JP7153916B2 - game machine - Google Patents

Description

The present invention relates to gaming machines.

Conventionally, a game called pachislot, which includes a plurality of reels with a plurality of patterns arranged on each surface, a start switch, a stop switch, a stepping motor provided corresponding to each reel, and a control unit. machine is known. The start switch detects that the start lever has been operated by the player after game media such as medals and coins have been inserted into the gaming machine (hereinafter also referred to as "start operation"), and the rotation of all reels is detected. Outputs a signal requesting a start. The stop switch detects that the stop button provided corresponding to each reel has been pressed by the player (hereinafter also referred to as "stop operation"), and outputs a signal requesting the rotation of the relevant reel to stop. do. The stepping motor transmits its driving force to the corresponding reel. Also, the control unit controls the operation of the stepping motor based on the signals output by the start switch and the stop switch, and rotates and stops each reel.

In such a game machine, when a start operation is detected, a lottery process using random numbers (hereinafter referred to as "internal lottery process") is performed on the program, and the result of the lottery (hereinafter referred to as "internal winning combination") is performed. ) and the timing of the stop operation. Then, when the rotation of all the reels is stopped and the symbol combination related to the establishment of the prize is displayed, a privilege corresponding to the symbol combination is given to the player. Examples of benefits given to the player include the payout of game media (medals, etc.), and the activation of replay (hereinafter also referred to as “replay”) in which internal lottery processing is performed again without consuming game media. , operation of a bonus game in which the opportunity to pay out game media increases, and the like.

In addition, among game machines having the above configuration, there is disclosed a game machine equipped with a display control device that receives a command from a main control device and performs DMA transfer to a VDP (see Patent Document 1, for example ).

Japanese Patent Application Laid-Open No. 2005-160828

However, in the game machine described in Patent Document 1, although the command from the main control device could be received normally, if an error occurs during the DMA transfer, the DMA transfer does not end normally and the transfer fails. was likely to occur .

SUMMARY OF THE INVENTION It is an object of the present invention to provide a game machine capable of suppressing transfer omissions in consideration of the actual situation of the above-described conventional technology.

In order to solve the above problems, the present invention provides a gaming machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and transmits multiple types of instruction commands to the display unit,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
an image control means (for example, an image recognition DSP 212 described later) that controls the display of an image by the display means;
an image storage means (for example, an external memory 203 to be described later) in which a plurality of images are stored in advance;
a transfer control means (for example, a DMAC 215 described later) that performs a transfer process of reading an image from the image storage means and transferring the image to the image control means;
Display control means (for example, a host controller 210 described later) connected to the image control means and the transfer control means,
The display control means is
consistency determination means for determining consistency of the instruction based on the type of the received instruction;
when the type of the received instruction command is related to an image, causing the transfer control means to perform the transfer processing of the image corresponding to the instruction command from among the plurality of images stored in the image storage means. a transfer processing means for causing
a transfer process monitoring means for monitoring whether or not the transfer process by the transfer control means has been completed normally;
response command transmission means for transmitting a response command (for example, an ACK/NAK command to be described later) according to the determination result of the consistency determination means or the monitoring result of the transfer process monitoring means to the control unit; ,
The types of the reply command include a normal reply command and an abnormal reply command,
The normal reply command has a different data length depending on the type of the instruction command received,
The reply command for the time of abnormality has the same data length regardless of the type of the instruction command received, and the reply command for the time of abnormality includes the number of times the reply command for the time of abnormality is continuously transmitted. and abnormal contents.

According to the present invention, transfer omission can be suppressed .

1 is a perspective view showing an example of the external configuration of a gaming machine according to an embodiment of the present invention; FIG. 1 is a front view of a gaming machine according to an embodiment of the present invention with a front panel removed; FIG. It is an LED arrangement port diagram in the gaming machine of one embodiment of the present invention. 1 is a perspective view showing the internal structure of the gaming machine of one embodiment of the present invention, with the front door opened. FIG. 1 is a block diagram showing the overall configuration of a circuit included in a gaming machine according to one embodiment of the present invention; FIG. It is a block diagram showing an internal configuration of a sub-control circuit in the gaming machine of one embodiment of the present invention. 3 is a block diagram showing a circuit configuration example of a sub liquid crystal unit in the gaming machine of one embodiment of the present invention; FIG. It is a figure which shows an example of the pattern arrangement|positioning table in one Embodiment of this invention. FIG. 4 is a diagram for explaining a communication data format between a sub-control circuit and a sub-liquid crystal unit in the gaming machine of one embodiment of the present invention; FIG. 4 is a diagram for explaining an all-image request command in the gaming machine according to one embodiment of the present invention; FIG. FIG. 4 is a diagram for explaining an image checksum request command in the gaming machine according to one embodiment of the present invention; FIG. FIG. 4 is a diagram for explaining an image clear command in the gaming machine according to one embodiment of the present invention; FIG. It is a figure for demonstrating the QR request command in the gaming machine of one Embodiment of this invention. It is a figure which shows an example of the QR code which the sub-control circuit produces in the gaming machine of one Embodiment of this invention. FIG. 5 is a diagram for explaining a procedure for displaying a QR code on the sub-liquid crystal unit in the gaming machine of one embodiment of the present invention; FIG. 4 is a diagram for explaining a polling command in the gaming machine according to one embodiment of the present invention; FIG. FIG. 4 is a diagram for explaining a first image display command in the gaming machine of one embodiment of the present invention; FIG. 10 is a diagram for explaining a display mode of an image based on a first image display command in the gaming machine of one embodiment of the present invention; FIG. 10 is a diagram for explaining a second image display command in the gaming machine of one embodiment of the present invention; FIG. 10 is a diagram (part 1) for explaining a display mode of an image based on a second image display command in the gaming machine of one embodiment of the invention; FIG. 10 is a diagram (part 2) for explaining a display mode of an image based on a second image display command in the gaming machine according to the embodiment of the invention; It is a figure for demonstrating the ACK command in the gaming machine of one Embodiment of invention. It is a figure for demonstrating the NAK command in the gaming machine of one Embodiment of invention. FIG. 10 is a timing chart (part 1) showing transmission timings of ACK/NAK commands when image display commands are received in the gaming machine of one embodiment of the invention; FIG. FIG. 10 is a timing chart (part 2) showing transmission timings of ACK/NAK commands when image display commands are received in the gaming machine of one embodiment of the invention; FIG. 4 is a timing chart showing transmission timings of ACK/NAK commands when a QR request command is received in the gaming machine of one embodiment of the invention; 4 is a main flow chart showing an example of processing of a main control circuit of a game machine in one embodiment of the present invention; 5 is a flowchart showing an example of interrupt processing under control of a main CPU in one embodiment of the present invention; FIG. 4 is a flow chart showing an example of a main board communication task performed by a sub CPU in one embodiment of the present invention; FIG. It is a flow chart which shows an example of an effect registration task performed by sub CPU in one embodiment of the present invention. 4 is a flowchart showing an example of effect content determination processing in one embodiment of the present invention. FIG. 11 is a flow chart showing an example of a sound control task in a variant of the invention; FIG. FIG. 10 is a flow chart showing an example of an LED control task in a modification of the invention; FIG. It is a figure for demonstrating the QR request command which concerns on a modification.

