern is displayed on the pay line 114.
[0020]
The winning line display lamp 120 is a lamp that indicates a winning line that is valid for each game. The activated pay line is determined in advance by the number of game media (medals are assumed in the present embodiment) inserted into the slot machine 100. For example, when one medal is inserted, the horizontal winning line in the middle row is valid, and when two medals are inserted, three additional horizontal winning lines and the lower horizontal winning line are valid, and the medal is When three cards are inserted, five lines in which the rightward payline and the rightward payline are added become effective as paylines. The number of winning lines is not limited to five.
[0021]
The start lamp 121 is a lamp that informs a player that the reels 110 to 112 are in a rotatable state. The re-game lamp 122 is a lamp for notifying a player that the current game is re-gameable (medal does not need to be inserted) when a re-game which is one of the winning combinations in the previous game is won. . The notification lamp 123 is a lamp that notifies a player that a specific winning combination (specifically, a big bonus or a regular bonus described later) has been internally won in an internal lottery described later. The medal insertion lamp 124 is a lamp that indicates that a player can insert medals from the medal insertion slot 134. The reel panel lamp 128 is an effect lamp for notifying a player of internal information of the slot machine 100. The medal insertion buttons 130 and 131 are buttons for inserting a predetermined number of medals that are electronically stored in a control unit (to be described later) of the slot machine 100.
[0022]
The payout number display 125 is a display for displaying the number of medals to be paid out to the player as a result of winning some winning combination. The number-of-games indicator 126 is a display for displaying the number of games in the BB game described later, the number of winnings of a predetermined winning combination, and the like. The stored number display 127 is a display for displaying the number of medals electronically stored in a control unit of the slot machine 100 described later.
[0023]
In the present embodiment, each time the medal insertion button 131 is pressed, one medal insertion button 131 is pressed, and a maximum of three cards are inserted. When the medal insertion button 130 is pressed, three coins are inserted. The medal insertion slot 134 is an insertion slot for a player to insert a medal when starting a game. That is, the medal can be inserted electronically by the medal insertion buttons 130 and 131, or an actual medal can be inserted from the medal insertion slot 134.
[0024]
The start lever 135 is a lever for starting rotation of the reels 110 to 112. That is, when the desired number of medals is inserted into the medal insertion slot 134 and the start lever 135 is operated, the reels 101 to 112 start rotating.
[0025]
The stop button unit 136 is provided with stop buttons 137 to 139. The stop buttons 137 to 139 are buttons for individually stopping the reels 110 to 112 that have started rotating by operating the start lever 135. Note that a light-emitting body may be provided inside each of the stop buttons 137 to 139. When the stop buttons 137 to 139 can be operated, the light-emitting body can be turned on to notify the player.
[0026]
A storage / payment button 132 is used to settle a medal electronically stored in a control unit (to be described later) of the slot machine 100, to pay the medal to the medal receiving slot 157 from the medal payout port 156, and to insert the medal into the medal slot 134. It is a button for switching between the stored four or more medals and a storage function for electronically storing up to 50 medals obtained by winning.
[0027]
The door key 140 is a key hole for unlocking the front door 102 of the slot machine 100. The medal payout port 156 is a payout port for paying out medals paid out by winning. The medal tray 157 is a container for storing medals paid out from the medal payout exit 156. The title panel 158 is a panel that displays the model name of the slot machine 100.
[0028]
The sound holes 160 and 161 are holes for outputting the sound of a speaker provided inside the slot machine 100 to the outside.
[0029]
The upper lamp 150, the side lamp 151, the center lamp 152, the waist lamp 153, and the lower lamp 154 are decorative lamps for exciting games.
[0030]
The effect reel 170 and the dot matrix type display device 180 are displays for displaying internal information of the slot machine 100 and the like.
[0031]
The dot matrix type display device 180 has a plurality of light emitting elements arranged in a matrix and is driven by a dynamic lighting method. In this embodiment, a light emitting diode (LED) is used as a light emitting element, but another light emitting element may be used.
[0032]
The effect reel 170 is a special effect reel different from the main reels (reels 110, 111, 112). In the present embodiment, the same number of effect reels as the main reels are provided. However, the number of effect reels may be more or less than this. Various patterns can be drawn on the production reel. In the present embodiment, patterns (“7”, “6”,...) Representing numbers are drawn. In addition, similarly to the main reel described above, each effect reel is provided with an optical sensor including a light emitting unit and a light receiving unit, and the reel is provided with an optical sensor between the light emitting unit and the light receiving unit. The light-shielding piece having a predetermined length passes through the light-shielding piece. The position of the picture on the reel in the rotation direction is determined based on the detection result of this sensor, and the reel can be stopped so that the desired picture is displayed on the front.
[0033]
Next, the circuit configuration of the control unit of the slot machine 100 will be described in detail with reference to FIGS. The slot machine 100 includes a main control unit 300 that controls a central part of the game, a sub-control unit A400 that controls various effect devices according to a command transmitted from the main control unit 300, and a command of the sub-control unit A400. , And a sub-control unit B500 for controlling the effect reel 170.
[0034]
(Configuration of main control unit)
First, the main controller 300 of the slot machine 100 will be described with reference to FIG. The main control unit 300 includes a CPU 310 as an arithmetic processing unit for controlling the entire main control unit 300, and a data bus and an address bus for the CPU 310 to transmit and receive signals to and from each IC. It has the configuration described.
[0035]
The clock circuit 314 is a circuit that divides the frequency of the clock oscillated from the crystal oscillator 311 and supplies the clock to the CPU 310. For example, when the frequency of the crystal oscillator 311 is 12 MHz, the frequency-divided clock is 6 MHz. The CPU 310 operates by receiving the clock divided by the clock circuit 314 as a system clock.
[0036]
Further, the CPU 310 is connected via a bus to a timer circuit 315 for setting a monitoring cycle for constantly monitoring the state of sensors and switches, which will be described later, and a transmission cycle of a motor drive pulse. When the power is turned on, the CPU 310 transmits frequency division data stored in a predetermined area of the ROM 312 to the timer circuit 315 via the data bus. The timer circuit 315 determines an interrupt time based on the received data for frequency division, and transmits an interrupt request to the CPU 310 for each interrupt time. The CPU 310 executes monitoring of each sensor and the like and transmission of a driving pulse, triggered by the interrupt request. For example, when the system clock of the CPU 310 is set to 6 MHz, the frequency division value of the timer circuit 315 is set to 1/256, and the data for frequency division stored in the ROM 312 is set to 44, the reference time of this interrupt is 256 × 44 ÷ 6 MHz = 1.877 ms.
[0037]
The CPU 310 has a ROM 312 for storing programs for controlling the respective control function units, lottery data used for internal lottery of winning combinations, reel stop positions, and a RAM 313 for storing temporary data. Is connected.
[0038]
Further, an input interface 360 for receiving an external signal is connected to the CPU 310, and the medal acceptance sensor 320, the start lever sensor 321, the stop button sensor 322, and the medal insertion button are provided via the input interface 360 every interruption time. The state of the sensor 323 and the settlement / storage switch 324 is detected, and each sensor is monitored.
[0039]
Two medal reception sensors 320 are provided in a passage inside the medal insertion slot 134, and detect whether or not a medal has passed. The start lever sensor 321 is provided on the start lever 135 and detects a start operation by the player. The stop button sensor 322 is provided for each of the stop buttons 137 to 139, and detects an operation of the stop button by the player.
[0040]
The medal insertion button sensor 323 is installed on each of the medal insertion buttons 130 and 131, and detects an insertion operation when inserting a medal electronically stored in the RAM 313 as a game medal. For example, when the medal insertion sensor 323 corresponding to the medal insertion button 131 becomes H level, the CPU 310 electronically inserts one stored medal and the medal insertion sensor 323 corresponding to the medal insertion button 130 becomes H level. , Three stored medals are inserted electronically. When the medal insertion button 130 is pressed, if the number of stored medals is less than three, that is, two in the case of two and one in the case of one.