A pachislot, which is a game machine representing an embodiment of the present invention, will be described below with reference to FIGS. 1 to 34. FIG.
In the present embodiment, a pachislot machine having a function of activating a replay time (hereinafter referred to as "RT"), which is a game state in which the probability of winning a replay becomes higher than in normal times when a specific combination of symbols is displayed, is described. explain.

<Structure of Pachislot>
Next, the structure of the pachislot according to the present embodiment will be described with reference to FIGS. 1 to 3. FIG.

[Appearance structure]
FIG. 1 is a perspective view showing the external structure of a pachislot machine 1. As shown in FIG. FIG. 2 is a front view of the pachislot machine 1 according to the present embodiment with the front panel 10 removed.

As shown in FIG. 1, the pachislot machine 1 has an exterior body 2. As shown in FIG. The exterior body 2 has a cabinet 2a for housing reels, circuit boards, etc., and a front door 2b attached to the cabinet 2a so as to be openable and closable.
Handles 7 are provided on both sides of the cabinet 2a (only the handle 7 on one side is shown in FIG. 1). The handle 7 is a concave portion that is used to hold the pachislot slot machine 1 when carrying it.

Inside the cabinet 2a, three reels 3L, 3C and 3R are arranged side by side. The reels 3L, 3C, and 3R are hereinafter referred to as the left reel 3L, middle reel 3C, and right reel 3R, respectively. Each of the reels 3L, 3C, and 3R includes a reel body formed in a cylindrical shape, a translucent sheet material attached to the peripheral surface of the reel body, and a reel for irradiating the sheet material with light from the inside of the reel body. and a light source. A plurality of (for example, 21) patterns are drawn on the surface of the sheet material at predetermined intervals along the circumferential direction. Here, a part of the red 7 patterns (not shown) is a translucent part. In addition, the reel body is provided with a reel backlight that illuminates the back surface of the sheet material. This reel backlight is turned on and off under the control of a sub-control circuit 42, which will be described later.

The front door 2 b includes a door body 9 , a front panel 10 and a light-emitting display device 11 .
The door body 9 is attached to the cabinet 2a using a hinge (not shown) so that it can be opened and closed. The hinge is provided at the left end of the door body 9 when the door body 9 is viewed from the front of the pachislot machine 1 .

A sub-door monitor switch (not shown) is provided at the other end in the left-right direction (on the right side when viewed from the front of the pachi-slot machine 1) on the rear side of the front door 2b. The sub door monitoring switch outputs to the sub control circuit 42 a signal indicating whether the front door 2b is opened or closed.

As shown in FIG. 1, the light-emitting display device 11 is provided above the door body 9 . The light-emitting display device 11 is composed of a dot matrix portion 119 (see FIG. 2) formed by a plurality of light source portions arranged in a matrix and a portion of the front panel 10 facing the dot matrix portion 119 .

The dot matrix section 119 lights (blinks) a light source section at an arbitrary location to illuminate an arbitrary location (firework pattern in this embodiment) of the design applied to the front panel 10 from the back. As a result, an effect is performed in which an arbitrary portion of the design applied to the front panel 10 is made to emit light.

Display windows 4L, 4C, and 4R for displaying patterns drawn on the three reels 3L, 3C, and 3R are provided below the light-emitting display device 11 . The display windows 4L, 4C, and 4R are hereinafter referred to as a left display window 4L, a middle display window 4C, and a right display window 4R, respectively.

The display windows 4L, 4C, 4R are made of a transparent member such as an acrylic plate. The display windows 4L, 4C, and 4R are provided at positions overlapping the arrangement areas of the three reels when viewed from the front (player's side), and positioned in front of the three reels (player's side). provided in Therefore, the player can visually recognize the three reels provided behind the display windows 4L, 4C and 4R through the display windows 4L, 4C and 4R.

In the present embodiment, the display windows 4L, 4C, and 4R display three consecutively arranged symbols out of a plurality of types of symbols drawn on each reel when the rotation of the corresponding reels provided behind them stops. It is set to a size that can display one pattern. That is, within the frames of the display windows 4L, 4C and 4R, upper, middle and lower areas are provided for each reel, and one symbol is displayed in each area.

The front panel 10 is attached to the top of the door body 9 . The front panel 10 has an upper display section 101 , a reel illumination section 102 , reel side effect display sections 103 A and 103 B, edge effect display sections 104 A and 104 B, and a reel lower display section 105 .

The upper display section 101 is arranged above the light-emitting display device 11 , and the reel illumination section 102 is arranged between the reels 3L, 3C, 3R and the light-emitting display device 11 . The reel side effect display portions 103A and 103B are arranged on the sides of the reels 3L, 3C and 3R, and the edge effect display portions 104A and 104B are arranged on the side of the reel side effect display portion 103.

The reel bottom display section 105 is arranged below the reels 3L, 3C, and 3R. A sub-liquid crystal unit 200 is provided in the central portion of the reel lower display portion 105 . The sub-liquid crystal unit 200 is a liquid crystal display device and includes a liquid crystal screen 202 on which images and videos are displayed.

The upper display unit 101, the reel illumination unit 102, the reel side effect display units 103A and 103B, the edge effect display units 104A and 104B, and the reel lower display unit 105 are provided with various lamp groups 111 to 117 provided on the door body 9 and described later. covering. These upper display portions 101, 102, 103A, 103B, 104A, 104B, and 105 are irradiated with light from various LED groups 111 to 117 and emit light.

For example, the reel side effect display section 103A is provided with three BET light emitting sections aligned in the vertical direction. The number of lit-up three BET light emitting parts indicates the number of medals used for one game.

In this embodiment, the number of medals used in one game is set to 1-3. For example, when the number of medals used in one game is set to "1", one BET light emitting portion (for example, the lowest BET light emitting portion) lights up, and the other BET light emitting portions (middle and one in line) light up. The BET light emitting part located at the top) goes out.

As shown in FIG. 1, a pedestal portion 12 is formed in the center of the door body 9 . Various devices to be operated by the player (medal slot 13, MAX bet button 14, 1 bet button 15, start lever 16, stop buttons 17L, 17C, 17R, enter button 21, select button, etc.) are provided on the pedestal 12. 22) is provided.

A medal slot 13 is provided for receiving medals dropped into the pachislot machine 1 from the outside by a player. The medals accepted from the medal slot 13 are used for one game with a preset number (for example, 3) as the upper limit, and the amount exceeding the preset number is deposited inside the pachi-slot machine 1.例文帳に追加(so-called credit function).