[0041]
The settlement / storage switch 324 is provided on the settlement / storage button 132. When the settlement / storage switch 132 is pressed once, the stored medals are settled, and when pressed once again, a medal to be paid out is stored electronically.
[0042]
Note that each of the above-described medal reception sensor 320, start lever sensor 321, stop button sensor 322, medal insertion button sensor 323, and settlement / storage switch 324 is a non-contact sensor or a contact sensor. You may.
[0043]
The CPU 310 further has an input interface 361, an output interface 370, and an output interface 371 connected to an address bus via an address decode circuit 350. The CPU 310 transmits and receives signals to and from external devices via these interfaces.
[0044]
The index sensor 325 is connected to the input interface 361. The index sensor 325 is specifically installed at a predetermined position of the reel mounting frame, and goes to the H level every time the light shielding piece provided on the reel member passes through the index sensor 325. When a position where the light shielding piece of the reel member is detected by the index sensor 325 is set as a reference position, and the CPU 310 detects a detection signal (H level) from the index sensor 325, the CPU 310 determines that the reel has made one rotation, and Reset the rotational position to zero.
[0045]
The output interface 370 includes a reel motor driving unit 330 for driving a reel and a hopper motor driving unit for driving a motor of a hopper (a device for paying medals accumulated in a bucket from a medal payout port 156). 331, a game lamp 340 (specifically, a winning line display lamp 120, a start lamp 121, a re-game lamp 122, a notification lamp 123, a medal insertion lamp 127, and the like), and a 7-segment display 341 (payout number display 125). , The number-of-games display 126, the stored number display 127, etc.) are connected.
[0046]
Further, a random number generation circuit 317 is connected to the CPU 310 via a data bus. The random number generation circuit 317 is an increment counter capable of incrementing a clock oscillated from the crystal oscillator 311 and the crystal oscillator 316 until a predetermined value is reached, and outputting the count value to the CPU 310. Used for various lottery processes including internal lottery. Note that the random number generation circuit 317 in the present embodiment uses, as two random number counters, for example, a counter that increments a value from 0 to 65535 using the clock frequency of the crystal oscillator 311 and a clock frequency of the crystal oscillator 317. And a counter for incrementing the value from 0 to 16777215.
[0047]
An output interface 371 for transmitting a command to the sub control unit A400 is connected to the data bus of the CPU 310.
[0048]
(Configuration of sub-control unit A)
Next, the sub control unit A400 of the slot machine 100 will be described with reference to FIG. The sub-control unit A400 is an arithmetic processing unit that controls the entire sub-control unit A400 based on the command transmitted from the main control unit 300 and the command transmitted from the sub-control unit B500. It has a data bus and an address bus for transmitting and receiving signals to and from the control function unit, and has the following configuration.
[0049]
The clock correction circuit 414 is a circuit that corrects a clock oscillated from the crystal oscillator 411 and supplies the corrected clock to the CPU 410 as a system clock.
[0050]
Further, a timer circuit 415 for setting a monitoring cycle for constantly monitoring switches and the like described later is connected to the CPU 410 via a bus. The setting of the interrupt time of the timer circuit 415 and the like are the same as those of the main control unit 300, and thus a specific description thereof is omitted.
[0051]
Further, the CPU 410 temporarily stores a command and data for controlling the entire sub-control unit A400, a ROM 412 storing data for controlling a backlight lighting pattern and various displays, and data to be transmitted and received. Is connected via each bus.
[0052]
The CPU 410 is connected to an input / output interface 460 for transmitting and receiving external signals. The input / output interface 460 includes a backlight 420 for illuminating the picture of each of the reels 110 to 112 from the back, and a front and a back. A door sensor 421 for detecting opening and closing of the door 101 and a reset switch 422 for clearing data in the RAM 413 are connected.
[0053]
An input interface 461 for receiving a command from the main control unit 300 via a data bus is connected to the CPU 410. Based on the command received via the input interface 461, an effect process for enlivening the entire game is performed. Be executed.
[0054]
The sound source IC 480 is connected to the data bus and the address bus of the CPU 410. The sound source IC 480 controls sound according to a command from the CPU 410. A ROM 481 storing audio data is connected to the sound source IC 480, and the audio data IC 480 amplifies the audio data obtained from the ROM 481 by the amplifier 482 and outputs the amplified audio data from the speaker 483. The speaker 483 is an example of a first control object controlled by the sub control unit A400, which is a first control unit. The first control object may be a backlight, an upper lamp, or the like.
[0055]
An address decode circuit 450 for selecting an external IC is connected to the CPU 410, similarly to the main control unit 300. The address decode circuit 450 has an input interface for receiving a command from the main control unit 300. 461, output interfaces 470 and 472 for transmitting signals to each display, an input interface 471 for inputting a signal from the sub control unit B500, a clock IC 490, and a signal for outputting a signal to the 7-segment display 440. The output interface 472 is connected. The connection of the clock IC 490 allows the CPU 410 to acquire the current time. The seven-segment display 440 is provided on the substrate of the sub-control unit A400, and the information set in the sub-control unit A400 can be displayed to a person in the hall.
[0056]
Further, a demultiplexer 419 is connected to the output interface 470. The demultiplexer 419 analyzes the signal transmitted from the output interface 470 and transmits the signal to each display unit or the like. That is, the demultiplexer 419 determines the upper lamp 150, the side lamp 151, the center lamp 152, the waist lamp 153, the lower lamp 154, the reel panel lamp 128, the title panel lamp 491, the saucer lamp 492, and the like according to the data received from the CPU 410. The payout strobe 493 is controlled. The title panel lamp 491 is a lamp for illuminating the title panel 158.
[0057]
Note that the CPU 410 executes command transmission to the sub-control unit B500 via the output interface 470 and the demultiplexer 419. Conversely, CPU 410 receives a command from sub-control unit B500 via input interface 471. That is, the CPU 410 performs bidirectional communication with the sub control unit B500 via the output interface 470, the demultiplexer 419, and the input interface 471.
[0058]
(Configuration of Sub-Control Unit B)
Next, the sub control unit B500 of the slot machine 100 will be described with reference to FIG. The sub control unit B500 controls the dot matrix type display device 180 and the effect reel 170 based on the command transmitted from the sub control unit A400. That is, the dot matrix type display device 180 and the effect reel 170 are examples of the second control object controlled by the sub control unit B500 as the second control means. Further, the second control object may be a liquid crystal display device or a dynamic display device (a display device having a movable body such as a moving doll).
[0059]
The sub-control unit B500 has the following configuration in addition to the data bus and address bus for transmitting and receiving signals to and from the CPU 510, which is an arithmetic processing unit, and each control function unit.
[0060]
The clock correction circuit 514 is a circuit that corrects a clock oscillated from the crystal oscillator 511 and supplies the corrected clock to the CPU 510 as a system clock.
[0061]
The CPU 510 includes a timer circuit 515 for setting the time for scanning the signal lines of the dot matrix type display device 180 (specifically, the row driving unit 181 and the column driving unit 182 of the matrix light emitting diode 183). It is connected to the. The scanning time of the matrix light emitting diode 183 is, as in the main control unit 300, when the CPU 510 is powered on, the CPU 510 sends the data stored in a predetermined area of a ROM 512 described later to the timer circuit 515 via a data bus. Determined by sending. That is, the timer circuit 515 sets a reference time from the received data, and notifies the CPU 510 of the elapse of the reference time. Then, the CPU 510 receives the signal and transmits a signal to the dot matrix display device 180.
[0062]
The CPU 510 includes an input interface 520 for receiving a command transmitted from the sub-control unit A400, and an output interface 521 for transmitting an answer signal (hereinafter, “answer command”) to the sub-control unit A400. Connected through.
[0063]
The CPU 510 includes a ROM 512 storing a program for controlling transmission and reception of data and signals for displaying predetermined figures and characters by the matrix light emitting diode 183, and a row driving unit 181 and a column driving unit 182. A RAM 513 as a work area for temporarily storing data for control and a RAM 516 for temporarily storing data to be transmitted / received are connected via respective buses.
[0064]
Further, the CPU 510 sends a signal to the serial interface 530 for transmitting a serial signal to the column driving unit 182 of the matrix light emitting diode 183 and a signal to the row driving unit 181 of the dot matrix display device 180 via the address decoder 184. An output interface 531 for transmission is connected via each bus. Then, the CPU 510 analyzes the command received from the sub control unit A400, obtains data to be displayed on the matrix light emitting diode 183 (for example, dot data of a yacht traveling in the sea) from the ROM 512, and sets the data in the timer circuit 515. The row driving unit 181 and the column driving unit 182 are controlled for each reference time, and a predetermined figure or character is displayed by turning on / off each of the light emitting diodes constituting the matrix light emitting diode 183.
[0065]
The CPU 510 is connected to an input / output interface 532 for transmitting and receiving to and from the effect reel 170 via each bus.
[0066]
Next, a circuit configuration of a portion related to communication between the sub control unit A400 as the first control unit and the sub control unit B500 as the second control unit will be described in detail with reference to FIG.
[0067]
In FIG. 5, when writing of data to a specific address space is designated during execution of a program by the CPU 410 of the sub control unit A400, the latch ICs 10a and 10b are selected by the CS2 signal, and the write signal (WR signal) ) Is output. As a result, data on the data bus (data on the data bus signal lines 0 to 7) is latched by the latch IC 10a, and addresses on the address bus (address bus signal lines 4 to 6) are latched by the latch IC 10b.
[0068]
The latched data is output from the latch IC 10a via an LPF (low-pass filter) 40a and a buffer IC 20b, and the latched address is output from the latch IC 10b to the demultiplexer 30 via the LPF 40b.
[0069]
Thereafter, a local data strobe signal is output from the CPU 410, and is input to the demultiplexer 30 (419 in FIG. 3) via the buffer IC 20a and the LPF 40c. Upon receiving the local data strobe signal, the demultiplexer 30 outputs a signal to a latch IC (latch ICs 10c, 10d, 10e, etc.) designated by the previously input address. The data on the bus is latched. The latched data is output to a target IC, and blinking of a lamp and sound output are realized.
[0070]
When the latch IC 10e is selected by the address specified as the output destination of the demultiplexer 30, the data output from the latch IC 10e is sent to the CPU 510 via the LPF 40d and the buffer IC 20c as 8-bit data of the sub-control command. Is entered.
[0071]
Thereafter, when a local data strobe signal (a signal of negative logic in this example) is further output, the local data strobe signal passes through the buffer IC 20a, the LPF 40c, and the demultiplexer 30 and then to the inverter 50, as in the previous case. , And is input to the CPU 510 via the LPF 40f and the buffer IC 20d. Upon receiving the local data strobe signal, the CPU 510 obtains 3-bit data of the sub-control command via the buffer IC 20a, the LPF 40e, and the buffer IC 20d.
[0072]
On the other hand, the answer command output from CPU 510 is output to buffer IC 20e, LPF 40g, and bus buffer IC 20f.
[0073]
Thereafter, when an answer request signal is output from the CPU 510, the answer request signal is input to the CPU 410 via the buffer IC 20e, the LPF 40h, and the buffer IC 20g, and the CPU 410 receiving the answer request signal acquires an answer command via the data bus.
[0074]
(Outline of the game)
FIG. 6 is a flowchart showing basic control (main control unit main processing) of a game in the slot machine 100 of the embodiment. The basic control of the game is performed mainly by the CPU 310, and a series of processing is repeatedly executed unless a power-off or the like is detected.
[0075]
In step 101 (S101), processing related to medal insertion is performed. Here, it is checked whether or not medals have been inserted, and the winning line display lamp 120 is turned on according to the number of inserted medals. It should be noted that if a re-game is won in the previous game, it is not necessary to insert a medal.
[0076]
In S102, a process related to a game start operation is performed. Here, it is checked whether or not the start lever 135 has been operated, and when it is determined that the start operation has been performed, the number of inserted medals is determined.
[0077]
In S103, an effective pay line 114 is determined according to the number of inserted cards determined in S103.
[0078]
In S104, the random number generated by the random number generator 317 is obtained.
[0079]
In S105, a winning combination lottery is performed using the random number value acquired in S104 and the winning combination lottery table stored in the ROM 312.
[0080]
In addition, although the kind of a winning combination can be employ | adopted arbitrarily, in this embodiment, a regular bonus (RB), a big bonus (BB), a small combination, a replay, etc. exist. In each winning combination, lottery data is set for each set value and each number of inserted coins. The number obtained by dividing the lottery data by a predetermined value (specifically, 16384, which is the entire range of random number values used in the winning combination lottery) is the winning probability. In other words, the range of the random number value acquired at the time of the winning combination lottery is divided in advance into several regions (regions corresponding to the size of each lottery data), and each region is associated with the winning or loss of each winning combination. Have been. These pieces of information are stored in the ROM 312 as a winning combination lottery table. In the winning combination lottery, the winning combination is determined according to the range to which the acquired random number belongs. The same applies to each lottery data described later.
[0081]
In the present embodiment, the types of games include RB games and BB games as bonus games. In the RB game, either a predetermined number of times (12 times in the present embodiment) of playing a role game or a predetermined number of times (8 times in the embodiment) of the role is won. This is a game in which establishment is a termination condition. Although there are a plurality of types of BB game contents, in the present embodiment, an SRB can be won during the BB game, and when the player wins the SRB, the SRB game is started. In the case of the present embodiment, either a condition that the BB general game is performed a predetermined number of times (30 times in the present embodiment) or a condition that the SRB game is performed a predetermined number of times (3 times in the present embodiment) Is satisfied, the BB game ends. When the SRB game ends, the game returns to the BB general game, or the BB game ends (when the SRB is won at the 30th BB general game and the SRB is started).
[0082]
In S106, a reel stop control table is selected. A plurality of reel stop control tables are prepared for each winning combination, and are selected by lottery. These reel stop control tables are stored in the ROM 312 in advance.
[0083]
In S107, one of a plurality of effect commands prepared in advance is selected, and the selected effect command is transmitted to the sub-control unit 400.
[0084]
In S108, the rotation of all the reels 110 to 112 is started.
[0085]
At S109, the stop buttons 137 to 139 can be received. When any one of the stop buttons is pressed, the reel corresponding to the pressed stop button is stopped based on the reel stop control table selected at S106. .
[0086]
In S110, a winning determination is made. Here, when the symbol combination corresponding to the winning combination is displayed on the activated winning line 114, it is determined that the winning combination has been won. For example, if "bell-bell-bell" is aligned on the activated winning line 114, it is determined that a bell has been won. If “7-7-7” is completed, it is determined that a BB prize has been won. The winning result is stored as a winning result code.
[0087]
In S111, if any winning combination with payout is won, the number of medals corresponding to the winning combination is paid out.
[0088]
In S112, a game state control process is executed. In this game state control processing, control for shifting the game type is performed. For example, in the case of a BB winning, preparation is made so that the BB game can be started from the next time, and in the final game of the BB game, the normal game is started from the next time. Prepare to start the game.