A MAX bet button 14 and a 1 bet button 15 are provided to determine the number of medals deposited inside the pachi-slot machine 1 to be used for one game. Although not shown in FIG. 1, the pedestal portion 12 is provided with a checkout button. This checkout button is provided for withdrawing (discharging) medals deposited inside the pachi-slot machine 1 to the outside.

A start lever 16 is provided to start rotation of all the reels (3L, 3C, 3R). The stop buttons 17L, 17C and 17R are provided corresponding to the left reel 3L, the middle reel 3C and the right reel 3R, respectively, and each stop button is provided to stop the rotation of the corresponding reel. The stop buttons 17L, 17C, and 17R are hereinafter referred to as the left stop button 17L, middle stop button 17C, and right stop button 17R, respectively.

The enter button 21 and the select button 22 are provided for selecting an arbitrary item among a plurality of selectable items on various screens displayed on the sub liquid crystal unit 200 . When the select button 22 is pressed, the position of the cursor for designating one of the displayed items and the highlighted item are changed. Also, when the enter button 21 is pressed, the specified item is selected.

A 7-segment display 6 made up of a 7-segment LED (Light Emitting Diode) is provided on the base portion 12 . This 7-segment display 6 displays the number of medals to be paid out to the player as a privilege (hereinafter referred to as the number of payouts), the number of medals deposited inside the pachislot machine 1 (hereinafter referred to as the number of credits), and the number of medals for playing the game. Information such as the number of inserted medals (hereinafter referred to as the number of bets) is digitally displayed.

A medal payout port 18, a medal tray 19, speakers 20L and 20R, and the like are provided at the lower portion of the door body 9. As shown in FIG. The medal payout port 18 guides to the outside the medals discharged by driving the medal payout device 33, which will be described later. A medal receiving tray 19 stores medals ejected from the medal pay-out port 18.例文帳に追加Also, the speakers 20L and 20R output sounds such as sound effects and music corresponding to the content of the presentation.

Further, the door body 9 is provided with a waist panel display portion 106 . The waist panel display section 106 is arranged above the speakers 20L and 20R. The waist panel display portion 106 covers a light source portion (port No. 53) provided on the door body 9 and described later. Then, the waist panel display section 106 emits light when irradiated with light from the light source section (port No. 53).

[Various LED groups]
FIG. 3 is an LED layout port diagram for pachislot 1. As shown in FIG.

As shown in FIG. 3, the door body 9 is provided with a 337-port light source. An LED is arranged in each light source. As the light source unit according to the present invention, an existing light-emitting element such as an organic electroluminescence element may be arranged as long as it can emit light in at least green, blue, and red.

A first LED group 111 is formed by the light source units associated with the No. 0 to No. 30 ports. The first LED group 111 emits light to the upper display section 101 (see FIG. 2). The light source units associated with ports No. 49 to No. 52 form a second LED group 112 . The second LED group 112 illuminates the reel illumination section 102 (see FIG. 2).

The light source units associated with ports No. 66 to No. 70 form a third LED group 113 , and the light source units associated with ports No. 71 to No. 75 form a fourth LED group 114 . The third LED group 113 emits light to the reel side effect display portion 103A (see FIG. 2), and the fourth LED group 114 emits light to the reel side effect display portion 103B (see FIG. 2). The light source units associated with the No. 68 to No. 70 ports of the third LED group 113 face the three BET light emitting units described above, and light up to cause the facing BET light emitting units to emit light.

The light source units associated with ports No. 54 to No. 59 form a fifth LED group 115 , and the light source units associated with ports No. 60 to No. 65 form a sixth LED group 116 . The fifth LED group 115 emits light to the edge effect display portion 104A (see FIG. 2), and the sixth LED group 116 emits light to the edge effect display portion 104B (see FIG. 2).

The light source units associated with ports No. 108 to No. 156 form a seventh LED group 117 . The seventh LED group 117 emits light to the reel lower display section 105 (see FIG. 2). The light source units associated with the No. 108 to No. 121 ports of the seventh LED group 117 display the number of stored medals, which is the number of medals deposited inside the pachislot machine 1, for example.

The light source units associated with ports No. 122 to No. 142 of the seventh LED group 117 display, for example, the number of medals won during the bonus. The light source units associated with ports No. 143 to No. 156 of the seventh LED group 117 display, for example, the number of medals to be paid out.

The light source units associated with ports No. 31 to No. 48 and No. 76 to No. 93 form an eighth LED group 118 . The light source units associated with ports No. 31 to No. 36 of the eighth LED group 118 function as a reel light source (reel backlight) for the left reel 3L. In addition, the light source units associated with ports No. 37 to No. 42 function as reel light sources (reel backlights) for the middle reel 3C, and the light source units associated with ports No. 43 to No. 48 function as light sources for the reels of the middle reel 3C. It functions as a 3R reel light source (reel backlight).

The light source unit associated with the No. 53 port illuminates the waist panel display unit 106 (see FIG. 2). The light source unit associated with the No. 157 port irradiates the MAXBET button 14 with light. Light is applied to the left stop button 17L. The light source unit associated with the No. 158 port illuminates the left stop button 17L. The light source unit associated with the No. 159 port illuminates the middle stop button 17C. The light source unit associated with the No. 160 port illuminates the right stop button 17R.

The light source sections associated with ports No. 161 to No. 337 form a dot matrix section 119 . The dot matrix portion 119 functions as a light source of the light emitting display device 11. FIG. Each port of the dot matrix section 119 is provided with one full-color LED. As a result, the transmission data to be transmitted to each port requires RGB (Red, Green, Blue) values on the cathode (minus) side and values on the anode (plus) side.

[Internal structure]
Next, the internal structure of pachislot 1 will be described with reference to FIG.
FIG. 4 is a perspective view showing the internal structure of the pachislot machine 1. As shown in FIG.

The cabinet 2a is formed in a substantially rectangular parallelepiped shape with one open surface on the front side. A main substrate 31 constituting a main control circuit 41 (see FIG. 5), which will be described later, is provided in the upper part of the cabinet 2a. The main control circuit 41 is a circuit that controls the main operations of the game in the pachislot 1, such as determining internal winning combinations, spinning and stopping each reel, and determining whether or not a prize has been won, and the flow between the operations. A specific configuration of the main control circuit 41 will be described later.

Further, the main board 31 is connected with a setting key type switch (not shown) used when changing the settings (settings 1 to 6) of the pachi-slot 1 or when checking the settings of the pachi-slot 1. ing. When a setting key (not shown) is inserted into the setting key-type switch, that is, when the setting key is turned on, the pachislot machine 1 is ready for setting operations (settings 1 to 6).

Three reels (a left reel 3L, a middle reel 3C and a right reel 3R) are provided in the central portion within the cabinet 2a. Although not shown in FIG. 4, each reel is connected to a corresponding stepping motor (one of stepping motors 61L, 61C, and 61R in FIG. 5) through a gear having a predetermined reduction ratio. .