[0089]
Thus, one game is completed, and thereafter, the game is advanced by repeating this.
[0090]
The commands transmitted from the main control unit 300 to the sub control unit 400 include the following various commands in addition to the above-described effect commands. Steps in parentheses indicate transmission timing.
[0091]
That is, a start lever operation command (command S102 indicating reception of a start lever) and a first stop operation command (information indicating a reel on which the first stop operation was performed) are stored, and are transmitted when the first stop operation is performed. Command to be executed: S109), a first reel stop command (a command that stores information indicating a reel stopped by performing the first stop operation and transmitted when the first reel is stopped: S109), and a similar second There are a stop operation command, a second reel stop command, a third stop operation command, a third reel stop command, and a winning determination information command (a command storing a winning result: S110). Although not specifically shown, the effect command is transmitted when a predetermined condition is satisfied (for example, at the time of winning a BB), in addition to S107.
[0092]
Next, the control of the sub control unit A400 and the sub control unit B500 will be described in detail. The sub-control unit A400 and the sub-control unit B500 each execute various processes as needed. As described below, the sub-control unit A400 and the sub-control unit B500 can perform cooperative processing while transmitting and receiving commands to and from each other. The flow of the cooperative processing is roughly classified into a first processing (reception of a command sent from the main control unit 300 to transmission of a command to the sub control unit B500) of the sub control unit A400, and a processing of the sub control unit B500 ( Reception of command transmitted from sub-control unit A400 to transmission of command to sub-control unit A400), second processing of sub-control unit A400 (reception of command transmitted from sub-control unit B500 to reception of command from sub-control unit A400) Device driving).
[0093]
First, the first process of the sub-control unit A400 (reception of a command sent from the main control unit 300 to transmission of a command to the sub-control unit B500) will be described.
[0094]
FIG. 7A is a flowchart illustrating a main control command receiving process in the sub control unit A400 of the slot machine 100 according to the present embodiment. This main control command receiving process is repeatedly executed by the CPU 410 of the sub-control unit A400 unless a power-off or the like is detected.
[0095]
In S201, it is determined whether or not a command (hereinafter, referred to as a main control command) from the main control unit 300 has been received. If the main control command is stored, the process proceeds to S202; otherwise, the process proceeds to S203. Proceed to.
[0096]
In S202, the main control command received in S201 is temporarily stored in the RAM 413. A common area accessible in both the main control command receiving process and the main process shown in FIG. 7B is secured in the RAM 413 in advance, and information is mutually exchanged by reading and writing data in the common area. You can send and receive. The received main control command is stored in this common area.
[0097]
In S203, it is determined whether or not to end this processing (for example, whether or not power-off is detected). If power-off or the like is detected, this processing is ended. Otherwise, the process returns to S201, and so on. Is repeated.
[0098]
FIG. 7B is a flowchart showing main processing of effect control in the slot machine 100 of the present embodiment. The control relating to the effect is performed mainly by the CPU 410 of the sub-control unit A400, and the processing of FIG.
[0099]
In S301, it is determined whether or not the main control command is stored. If the main control command is stored, the process proceeds to S302; otherwise, the process proceeds to S303.
[0100]
In S302, the contents of the main control command are determined. As described above, since there are a plurality of types of main control commands, such as an effect command, a first stop operation command, and a first reel stop command, the type of the command is determined in this step.
[0101]
In S303, an effect process is executed. The details of the effect processing will be described later.
[0102]
In S304, it is determined whether or not it is necessary to output control data to the device driver based on the result of the rendering process. If it is necessary to output control data to the device driver, the process proceeds to S305; otherwise, the process proceeds to S306.
[0103]
In S305, the control data is output to each device driver determined to have the control data output in S304.
[0104]
The device driver is prepared for each device mounted on the sub-control unit A400. For example, there are a device driver for controlling the output of the BGM, a device driver for controlling the output of the sound effect, and a device driver for controlling the illumination of the backlight. The program of each device driver is stored in the ROM 412 in advance, and is executed by the CPU 410. In the RAM 413, a common area accessible by the main process and each device driver is secured, and information can be mutually exchanged by reading and writing data in the common area. .
[0105]
In S306, it is determined whether or not a control command needs to be transmitted to the sub-control unit B500 based on the result of the rendering process in S303. If it is necessary to transmit a control command (hereinafter, a sub-control command) to the sub-control unit B500, the process proceeds to S307; otherwise, the process proceeds to S308.
[0106]
In S307, a sub control command transmission process is executed. The details of the sub control command transmission processing will be described later.
[0107]
In S308, it is determined whether or not to end the present process (for example, whether or not a power-off has been detected). If a power-off or the like is detected, the present process is ended. Otherwise, the process returns to S301, and so on. Is repeated.
[0108]
FIG. 8A is a flowchart illustrating the rendering process (FIG. 7B: S303) of the sub-control unit A400 described above.
[0109]
In S401, it is determined whether or not an effect needs to be performed. Here, when it is necessary to perform an effect, it is determined whether the direct designation effect or the order designation effect is set. The order designation effect is an effect that is executed according to the effect order determined by the effect command sent from the main control unit 300. The direct designation effect is specified by an answer command sent from the sub-control unit B500, or specified by an effect command sent from the main control unit 300 when a predetermined condition is satisfied (for example, an effect command sent at the time of BB winning). It is a production that is done. If it is not necessary to perform an effect, other processing is executed in S405, and the processing in FIG.
[0110]
In S402, it is determined whether or not the direct designation effect is set. If the direct designation effect has been set, the process proceeds to S403; otherwise, the process proceeds to S404.
[0111]
In S403, effect data based on the effect order is acquired. The effect order represents, for example, an effect order in which effect A is executed when the start lever is operated, effect B is executed during the first stop operation, and effect C is executed during the second stop operation.
[0112]
In S404, the effect data of the designated effect is obtained, and in S403, the effect data determined based on the order of the effects is obtained.
[0113]
After the acquisition of the effect data, as described later, an effect based on the acquired effect data is performed. For example, there is a comparatively long effect (regardless of the order-specified effect or the direct-specified effect). If the next effect data is set during this effect, the effect based on the effect data is immediately performed, and the effect currently being executed is canceled.
[0114]
FIG. 8B is a flowchart showing the sub-control command transmission process (FIG. 7B: S307) of the sub-control unit A400 described above.
[0115]
In S501, a command to be transmitted to the sub control unit B500 (hereinafter, referred to as a sub control command) is set in a transmission queue.
[0116]
In S502, whether the acknowledgment (Ack) from the sub-control unit B500 has not returned within the predetermined time or not (whether or not the Ack waiting timer for measuring the predetermined time for waiting for the acknowledgment has timed out). Judge. This affirmative response is a response from the sub-control unit B500 to the previously transmitted sub-control command. If the acknowledgment has not been returned within the predetermined time, the process proceeds to S504; otherwise, the process proceeds to S503.
[0117]
In S503, the transmission level is incremented (increased by 1). That is, if the current transmission level is “0”, the transmission level is “1”.
[0118]
In S504, the transmission level is reset (the transmission level is set to 1). As described later, when the transmission level is not 0, transmission to the sub control unit B500 is not permitted.
[0119]
In S505, the Ack wait timer is reset, and the waiting time of the acknowledgment returned from the sub control unit B500 for the sub control command set in the transmission queue in S501 is counted.
[0120]
The first process (reception of a command sent from the main control unit 300 to transmission of a command to the sub control unit B500) of the sub control unit A400 has been described above. This will be described in detail with reference to FIG.
[0121]
As shown in FIG. 12, in the sub-control unit A400 including the first table (for example, composed of an order table (production order table) and a control data table), the main control unit 300 sends the main control command when the start lever is operated. When the effect command is received, the effect order specified by the effect command is acquired, and the first effect data defined by the acquired effect order is acquired. An effect order table is stored in the ROM 412 of the sub-control unit A400 in advance. For each block, the start lever operation, the first stop operation, the first reel stop, the second stop operation, the second reel At the time of stoppage, the third reel stop operation, at the time of the third reel stoppage, and at the time of winning determination, the contents of the effect to be executed are stored as effect data. Of course, this is only an example, and items other than the above may be provided.
[0122]
That is, upon receiving the effect command sent when the start lever is operated, the sub-control unit A400 accesses the effect order table in the effect data acquisition process (FIG. 8A: S403), and receives the effect command based on the received effect command. The first effect data (the effect at the time of operating the start lever in FIG. 12) is acquired with reference to the designated block. Thereafter, the main process of FIG. 7B loops several times, and, for example, when the first stop operation command is received, the effect data acquisition process (FIG. 8A: S403) is performed again. The effect data of the first stop operation command included in the previous block is acquired, and after that, the main process of FIG. 7B loops several times, and when the second stop operation command is received, the effect is again performed. In the effect data acquisition process based on the order (FIG. 8A: S403), effect data of the second stop operation command is acquired.
[0123]
As described above, once the production order is specified by the production command, the production data is acquired in accordance with the type of the command from the main control unit 300.
[0124]
Now, after obtaining the effect data, the detailed contents (control data) of the effect are obtained. FIG. 12 shows, as an example, control data at the time of the third stop operation.
[0125]
A control data table is stored in the ROM 412 of the sub-control unit A400 in advance, and for each block, a BGM, a sound effect, a system sound, a backlight, an upper lamp, a side lamp, a reel lighting lamp, a reel panel lamp, A title panel lamp, a saucer lamp, a payout exit strobe, a sub control command 1, a sub control command 2, an effect content, a reserve 1, and a reserve 2 are stored.
[0126]
Here, BGM indicates data that defines music to be played during the game, and sound effects include a sound when a medal is inserted, a sound when a stop button is pressed, and a missile required for an effect. Data indicating explosive sounds and firing sounds are shown, and system sounds are data specifying sounds when a door is opened. The backlight is data defining a blinking pattern of the backlight and the like. Upper lamps, side lamps, etc. (specifically, side lamps, center lamps, waist lamps, lower lamps), reel lighting lamps, reel panel lamps, title panel lamps, saucer lamps, and payout exit strobes are blinking patterns for each lamp. The following shows the data defining. The effect contents generally represent the contents of the game indicated by each data of the block.
[0127]
Then, when the control data is obtained, the control data is output to a necessary device driver (S307 in FIG. 7). The device driver that has received the control data drives the device in charge of itself. For example, the backlight device driver that has received the control data blinks the backlight in a blinking pattern based on the control data.
[0128]
In addition, as shown in FIG. 12, each data of the sub-control commands 1 and 2 is transmitted to the sub-control unit B500. The format of the command (sub-control command) transmitted to the sub-control unit B500 is as shown in FIG. As shown in the figure, the sub-control commands are classified into STX (Start of Text), MTX (Middle of Text), and ETX (Endof Text).
[0129]
The STX stores command distinction (bit10, bit9), parity (bit8), command type (bit7 to bit4), and data length (bit3 to bit0).
[0130]
The command distinction indicates information on the transmission order of the command, and includes 01b (b is binary): STX, 10b: MTX, and 11b: ETX.
[0131]
The parity is a parity for bit 0 to bit 7, and is set at the time of command transmission so that the result of adding the parity bit and each bit of bit 0 to bit 7 (carrying ignoring) becomes, for example, an even number.
[0132]
The command type indicates the type of the command. There are 0 (notation here is decimal): system command, 1: device 1, 2: device 2, 3 to 15: unused. The system command indicates a system command (such as a reset command). The device 1 specifically shows the effect reel 170, and the device 2 shows the dot matrix type display device 180.
[0133]
The data length indicates the length of a command that does not include STX (that is, an MTX or ETX command). Note that one STX and one ETX are added to each command, but the number of MTXs changes according to the length of the command to be transmitted. For example, when it is desired to display the acquired number of medals during a special game (eg, during BB) on the dot matrix display device 180, the number of MTXs may increase in accordance with the acquired number. Therefore, when transmitting a command, it is standard that STX, MTX, and ETX are transmitted continuously (three continuous transmissions). However, when MTX is increased, four continuous transmissions, five continuous transmissions, and so on are performed. There is also.
[0134]
The data is the content of the command itself.
[0135]
Here, as an example with reference to FIG. 12, when transmitting the data of the sub-control command 1, 1h (h: hex) is stored in the STX command type, and 00h is stored in the MTX data portion. , ETX stores 1Eh. Thus, the control data 001Eh recorded in the control data table corresponding to the sub-control command 1 can be transmitted to the sub-control unit B500.
[0136]
Next, the processing of the sub-control unit B500 (reception of a command sent from the sub-control unit A400 to transmission of a command to the sub-control unit A400) will be described.
[0137]
FIG. 9A is a flowchart illustrating a sub-control command receiving process in the slot machine 100 according to the present embodiment. This sub-control command receiving process is repeatedly executed by the CPU 510 unless a power-off or the like is detected.
[0138]
In S601, it is determined whether a command (sub-control command) from the sub-control unit A400 has been received. If a sub-control command has been received, the process advances to step S602; otherwise, the process advances to step S615.
[0139]
In S602, the contents of the sub-control command received in S601 are determined.
[0140]
In S603, it is determined whether or not the received sub-control command is a command indicating an instruction to the device 1 (effect reel). If the received sub-control command is a command indicating an instruction to the device 1, the process proceeds to S604, otherwise. If so, the process proceeds to S608.
[0141]
In S604, control data (data part of the received sub-control command) is output to the device driver 1.
[0142]
It should be noted that the sub-control unit B500 is also equipped with a device driver corresponding to each device (effect reel, dot matrix type display device). The program of each device driver is stored in the ROM 512 in advance. The RAM 516 of the sub-control unit B500 is provided with a common area that can be accessed by both the device driver and the sub-control command reception processing, and data is exchanged by reading and writing data in the common area. You can do it.
[0143]
Then, the device driver that has received the control data drives the device in charge of itself. For example, when control data for rotating the left reel N and stopping at 7 is given to the device driver of the effect reel, the device driver of the effect reel outputs a drive pulse to the motor of the left reel. After that, when it is detected that the left reel has rotated N times based on the detection result of the above-described index sensor 325 for detecting the rotational position, the driving is performed when the next seven patterns appear on the front surface. Stop the pulse.
[0144]
When a command for causing a picture of a yacht to appear is given to the device driver of the dot matrix type display device 180, the picture of the yacht is read from the ROM 512 and ON / OFF of each light emitting diode is controlled. Use to draw a yacht pattern.
[0145]
Each device driver outputs an answer command after its own process is completed. This answer command is received in an answer command transmission process described later. In addition, when each device driver is driving its own device (that is, performing an effect) and receives new control data, it immediately performs an effect based on the control data, and the effect performed at that time is Cancel.
[0146]
In S605, it is determined whether there is an answer command of the device driver 1 to be transmitted. If an answer command of the device driver 1 to be transmitted exists, in S606, it is discarded, and the device driver 1 to be transmitted is discarded. If there is no answer command, the process proceeds to S607. As will be described later, the answer command sent from the device driver is sequentially transmitted to the sub-control unit A400, but the processing is delayed for some reason, and the answer command is delayed before the answer command is actually set in the answer queue. If so, discard this answer command.
[0147]
In S607, Ack of the device driver 1 is set in the answer queue. The Ack set in the answer queue in this way is transmitted to the sub control unit A400.