A medal payout device 33 (hereinafter referred to as a hopper 33) having a structure capable of accommodating a large amount of medals and discharging them one by one is provided in the lower part of the cabinet 2a. A power supply device 34 is provided on one side (the left side in the example shown in FIG. 4) of the hopper 33 inside the cabinet 2a to supply necessary power to each device of the pachi-slot machine 1. As shown in FIG.

A sub-board 32 that constitutes a sub-control circuit 42 (see FIGS. 5 and 6), which will be described later, is provided on the upper portion of the back side of the front door 2b (the portion on the side opposite to the display screen side). The sub-control circuit 42 is a circuit that controls execution of effects such as video display. A specific configuration of the sub-control circuit 42 will be described later.

Further, a selector 35 is provided at a substantially central portion on the back side of the front door 2b. The selector 35 is a device for selecting whether or not the material, shape, etc. of medals inserted from the outside through the medal slot 13 (see FIG. 1) are appropriate. guide to. Although not shown in FIG. 4, a medal sensor 35S (see FIG. 5) is provided on the path through which the medals pass in the selector 35 to detect that a proper medal has passed.

<Structure of circuit provided by pachislot>
Next, the circuit configuration of the pachi-slot machine 1 will be described with reference to FIGS. 5 and 6. FIG.
FIG. 5 is a block diagram of the entire circuit provided in the pachi-slot machine 1. As shown in FIG. FIG. 6 is a block configuration diagram showing the internal configuration of the sub-control circuit.

The pachi-slot machine 1 includes a main control circuit 41, a sub-control circuit 42, and peripheral devices (actuators) electrically connected to these circuits.

[Main control circuit]
The main control circuit 41 is mainly composed of a microcomputer 50 installed on the circuit board (main board 31). Other components of the main control circuit 41 include a clock pulse generation circuit 54, a frequency divider 55, a random number generator 56, a sampling circuit 57, a display drive circuit 64, a hopper drive circuit 65, and a payout completion signal circuit. 66 included.

The microcomputer 50 includes a main CPU 51 , a main ROM (Read Only Memory) 52 and a main RAM (Random Access Memory) 53 .

The main ROM 52 stores control programs for various processes executed by the main CPU 51, data tables such as an internal lottery table, data for transmitting various control instructions (commands) to the sub-control circuit 42, and the like. . The main RAM 53 is provided with a storage area for storing various data such as an internal winning combination determined by executing the control program.

A clock pulse generation circuit 54 , a frequency divider 55 , a random number generator 56 and a sampling circuit 57 are connected to the main CPU 51 . A clock pulse generating circuit 54 and a frequency divider 55 generate clock pulses. The main CPU 51 executes the control program based on the generated clock pulse. Also, the random number generator 56 generates a random number within a predetermined range (0 to 65535, for example). The sampling circuit 57 then extracts one value from the generated random numbers.

Various switches and sensors are connected to the input port of the microcomputer 50 . The main CPU 51 receives input signals from various switches and the like, and controls operations of peripheral devices such as stepping motors 61L, 61C, and 61R.

The stop switch 17S represents a specific example of stop operation detection means according to the present invention, and indicates that each of the left stop button 17L, middle stop button 17C, and right stop button 17R has been pressed by the player (stop operation). ). The start switch 16S represents a specific example of start operation detection means according to the present invention, and detects that the start lever 16 has been operated by the player (start operation). The settlement switch 14S detects that the settlement button has been pressed by the player.

The medal sensor 35</b>S represents a specific example of the insertion operation detection means according to the present invention, and detects that the medal inserted into the medal insertion slot 13 has passed through the selector 35 . Also, the bet switch 12S detects that the bet button (MAX bet button 14 or 1 bet button 15) has been pressed by the player.

Peripheral devices whose operations are controlled by the microcomputer 50 include three stepping motors 61L, 61C, 61R, a 7-segment display 6, and a hopper 33. A drive circuit for controlling the operation of each peripheral device is connected to the output port of the microcomputer 50 .

A motor drive circuit 62 controls driving of three stepping motors 61L, 61C and 61R provided corresponding to the left reel 3L, middle reel 3C and right reel 3R, respectively. The reel position detection circuit 63 detects a reel index indicating that the reel has made one rotation for each reel by means of an optical sensor having a light-emitting portion and a light-receiving portion.

Each of the three stepping motors 61L, 61C, and 61R has a momentum proportional to the number of pulse outputs, and has a configuration capable of stopping the rotating shaft at a specified angle. Also, the driving force of each stepping motor is transmitted to the corresponding reel via a gear having a predetermined reduction ratio. Each time one pulse is output to each stepping motor, the corresponding reel rotates at a constant angle.
The three reels 3L, 3C, 3R and the three stepping motors 61L, 61C, 61R represent one specific example of the variable display means according to the present invention.

After detecting the reel index of each reel, the main CPU 51 counts the number of times a pulse is output to the corresponding stepping motor to determine the rotation angle of each reel (specifically, how many symbols the reel has). only rotated).

Here, management of the rotation angle of each reel will be specifically described. The number of pulses output to each stepping motor is counted by a pulse counter (not shown) provided in the main RAM 53 . Then, each time the pulse counter counts the pulse output a predetermined number of times (for example, 16 times) required for one symbol rotation, the value of the symbol counter (not shown) provided in the main RAM 53 is changed to "1". ” is added. A symbol counter is provided for each reel. The symbol counter value is cleared when the reel position detection circuit 63 detects the reel index.

That is, in this embodiment, by managing the value of the symbol counter, it is managed how many symbols have been rotated since the reel index was detected. Therefore, the position of each symbol on each reel is detected with reference to the position where the reel index is detected.

Note that the display drive circuit 64 controls the operation of the 7-segment display 6 . A hopper drive circuit 65 controls the operation of the hopper 33 . The payout completion signal circuit 66 manages medal detection performed by the medal detector 33S provided in the hopper 33, and checks whether or not the number of medals discharged outside from the hopper 33 has reached a predetermined payout number. Also, the main control circuit 41 is connected to an external terminal board 18S. The main control circuit 41 is connected to the hall computer or calling device 100 via the external terminal board 18S.

[Sub control circuit]
As shown in FIG. 6 , the sub-control circuit 42 is electrically connected to the main control circuit 41 and performs processing such as determination and execution of effects based on commands transmitted from the main control circuit 41 . The sub-control circuit 42 basically includes a sub-CPU 81, a sub-ROM 82, a sub-RAM 83, a DSP (Digital Signal Processor) 90, an audio RAM 91, a D/A (Digital to Analog) converter 92, and an amplifier 93 is included.

The sub CPU 81 controls the output of sound, light, and images in accordance with the control program stored in the sub ROM 82 in response to commands transmitted from the main control circuit 41 . The sub-ROM 82 represents a specific example of effect storage means in the gaming machine of the present invention, and basically has a program storage area and a data storage area.