[0148]
In S615, it is determined whether or not to end the present process (for example, whether or not power-off is detected). If power-off or the like is detected, the present process is ended. Otherwise, the process returns to S601.
[0149]
In S608, it is determined whether or not the sub-control command determined in S603 to be not a command indicating an instruction to the device 1 is a command indicating an instruction to the device 2 (dot matrix display device). If the command is a command 2 indicating an instruction to the sub-control command, the control data of the sub-control command is output to the device driver 2 in S609, otherwise the process proceeds to S613.
[0150]
In S610, it is determined whether or not there is an answer command for the device driver 2 to be transmitted. If there is an answer command for the device driver 2 to be transmitted, this is discarded in S611, and the device driver to be transmitted is determined. If there is no answer command of 2, the process proceeds to S612.
[0151]
In S612, Ack of the device driver 2 is set in the answer queue. Similarly, Ack set in the answer queue is transmitted to the sub control unit A400.
[0152]
In S613, it is determined whether the sub-control command determined in S603 and S608 to be neither a command indicating an instruction to the device 1 nor a command indicating an instruction to the device 2 is a system command. In S614, a process corresponding to the content of the system command is executed, and if not, the process proceeds to S615.
[0153]
FIG. 9B is a flowchart illustrating an answer command transmission process in the slot machine 100 according to the present embodiment. In the answer command transmission process, the CPU 510 repeatedly executes the process of FIG.
[0154]
In S701, it is determined whether there is an answer command transmission request from the device driver 1 or the device driver 2. If there is an answer command transmission request, in S702, the answer command is set in the answer queue. Otherwise, the process proceeds to S703.
[0155]
In S703, it is determined whether or not the present process is to be ended (for example, whether or not the power-off is detected). If the power-off is detected, the present process is ended. If not, the process returns to S701.
[0156]
The processing from the reception of the command from the sub-control unit A400 to the transmission of the command to the sub-control unit A400 has been described above. A more specific processing flow will be described with reference to FIG.
[0157]
That is, as shown in FIG. 12, when the sub-control unit B500 including the second table (order / control data table) receives, for example, the sub-control command 1 as the sub-control command, the sub-control command B Is output to a device driver for effect reels. The effect reel device driver acquires the order of effects and the detailed contents of the effects specified by the sent control data. As shown in the drawing, in the ROM 512 of the sub-control unit B500, the effect order / control data table 1 and the order / control data table in which the effect order and effect details are stored in advance for each device driver are stored. An effect order / control data table 2 is stored, and an effect order and control contents are stored for each block. The number of effects in the effect order may be different for each block. For example, in one block, only the effect of rotating the left reel once and stopping at 7 is specified, and in other blocks, the effect of rotating the left reel once and stopping at 7, and the backlight of the left reel blinks. Two of the effects to be performed may be defined.
[0158]
In the example of FIG. 12, the effect 1: the right reel is rotated once and stopped at “6”, the effect 2: the backlight of the right reel is turned on, and the effect 3: an answer command (restart sound) according to the control data of the sub-control command 1. ), Effect 4: the right reel is rotated three times and stopped at "7", and effect 5: a block in which issuance of an answer command transmission (explosion sound) is referenced. The effect reel driver executes effects in this order.
[0159]
If the answer command is specified in the rendering order / control data table, the answer command is transmitted to the sub control unit A400.
[0160]
The format of the command (answer command) to be transmitted to the sub-control command A400 is as shown in FIG. That is, the acknowledgment (Ack) indicates a normal response, 0001b (b: binary) is an Ack from the device 1, and 1000b is an Ack from the device 2. In the answer command, 0010b to 0111b are answer commands from the device 1, and 1001b to 0111b are answer commands from the device 2. 0000b and 1111b are unused.
[0161]
Next, the second processing of the sub-control unit A400 (reception of a command from the sub-control unit B500 to driving of the device of the sub-control unit A400) will be described.
[0162]
FIG. 10 is a flowchart showing an answer command receiving process in the slot machine 100 of the present embodiment. This answer command receiving process is repeatedly executed by the CPU 410 unless a power failure or the like is detected.
[0163]
In S801, it is determined whether an answer command has been received from the sub control unit B500. If an answer command has been received, the answer command is determined in step S802; otherwise, the process proceeds to step S810.
[0164]
In S803, it is determined whether an acknowledgment (Ack) has been received. If an acknowledgment has been received, the process proceeds to S808; otherwise, the process proceeds to S804.
[0165]
In S804, it is determined whether or not the current transmission level is “0”. If the transmission level is “0”, the process proceeds to S805; otherwise, the process proceeds to S810.
[0166]
In S805, the current game mode (specifically, the data of the transmitted sub-control command) is acquired.
[0167]
In S806, the contents of the effect (effect data) to be executed are determined based on the received answer command and the current game mode with reference to the answer command conversion table.
[0168]
In S807, the effect data converted from the answer command in S806 is set.
[0169]
In other words, if the data of the sub-control command transmitted to the sub-control unit B500 is 1E, for example, and the data of the received answer command is 5, the effect data specified by 1E-5 is set by referring to the answer command conversion table. Will be done. When the effect data is set, it is determined in S402 of FIG. 8 that the designated effect is directly present, and thus the effect data set is acquired in S404.
[0170]
In S808, it is determined whether or not an Ack waiting timeout has occurred. If an Ack waiting timeout has occurred, the process proceeds to S810; otherwise, the process proceeds to S809. In this embodiment, an Ack wait timer for measuring the Ack wait timeout is set in S505 of the sub control command transmission process (FIG. 8B), and after the sub control command is transmitted by the Ack wait timer, Ack waiting time can be measured.
[0171]
In S809, the transmission level is decremented (subtracted by 1). Unless any communication error occurs, Ack is returned by the number of transmitted sub-control commands. Therefore, when all Ack for the transmitted control command are returned, the transmission level is 0.
[0172]
In S810, it is determined whether or not this processing is to be ended (for example, whether or not power-off has been detected). If power-off or the like is detected, this processing is ended; otherwise, the flow returns to S801.
[0173]
The processing from the reception of the command from the sub-control unit B500 to the driving of the device of the sub-control unit A400 has been described above. The specific processing flow will be described with reference to FIG.
[0174]
The sub-control unit A400 refers to the answer command conversion table and acquires the effect data corresponding to the answer command received from the sub-control unit B500. As described above, if the answer command conversion table is used, the number of answer command signal lines can be reduced. That is, in the present embodiment, the answer command is composed of 4 bits as described with reference to FIG. 11B, and can transmit only 16 types (2 × 2 × 2 × 2 = 16) of information at the maximum. However, if such a conversion table is used, more effect data can be associated with 4-bit information, so that a large amount of information can be transmitted regardless of the number of answer command signal lines. Will be able to
[0175]
Then, when the effect data is specified by the answer command conversion table, thereafter, each control data associated with the effect data is selected. For example, if data indicating explosion sound is defined in the item of sound effect in the control data, the device driver for sound effect output controls the speaker based on this data, and the sound explosion is output from the speaker. For example, the effect reel 170 stops at 7-7-7 under the control of the sub control unit B500, and at the same time, an explosion sound is emitted under the control of the sub control unit A400.
[0176]
Next, a specific example of the effect display of the effect reel 170 presented to the player by the above-described processing is shown in FIG.
[0177]
First, when the start lever is operated, the three effect reels start rotating (see FIG. 13 (1)).
[0178]
Thereafter, at the time of the first stop operation, "the left reel makes one rotation and stops at" 7 "", and at the time of the second stop operation, "the middle reel makes one rotation and stops at" 7 "" (FIG. 13 (2), (13) 3)).
[0179]
Next, at the time of the third stop operation, the right reel rotates once and stops at “6” (see FIG. 13 (4)), and immediately thereafter, the three effect reels rotate (see FIG. 13 (5)), and N After the rotation, the left reel, the center reel, and the right reel stop at "7", "7", and "7" (see FIG. 13 (6)). The explosion sound is output when "7", "7", and "7" are aligned.
[0180]
As described above, according to the present embodiment, at the end of the effect of the sub-control unit B500, the answer command is transmitted to the sub-control unit A400, and the reception of the answer command triggers the Since the effect is started, the effects of the sub-control unit A400 and the sub-control unit B500 can be completely synchronized.
[0181]
Note that the transmission timing of the answer command is not limited to the case where the response command is transmitted after the end of the effect processing as in the above-described embodiment. Just send it to For example, a time lag (effect execution delay time) from when the sub-control unit B500 sends the answer command to when the effect operation specified by the answer command is executed by the sub-control unit A400 is anticipated. The answer command may be sent earlier by the effect execution delay time than when the effect control that is being performed is scheduled to end.
[0182]
In the control data table of FIG. 12, when the sub-control command 1 and the sub-control command 2 are stored in the block specified by the received answer command, these sub-control commands are transmitted to the sub-control unit B500. This is transmitted to the effect reel 170 and the effect display by the effect reel 170 and the dot matrix type display device 180 is executed.
[0183]
In the above-described embodiment, the effect is mainly described by controlling the effect reel 170. However, it is needless to say that the effect by the dot matrix type display device 180 is also possible. Hereinafter, an example of the effect by the control of the dot matrix type display device 180 will be described.
[0184]
As shown in FIG. 12, an effect order / control data table 2 of a device driver for a dot matrix type display device (hereinafter, a device driver for a dot matrix) is prepared in the sub control unit B500. The rendering order / control data table 2 of the dot matrix device driver is stored in the ROM 512 of the sub-control unit B500, like the rendering order / control data table 1 of the rendering reel.
[0185]
Although not shown in the rendering order / control data table 2, the yacht appears when the start lever is operated, the yacht moves one frame at the first stop operation, and the yacht moves one frame at the second stop operation. Contents are stored. At the time of the third stop operation, the yacht is further moved by one frame. Processing contents such as display of a mark, followed by display of characters of a goal and transmission of an answer command indicating explosion sound are associated with each other.
[0186]
On the other hand, in the answer command conversion table of the sub-control unit A400, effect data including an explosion sound output is associated with the answer command so that the effect data is selected when the answer command is received. deep.
[0187]
FIG. 14 shows a specific example of the effect display of the dot matrix type display device 180 presented to the player with the above configuration.
[0188]
First, when the start lever is operated, a “yacht” appears on the dot matrix display device 180 (see FIG. 14A).
[0189]
Thereafter, at the time of the first stop operation, the “yacht” moves one frame to the left, and at the time of the second stop operation, the “yacht” appears one frame to the left (see FIGS. 14 (2) and (3)).
[0190]
Next, at the time of the third stop operation, the “yacht” moves to the left by one frame (see FIG. 14 (4)). The mark is displayed (see FIG. 14 (5)), and finally, the character display of the goal and the output of the explosion sound are performed simultaneously (see FIG. 14 (6)).
[0191]
When effect display is performed, not only one of the effect reel 170 and the dot matrix display device 180 but also both may be simultaneously driven. In addition, the effect display may be performed by three or more devices in addition to the effect display device provided as another second control object.
[0192]
Subsequently, communication between the sub control unit A400 and the sub control unit B500 will be described with reference to FIG. Here, it is assumed that the answer command is sent to the sub-control unit A400 after the effect of the sub-control unit B500 is completed.
[0193]
FIG. 15A shows a state in which communication is normally performed.
[0194]
For example, assume that the effect A (the effect of rotating each effect reel N times and finally stopping at “7-7-7”) is selected in the sub-control unit A400.
[0195]
As described above, the effect contents are stored in the sub-control command and transmitted to the sub-control unit B500. In the sub-control unit B500 that has received the sub-control command, control data corresponding to the sub-control command is notified to a predetermined device driver (FIG. 9A: S604), and Ack is sent to the sub-control unit A400. It is transmitted (FIG. 9A: S607).
[0196]
Thereafter, when the effect A is completed in the sub-control unit B500, an answer command is transmitted (FIG. 9B: S702), and the effect (for example, explosion sound) specified by the answer command is output in the sub-control unit A400. You.
[0197]
FIG. 15B shows a case where communication has not been performed normally due to some failure. Here, it is assumed that no Ack wait timeout has occurred for the sub-control command.
[0198]
Before receiving the Ack of these two sub-control commands (sub-control commands A and B), the sub-control unit A 400 that has transmitted the sub-control commands A and B instructing the effects A and B, When the sub-controller A400 receives the answer command (here, the answer command A), the transmission level is still set to “1”, and therefore, FIG. The effect processing by A is skipped. Therefore, even if the answer command A is returned, the effect of the answer command A (answer effect A) is not executed.
[0199]
As described above, if any communication failure occurs, the effect related to the failure is skipped, so that the player is not confused. For example, if the answer effect A outputs a stop sound of the left reel, and the answer effect B outputs a stop sound of the middle reel, the stop sound of the left reel is output after the stop sound of the middle reel is output. Is no longer output.
[0200]
FIG. 15C also shows a case where communication is not performed normally due to some kind of failure. In this case, the sub-control unit A responds to the sub-control command A transmitted from the sub-control unit A to the sub-control unit B. AckA is not returned. Therefore, even if the answer command A is received from the sub-control unit B with the end of the effect A, the answer effect A is executed because the transmission level is still set to “1” as described above. There is nothing to distract the player.
[0201]
When the next sub-control command B is transmitted, a timeout has occurred for AckA waiting for the sub-control command A, so that the transmission level is reset in S504 of FIG. Set). That is, when the AckB corresponding to the sub-control command B transmitted later is received, the transmission level becomes 0, so that the answer effect B by the answer command B is performed without any problem.
[0202]
【The invention's effect】
As described above, according to the gaming table of the first aspect, the second control unit controls the operation of the second control target based on the control signal sent from the first control unit to the second control unit, The first control unit can control the operation of the first control target based on the answer signal sent from the second control unit to the first control unit. It is possible to easily realize a cooperative operation between them.
[0203]
According to the gaming table of the second aspect, the transmission processing means of the second control unit, based on the transmission timing determined in relation to the end of a series of predetermined operations of the second control object, Since the signal is transmitted to the first control unit, the control operation of the second control object by the second control unit and the start of the control operation of the first control object by the first control unit can be smoothly performed without a break. .
[0204]
According to the gaming table of the third aspect, the transmission processing means of the first control unit further transmits a new control signal to the second control unit based on the answer signal received from the second control unit. Since it has a function, the control operation start / control operation end of the first control object by the first control unit and the control operation start / control operation end of the second control object by the second control unit are continuously performed. This makes it possible to easily realize a complicated linked operation between the first control object and the second control object.
[0205]
According to the gaming table of the fourth aspect, when the operation processing means of the first control unit receives the answer signal after receiving the acknowledgment signal from the second control unit, the operation processing unit based on the answer signal When the first control target is operated in response to receiving the answer signal without receiving the acknowledgment signal from the second control unit, the operation of the first control target based on the answer signal is canceled. When the first control unit and the second control unit do not perform appropriate signal transmission and reception, the first control unit operates when the first control unit does not cooperate with the second control object. The processing is performed so that the person playing the game at the gaming table is not puzzled.
[0206]
Further, according to the game console according to claim 5, when the first control unit receives the answer signal from the second control unit, the first control unit refers to the conversion table and corresponds to the answer signal corresponding to the received answer signal. (1) Since the operation processing means operates the first control object based on the content of the operation of the control object, the answer signal can be easily converted even if the operation control for the first control unit is complicated. The capacity can be reduced.