Various control programs executed by the sub CPU 81 are stored in the program storage area. Note that the control program stored in the program storage area includes, for example, a main board communication task for controlling communication with the main control circuit 41, a random number value for effect extraction, determination of effect contents (effect data), and An effect registration task for performing registration, a lamp control task for controlling light output from the dot matrix unit 119 of the light-emitting display device 11 and various LED groups based on the determined effect content, and sound output from the speakers 20L and 20R programs such as a sound control task for controlling , and an image control task for controlling image output by the sub liquid crystal unit 200 .

The data storage area includes, for example, a storage area for storing various data tables, a storage area for storing effect data that constitutes various effect contents, a storage area for storing sound data related to BGM and sound effects, and a light on/off pattern. Various storage areas such as a storage area for storing LED data related to are included.

The sub-RAM 83 has a storage area for registering determined effect contents and effect data, a storage area for storing various data such as internal winning combinations transmitted from the main control circuit 41, and the like.

The sub CPU 81 also receives information from the front door 2b at 10:30 on September 18, 2018, based on the signal received from the sub door monitoring switch. is opened, "20180918 1030 OPEN"), or information indicating that the front door 2b is closed and the closing time (hereinafter sometimes referred to as door opening/closing history data) is stored in the sub-RAM83.

6, the sub-control circuit 42 includes peripheral devices such as a first LED group 111, a seventh LED group 117, an eighth LED group 118, a dot matrix section 119, speakers 20L and 20R, and a sub-liquid crystal unit 200. It is connected. That is, the operations of these peripheral devices are controlled by the sub-control circuit 42 . The sub-control circuit 42 is also connected to an enter switch 21S for detecting the operation of the enter button 21 and a select switch 22S for detecting the operation of the select button 22. FIG.

The first LED group 111, the seventh LED group 117, the eighth LED group 118, and the dot matrix section 119 show a specific example of the effect executing means according to the present invention, and the eighth LED group 118 is a rotating LED group according to the present invention. It shows one specific example of the display means. Also, the speakers 20L and 20R show a specific example of the audio output means according to the present invention.

The first LED group 111 is connected to the sub CPU 81 (sub control circuit 42) via the upper display LED drive board 121. As shown in FIG. A driver (circuit) that receives a control signal (LED control data or difference data described later) sent from the sub CPU 81 and supplies current to the first LED group 111 is mounted on the upper display unit LED drive board 121 . . That is, the sub CPU 81 and the upper display unit LED drive board 121 show a specific example of the effect control means, create a control signal (LED control data or difference data described later) based on the content of the effect, the first LED group 111 control.

The seventh LED group 117 is connected to the sub CPU 81 (sub control circuit 42) through the 7SEG drive board 127. FIG. The 7SEG drive board 127 is mounted with a driver (circuit) that receives a control signal (LED control data or differential data described later) transmitted from the sub CPU 81 and supplies current to the seventh LED group 117 . That is, the sub CPU 81 and the 7SEG drive board 127 show a specific example of the effect control means, and create a control signal (LED control data or differential data described later) based on the content of the effect, and control the seventh LED group 117. do.

The eighth LED group 118 is connected to the sub-CPU 81 (sub-control circuit 42) through the reel LED drive board 128. As shown in FIG. A driver (circuit) that receives a control signal (LED control data or difference data described later) transmitted from the sub CPU 81 and supplies current to the eighth LED group 118 is mounted on the drum section LED drive board 128 . . In other words, the sub CPU 81 and the reel section LED drive board 128 show a specific example of the effect control means, and create a control signal (LED control data or difference data described later) based on the content of the effect, and the eighth LED group 118.

The dot matrix section 119 is connected to the sub CPU 81 (sub control circuit 42) through the matrix drive board 129. FIG. The matrix drive board 129 is mounted with a driver (circuit) that receives a control signal (LED control data or differential data described later) transmitted from the sub CPU 81 and supplies current to the eighth LED group 118 . That is, the sub CPU 81 and the matrix drive board 129 show a specific example of effect control means, and create a control signal (LED control data or difference data, which will be described later) based on the content of the effect, and control the dot matrix section 119. do.

In addition, the second LED group 112, the third LED group 113, the fourth LED group 114, the fifth LED group 115, the sixth LED group 116, and the light source units related to other ports according to the present embodiment each include a drive board (not shown). It is connected to the sub-control circuit 42 via. In this embodiment, the 337-port light source units (see FIG. 3) are controlled at a predetermined cycle (2 msec in this embodiment).

The sub CPU 81 and various drive boards (rotary drum section LED drive board 128, matrix drive board 129, etc.) show specific examples of effect control means according to the game machine of the present invention.

Further, in this embodiment, each substrate 121, 127, 128, 129 communicates with each lamp group 111, 117, 118 and the dot matrix section 119 by a serial bus communication method. In the serial bus communication, the lamp groups 111, 117, 118 and the dot matrix section 119 are controlled by synchronous serial communication using two lines of data line/clock line or three lines of data line/clock line/select line. Data for controlling the light emission mode of the LED is transmitted.

Further, in the present embodiment, the reel section LED drive board 128 statically controls the reel light source (reel backlight) in the eighth LED group 118 . There are dynamic control and static control as LED lighting methods (methods). In the dynamic control, the lit LED blinks at a constant frequency at high speed. In this dynamic control, if the interval of flickering at a high frequency is shortened, when viewed with the human eye, it appears as if it is always on due to the afterimage phenomenon.

When the reel backlight is dynamically controlled, the emission of the reel backlight appears to flicker when the reel rotates. As a result, problems such as hindrance to so-called eye pressing and eye fatigue tend to occur. Therefore, in this embodiment, the reel backlight is statically controlled. In static control, current is continuously applied to the LED. As a result, since a constant current always flows through the LEDs, it is possible to prevent flickering of light emitted from the reel backlight. In this embodiment, part of the red 7 pattern is a semi-transparent portion, and when the reels rotate, the semi-transparent portion is emphasized by the light of the reel backlight to enhance the distinguishability of the pattern. At that time, when the translucent portions of the reels pass through the display windows 4L, 4C, and 4R, the light of the reel backlight is strong and visible, so if flickering occurs here, it is likely to interfere with eye pressing. It can be said that static control for suppressing flicker is more effective when it is applied to a game machine having reels having semi-transparent portions in this way. However, static control requires more wires and ports than dynamic control.

Also, the sub CPU 81, DSP 90, audio RAM 91, D/A converter 92 and amplifier 93 output sounds such as BGM from the speakers 20L and 20R in accordance with sound data specified by the presentation content.

[Sub LCD unit]
Next, the circuit configuration of the sub liquid crystal unit 200 will be described with reference to FIG.
FIG. 7 is a block diagram showing a circuit configuration example of the sub liquid crystal unit 200. As shown in FIG.

The sub liquid crystal unit 200 is composed of a control LSI 201 , a horizontally long rectangular liquid crystal screen 202 , and an external memory 203 .
The external memory 203 is composed of a flash memory and stores image data (image data) to be displayed on the liquid crystal screen. The control LSI 201 reads out image data from the external memory 203 according to a command or the like received from the sub-control circuit 42 and displays it on the liquid crystal screen. Each of the plurality of image data stored in the external memory 203 is assigned an image number consisting of 2 bytes. Further, in this embodiment, a read-only flash memory is used as the external memory 203, but other storage devices such as SSD, HDD, and rewritable flash memory can be used instead of the read-only flash memory. etc. may be used as an external memory.

The control LSI 201 includes a host controller 210 , a video output circuit 211 , an image recognition DSP (digital signal processor) 212 , an SRAM (Static Random Access Memory) 213 and a flash memory 214 .

The control LSI 201 also includes a DMAC (DMA Controller) 215 , an SPI (Serial Peripheral Interface) 216 and a UART (Universal Asynchronous Receiver Transmitter) 217 . Various devices included in the control LSI 201 are interconnected via a bus, and the control LSI 201 of this embodiment employs AXI (Advanced eXtensible Interface) as a bus protocol.

The host controller 210 is composed of, for example, a CPU and an MPU, and controls various devices included in the control LSI 201, such as the image recognition DSP 212 and the like.

The control LSI 201 is connected to the external memory 203 via the SPI 216 . In this embodiment, the control LSI 201 uses the SPI 216 to read the image data from the external memory 203. Instead of the SPI 216, other interfaces such as SATA I/F, I2C, and I3C are used. may be used to read image data from the external memory 203 .
The UART 217 is a serial communication device for transmitting and receiving various commands described later between the sub liquid crystal unit 200 and the sub control circuit 42 . In this embodiment, the UART 217 is used for communication between the sub-liquid crystal unit 200 and the sub-control circuit 42. Instead of the UART 217, other interfaces such as SPI, I2C, I3C, Ethernet ( Ethernet (registered trademark) may be used for communication between the sub liquid crystal unit 200 and the sub control circuit 42 .

The DMAC 215 reads image data from the external memory 203 and transfers it to the image recognition DSP 212 according to instructions from the host controller 210 . Also, QR data, which will be described later, is transferred from the SRAM 213 to the image recognition DSP 212 . These transfer processes may be referred to as DMA transfer in the following description.

Various programs are stored in the flash memory 214. For example, the host controller 210 develops the programs stored in the flash memory 214 in the SRAM 213 and executes them.

The video output circuit 211 is capable of outputting an image by LVDS (Low voltage differential signaling), and the image recognition DSP 212 outputs an image related to the data DMA-transferred by the DMAC 215 via the video output circuit 211. , is displayed on the liquid crystal screen 202 .

<Structure of Data Table Stored in Main ROM>
Next, referring to FIG. 8, a symbol layout table (symbol layout table) will be described as an example of a data table stored in the main ROM 52. FIG.

[Pattern arrangement table]
As shown in FIG. 8, the symbol layout table defines the position of each symbol in the rotational direction of each of the left reel 3L, middle reel 3C and right reel 3R.

In the symbol arrangement table, when the reel index is detected, the position of the symbol of each reel arranged in the middle area within the frames of the display windows 4L, 4C, 4R is defined as "0". Then, on each reel, "0" to "20" corresponding to the symbol counter are set as symbol positions in the order of progression in the reel rotation direction (arrow A direction in FIG. 7) with symbol position "0" as a reference. assigned to the pattern.

That is, by referring to the value of the symbol counter (“0” to “20”) and the symbol layout table, the symbols are displayed in the upper, middle and lower areas of each reel within the frames of the display windows 4L, 4C and 4R. It is possible to specify the type of pattern that is being used. For example, when the value of the symbol counter corresponding to the left reel 3L is "7", the upper, middle and lower areas of the left reel 3L within the frame of the display window 4 each have " Symbols corresponding to "Don 1", "Bell 2" at symbol position "7", and "Replay" at symbol position "6" are displayed.
Description of other data tables such as the internal lottery table stored in the main ROM 52 will be omitted.

<Communication between sub control circuit and sub liquid crystal unit>
[Communication data format]
Next, communication between the sub-control circuit 42 and the sub-liquid crystal unit 200 will be described. First, the communication data format between the sub-control circuit 42 and the sub-liquid crystal unit 200 will be described with reference to FIG. FIG. 9 is a diagram for explaining the communication data format between the sub-control circuit 42 and the sub-liquid crystal unit 200. As shown in FIG.

Here, the communication specifications between the sub-control circuit and the sub-liquid crystal unit are set such that the communication speed is 115200 bps, the data length is 8 bits, the stop bit is 1 bit, and the parity bit is EVEN (even number).

As shown in FIG. 9, the communication data between the sub-control circuit 42 and the sub-liquid crystal unit 200 includes STX, CRC, LEN, BLK, CNT, CMD, DAT, and ETX codes.

STX is a 1-byte code indicating a start code, and its value is "02" in hexadecimal.
CRC is a 2-byte code used for cyclic redundancy check, and the check target is from LEN to the end of DAT.

LEN is a 1-byte code indicating the text length (from BLK to end of DAT).
BLK is a 1-byte code indicating a transmission block end flag. "0"("00" in hexadecimal) indicates the end, "1"("01" in hexadecimal) indicates continuation, "2"("02" in hexadecimal) ) indicates continuation of another ID. For example, if the data body related to a command is 128 bytes or more, the data body cannot be transmitted by sending the command once. In such a case, since the same command is continuously transmitted, the BLK value of the previously transmitted command becomes "01". Also, when another command is transmitted next in relation to the command transmitted first, the value of BLK is "02". It is not that the sub-control circuit 42 cannot transmit a data body of 128 bytes or more, but rather that it receives a command with a data body of 128 bytes or more due to the relationship between the processing speed of the host controller 201 of the sub-liquid crystal unit 200 and the capacity of the SRAM 213. Since this is difficult, the number of data that the sub-control circuit 42 transmits to the sub-liquid crystal unit 200 is limited. For this reason, a situation may arise in which the data text cannot be transmitted in one command transmission.

CNT is a 2-byte code indicating a transmission counter.
CMD is a 2-byte code indicating a command ID, which is a unique ID of various commands transmitted and received between the sub-control circuit 42 and the sub-liquid crystal unit 200 . Here, the various commands include an all image information request command (command ID is "10" in hexadecimal notation), an image checksum request command (command ID is "11" in hexadecimal). Also, a screen clear command (command ID is "30" in hexadecimal), a first image display command (command ID is "33" in hexadecimal), a QR request command (command ID is "33" in hexadecimal) "32"), and a second image display command (command ID is "31" in hexadecimal). There is also a polling command (command ID is "7F" in hexadecimal).