[0207]
According to the gaming table of the sixth aspect, when the first control unit receives a signal from the main control unit, the first control unit operates the first control target with reference to the first table, and The control signal stored in the table is transmitted to the second control unit, and the second control unit receiving the control signal operates the second control target with reference to the second table and transmits the control signal to the second table. Since the stored answer signal is transmitted to the first control unit, a signal transmitted from the main control unit to the first control unit, a control signal transmitted from the first control unit to the second control unit, The answer signal transmitted from the second control unit to the first control unit can be simple and small in capacity.
[0208]
According to the game console according to claim 7, when the first control unit receives a signal from the main control unit, the first control unit operates the first control target object with reference to the order table and the control data table. Transmits the control signal stored in the control data table to the second control unit, and upon receiving the control signal, the second control unit operates the second control object with reference to the sequence / control data table. Since the answer signal stored in the order / control data table is transmitted to the first control unit, a signal transmitted from the main control unit to the first control unit and a signal transmitted from the first control unit to the second control unit And the answer signal transmitted from the second control unit to the first control unit can be made simple and small in capacity.
[Brief description of the drawings]
FIG. 1 is a front view showing an appearance of a slot machine which is an embodiment of a game console according to the present invention.
FIG. 2 is a functional block diagram showing a main control unit of the slot machine.
FIG. 3 is a functional block diagram showing a sub control unit A of the slot machine.
FIG. 4 is a functional block diagram showing a sub control unit B of the slot machine.
FIG. 5 is a functional block diagram schematically showing a communication system of a sub control unit A and a sub control unit B of the slot machine.
FIG. 6 is a flowchart showing a main process performed by a main controller of the slot machine.
FIG. 7A is a flowchart showing a main control command receiving process in a sub control unit A of the slot machine.
(B): a flowchart showing a main process in a sub-control unit A of the slot machine.
FIG. 8A is a flowchart showing an effect process in the sub control unit A of the slot machine.
10B is a flowchart illustrating a sub-control command transmission process in the sub-control unit A of the slot machine.
FIG. 9A is a flowchart showing a control command receiving process in the sub-control unit B of the slot machine.
10B is a flowchart illustrating an answer command transmission process in the sub-control unit B of the slot machine.
FIG. 10 is a flowchart showing an answer command receiving process in a sub control unit A of the slot machine.
FIG. 11A is a schematic explanatory diagram of a command format (sub-control command) in the sub-control unit A of the slot machine.
(B): A schematic explanatory view of a command format (answer command) in the sub control unit B of the slot machine.
FIG. 12 is a schematic explanatory diagram showing a flow of a command transmission / reception process between a sub control unit A and a sub control unit B of the slot machine.
FIG. 13 is an explanatory diagram showing an example of a rotating operation of the effect reel provided in the slot machine.
FIG. 14 is an explanatory diagram showing an example of a display movement in a dot matrix type display device provided in a slot machine.
FIG. 15A is an explanatory diagram showing a flow of processing when communication is normally performed between the sub control unit A and the sub control unit B of the slot machine.
FIG. 4B is an explanatory diagram showing a first example of a processing flow when communication between the sub-controller A and the sub-controller B of the slot machine is not normally performed.
(C): an explanatory diagram showing a second example of the processing flow when communication between the sub-controller A and the sub-controller B of the slot machine is not performed normally.
[Explanation of symbols]
100 gaming tables
170 Direction Reel
180 dot matrix type display device
300 Main control unit
400 Sub-control unit A
500 Sub-control unit B

Claims (7)

A first control unit and a second control unit capable of two-way communication;
One or more first control objects controlled by the first control unit,
One or more second control objects controlled by the second control unit,
A game console having at least
In the second control unit,
Operation processing means for operating the second control target based on a control signal transmitted from the first control unit;
Transmission processing means for transmitting an answer signal to the first control unit based on the progress of the operation of the second control object;
And
In the first control unit,
Transmission processing means for transmitting a control signal to the second control unit, operation processing means for operating the first control target based on the answer signal transmitted from the second control unit,
A gaming table characterized by having a. The transmission processing means of the second control unit transmits the answer signal to the first control unit based on a transmission timing determined in association with the end of a predetermined series of operations of the second control object. The gaming table according to claim 1, wherein: The transmission processing means of the first control unit further has a function of transmitting a new control signal to the second control unit based on an answer signal received from the second control unit. The gaming table according to claim 1 or claim 2. The transmission processing means of the second control unit transmits an acknowledgment signal corresponding to the control signal to the first control unit based on receiving the control signal from the first control unit, and thereafter, transmits the answer signal , And
The operation processing means of the first control unit, when receiving the answer signal after receiving the acknowledgment signal from the second control unit, causes the first control target to operate based on the answer signal. When the answer signal is received without receiving an acknowledgment signal from the second control unit, the operation of the first control target based on the answer signal is canceled. The game console according to any one of claims 1 to 3. The first control unit includes, for each predetermined game mode, a conversion table that associates an answer signal to be received with a content of an operation of the first control target,
When an answer signal is received from the second control unit, the content of the operation of the first control object corresponding to the received answer signal is specified with reference to the conversion table, and the operation is performed based on the content. The game console according to any one of claims 1 to 4, wherein the processing means operates the first control target. The gaming table,
A plurality of reels on which a plurality of types of patterns are applied,
A start switch for starting rotation of the reel;
A stop switch provided for each of the reels for individually stopping the rotation of the reels,
The internal winning of the predetermined winning combination is determined by lottery and the winning combination is internally won, and the combination of the patterns displayed by the reels at the time of stoppage is determined by the internal winning winning combination. A main control unit that determines that the winning combination has been won if the combination is a predetermined pattern correspondingly;
With
The first control unit includes, for a signal sent from the main control unit, a first table that defines information relating to each operation of the first control target, and the first table includes at least the Defining data indicating the control signal to be transmitted to the second control unit,
The second control unit includes a received control signal and a second table that defines information relating to each operation of the second control target, and the second table indicates at least the answer signal. Store data,
When the first control unit receives the signal from the main control unit, the first control unit operates the first control target with reference to the first table, and stores the first control target in the first table. A control signal is transmitted to the second control unit, and the second control unit having received the control signal refers to the second table, operates the second control target, and stores the control object in the second table. The game console according to any one of claims 1 to 5, wherein the answer signal is transmitted to the first control unit. The gaming table,
A plurality of reels on which a plurality of types of patterns are applied,
A start switch for starting rotation of the reel;
A stop switch provided for each of the reels for individually stopping the rotation of the reels,
The internal winning of the predetermined winning combination is determined by lottery and the winning combination is internally won, and the combination of the patterns displayed by the reels at the time of stoppage is determined by the internal winning winning combination. A main control unit that determines that the winning combination has been won if the combination is a predetermined pattern correspondingly;
With
The first control unit includes, for a signal sent from the main control unit, an order table in which each operation content of the first control object and an operation order of the first control object are associated with each other; A control data table that defines the details of each operation content, and the control data table defines at least data indicating the control signal to be transmitted to the second control unit,
The second control unit includes a received control signal, and an order / control data table that defines an operation order of each of the second control objects and details of an operation content of each of the second control objects. The order / control data table stores at least data indicating the answer signal,
When the first control unit receives the signal from the main control unit, the first control unit operates the first control target with reference to the order table and the control data table, and transmits the signal to the control data table. The stored control signal is transmitted to the second control unit, and the second control unit that has received the control signal refers to the order / control data table and operates the second control object, The gaming table according to any one of claims 1 to 5, wherein an answer signal stored in the control data table is transmitted to the first control unit.

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