The various commands include an ACK command (command ID is "06" in hexadecimal), a NAK command (command ID is "15" in hexadecimal), which are transmitted from the sub-liquid crystal unit 200 to the sub-control circuit 42. ”). Details of these commands will be described later.

DAT is the data body and has a variable length of 0 to 128 bytes. ETX is a 1-byte code indicating an end code, and its value is "03" in hexadecimal.

The communication data includes codes (STX, CRC, LEN, BLK, CNT, CMD, ETX) other than DAT regardless of the command type. Therefore, the data length of the communication data is variable from 9 bytes (when the DAT is 0 bytes) to 137 bytes (when the DAT is 128 bytes).

[All image information request command]
Next, the all image request command will be described with reference to FIG. FIG. 10 is a diagram for explaining the all image request command.

The all image request command is composed of STX, CRC, LEN, BLK, CNT, CMD, and ETX codes. In FIG. 10, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the all image request command is "04" (hexadecimal notation) indicating 4 bytes.
The value of BLK is "02" (in hexadecimal notation) when another command related to this command is transmitted next, and "00" (16 notation).

The value of CNT is the number of counts at that time.
The value of CMD is "10" (hexadecimal notation) indicating the command ID of the all image information request command.

[Image checksum request command]
Next, the image checksum request command will be described with reference to FIG. FIG. 11 is a diagram for explaining the image checksum request command.

All image request commands are composed of STX, CRC, LEN, BLK, CNT, CMD, 2-byte DAT (DAT0, DAT1), and ETX codes. In FIG. 11, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the image checksum request command is "06" (hexadecimal notation) indicating 6 bytes.
The value of BLK is "02" (in hexadecimal notation) when another command related to this command is transmitted next, and "00" (16 notation).

The value of CNT is the number of counts at that time.
The value of CMD is "11" (hexadecimal notation) indicating the command ID of the image checksum request command.
The values of DAT0 and DAT1 are image numbers of image data stored in the external memory 203 to be checked.

[Screen clear command]
Next, the screen clear command will be described with reference to FIG. FIG. 12 is a diagram for explaining the screen clear command.

The screen clear command consists of STX, CRC, LEN, BLK, CNT, CMD, and ETX codes. In FIG. 12, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the screen clear command is "04" (hexadecimal notation) indicating 4 bytes.
The value of BLK is "02" (in hexadecimal notation) when another command related to this command is transmitted next, and "00" (16 notation).

The value of CNT is the number of counts at that time.
The value of CMD is "30" (hexadecimal notation) indicating the command ID of the screen clear command.

[QR request command]
Next, the QR request command will be explained with reference to FIGS. 13 to 15. FIG. FIG. 13 is a diagram for explaining the QR request command. FIG. 14 is a diagram showing an example of a QR code (registered trademark) created by the sub-control circuit 42. As shown in FIG. FIG. 15 is a diagram for explaining the procedure for displaying the QR code on the sub liquid crystal unit.

The QR request command is transmitted from the sub-control circuit 42 to the sub-liquid crystal unit 200 when displaying the QR code on the sub-liquid crystal unit 200 .
The QR request command consists of STX, CRC, LEN, BLK, CNT, CMD, DAT (DAT 0-4, DAT 5-127 depending on the amount of data), and ETX codes. In FIG. 13, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the QR request command is variable according to the number of DATs, and is a value from "04" (hexadecimal notation) indicating 4 bytes to "84" (hexadecimal notation) indicating 132 bytes.
The value of BLK is one of "00", "01", and "02". For example, when the data (QR data) related to the QR code to be displayed is 128 bytes or more, the data cannot be transmitted by transmitting the QR request command once. Therefore, in such a case, since the QR request command is subsequently transmitted, the BLK value of the previously transmitted QR request command becomes "01" (hexadecimal notation) indicating continuation. If another command is sent next in relation to this command, it will be "02" (hexadecimal notation) indicating continuation of another ID, and if there is no next command in relation to this command, "00" will be displayed. (hexadecimal notation).

The value of CNT is the number of counts at that time.
The value of CMD is "32" (hexadecimal notation) indicating the command ID of the QR request command.
The values of DAT0 to DAT127 are the values of QR data, which is data related to the QR code to be displayed.

The values of DAT0 to 3 are values indicating display coordinates, which are positions on the liquid crystal screen 202 where the reference point (upper left corner of the image) of the image (QR code in this command) is displayed. In the liquid crystal screen 202 of this embodiment, the display coordinate value in the horizontal direction (X direction) of the gaming machine can be set to 0 to 479, and the display coordinate value in the vertical direction (Y direction) can be set to 0 ∼271 can be set. When the display coordinate values are represented in the format of (X-direction display coordinate value, Y-direction display coordinate value), in this embodiment, as shown in FIG. The corner display coordinates are set to (0, 0), the upper right corner display coordinates are set to (479, 0), and the lower left corner display coordinates are set to (0, 271).

The values of DAT0 and 1 among DAT0 to 3 are the display coordinate values in the X direction of the upper left corner of the QR code to be displayed. Also, the values of DAT2 and 3 are the values of the display coordinates in the Y direction of the upper left corner of the QR code to be displayed.

When displaying the QR code on the sub liquid crystal unit 200, the sub CPU 81 of the sub control circuit 42 reads the door opening/closing history data from the sub RAM 83, and displays the QR code shown in FIG. 14(A) based on the read door opening/closing history data. to create Regarding the QR code, the version of the so-called QR code model (which can be set arbitrarily from 1 to 40) is the information amount of the door opening/closing history data represented by the QR code and the required decoding level (error correction level, L, M, Q, H), it is preset in the sub-ROM 82 or stored in the SRAM 213 . Also, a QR enlargement factor (for example, 1 to 10 times can be set) that specifies the size of the QR code when displayed is preset.

Next, the sub CPU 81 of the sub control circuit 42 performs binarization processing for binarizing the created QR code. In the binarization process, as shown in FIG. 14(A), an area (an area surrounded by a chain double-dashed line in the drawing, hereinafter referred to as a "predetermined area") excluding the rectangular cutout symbol (position detection pattern) at the three corners is performed).

FIG. 14B shows an enlarged view of a region A (the region surrounded by a dashed line) within the predetermined region shown in FIG. 14A.
In the binarization process, the sub CPU 81 of the sub control circuit 42, as shown in FIG. "1" is set, and white is set to "0".
Then, the sub CPU 81 of the sub control circuit 42 issues a QR request command including the display coordinates (DAT0 to 3) of the QR code, the QR magnification (DAT4), and the binarized QR code data (DAT5 to DAT127). , to the sub liquid crystal unit 200 .
One cell converted to 1-bit data depends on the decoding level and the QR expansion ratio, but for example, the number of pixels is 4 to 10 pixels in the horizontal direction (X direction) and 4 to 10 pixels in the vertical direction (Y direction). It consists of 10 pixels.

Here, the operation for displaying the QR code on the sub liquid crystal unit 200 will be described. The standby screen shown in FIG. 15A is displayed on the sub liquid crystal unit 200 during standby (playing). When the enter button 21 is operated while the standby screen is displayed, the sub-control circuit 42 causes the sub-liquid crystal unit 200 to display the menu screen shown in FIG. 15(B).

When the select button 22 is operated to select "Unimemo" as a selection item while the menu screen is displayed, a setting key (not shown) connected to the main control circuit 41 is turned on, Further, when the enter button 21 is operated, the sub-control circuit 42 creates a QR code of the door opening/closing history data. Then, the sub-control circuit 42 binarizes the created QR code, and transmits to the sub liquid crystal unit 200 a QR request command including the display coordinates of the QR code, the QR enlargement magnification, and the data of the binarized QR code.
When the enter button 21 is operated while the setting key is off, a QR code of game history data (total number of games played, number of bonus games, number of ART, etc.) is created.

When the sub-liquid crystal unit 200 receives the QR request command, the image recognition DSP 212 of the control LSI 201 detects the version of the predetermined QR code model and the QR data included in the command, that is, the display coordinates of the QR code, the QR enlargement magnification and the QR The QR code is restored based on the binarized data of the code, and the restored QR code is displayed on the liquid crystal screen 202 as shown in FIG. 15(c). When restoring the QR code, the image of the rectangular clipped symbol (position detection pattern) at the three corners corresponding to the QR enlargement magnification stored in the pre-stored flash memory 214 is used for the received QR code. Synthesize with data and restore.

In addition, as described above, if the QR data is 128 bytes or more and the QR data cannot be transmitted by transmitting the QR request command once, as shown in "DAT after the second QR request command" in FIG. The values of DAT0 to 127 in the QR request command transmitted through the QR request command are binarized QR code data values. In other words, data relating to display coordinates and magnification are not transmitted redundantly.

The QR code displayed on the liquid crystal screen 202 is read by a mobile terminal device (for example, a smartphone or tablet terminal). In this portable terminal device, the QR code is analyzed and the door opening/closing history data can be displayed on the display means in a manner ("20180918 1030 OPEN") that can be recognized by the administrator. As a result, even if the pachi-slot machine 1 is equipped with a sub-liquid crystal unit 200 having a relatively small liquid crystal screen 202, the administrator can easily check the door opening/closing history with the portable terminal device regardless of the size of the liquid crystal screen 202. can be confirmed. The mobile terminal device and pachislot 1 constitute a gaming system that is an embodiment of the present invention.

In the above description, an example in which the sub-control circuit 42 (the sub-CPU 81 of the sub-CPU 81) performs the binarization process on a predetermined area excluding the rectangular cut-out symbols (position detection patterns) at the three corners has been described. However, instead of this, the target of binarization processing may be the entire QR code including the rectangular clipped symbols at the three corners.

[Polling command]
Next, polling commands will be described with reference to FIG. FIG. 16 is a diagram for explaining polling commands.
The polling command is sent from the sub-control circuit 42 to the sub-liquid crystal unit 200 at regular intervals (for example, every 200 msec) when it is desired to inquire whether the sub-liquid crystal unit 200 is active.

The polling command consists of STX, CRC, LEN, BLK, CNT and CMD codes. In FIG. 16, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the polling command is "04" (hexadecimal notation) indicating 4 bytes.
The value of BLK is "02" (in hexadecimal notation) when another command related to this command is transmitted next, and "00" (16 notation).

The value of CNT is the number of counts at that time.
The value of CMD is "7F" (hexadecimal notation) indicating the command ID of the polling command.

[First image display command]
Next, the first image display command will be described with reference to FIGS. 17 and 18. FIG. FIG. 17 is a diagram for explaining the first image display command. FIG. 18 is a diagram for explaining how an image is displayed based on the first image display command.
The first image display command command is transmitted from the sub-control circuit 42 to the sub-liquid crystal unit 200 when displaying an image on the sub-liquid crystal unit 200 . More specifically, a plurality of images are displayed continuously at predetermined intervals without changing the display coordinates of the reference point (the upper left corner of the image) in these images (that is, without changing the display position). will be sent when

The first image display command consists of STX, CRC, LEN, BLK, CNT, CMD, 10-byte DAT (DAT0 to DAT9), and ETX code. In FIG. 17, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the first image display command is "0E" (hexadecimal notation) indicating 14 bytes.
The value of BLK is "02" (in hexadecimal notation) when another command related to this command is transmitted next, and "00" (16 notation).

The value of CNT is the number of counts at that time.
The value of CMD is "33" (hexadecimal notation) indicating the command ID of the first image display command.

The value of DAT0,1 is the image number of the image data of the start image, which is the first image among images to be continuously displayed.
DAT2 and 3 are values of display coordinates in the X direction (horizontal direction) of the upper left corner of the starting image. Also, the values of DAT4 and 5 are the values of the display coordinates in the Y direction (vertical direction) of the upper left corner of the starting image.

The values of DAT6 and 7 are the image numbers of the image data of the final image, which is the last image among the images to be continuously displayed.
The value of DAT8 is a value indicating an image update interval, which is the timing for switching images. In this embodiment, the image update interval can be set between 10 milliseconds and 2.55 seconds.

The value of DAT9 is a value indicating whether or not there is an image update loop. Here, the image update loop is to repeat the display of these images after displaying the images from the start image to the end image. When the image update loop is performed, the value of DAT9 is "01" (hexadecimal notation) indicating presence, and when the image update loop is not performed, the value of DAT9 is "00" (hexadecimal notation) indicating no image update loop. .

When the sub liquid crystal unit 200 receives the first image display command as described above, the control LSI 201 receives a plurality of images corresponding to the image numbers from the image number of the start image to the image number of the end image in the received command. The images are sequentially displayed on the liquid crystal screen 202 at the image update interval specified by the received command. Also, the control LSI 201 matches the display coordinates of the reference point (upper left corner of the image) of the plurality of images to be sequentially displayed with the display coordinates of the start image in the received command.

Here, from the sub-control circuit 42 to the sub-liquid crystal unit 200, "01" is the image number of the start image, "0000" is the display coordinate of the start image in the X direction, "0000" is the display coordinate of the start image in the Y direction, and "0000" is the display coordinate of the end image. A display mode when the first image display command including "04" as the image number of is transmitted will be described. The same command includes "01" as the image update interval and "01" as the presence or absence of an image update loop.

Upon receiving the first image display command, the control LSI 201 of the sub-liquid crystal unit 200 reads the image data of the image number “01” of the start image from the external memory 203 . Next, as shown in FIG. 18A, the control LSI 201 sets the display coordinates of the upper left corner, which is the reference point of the image related to the read image data, to (0, 0), and causes the liquid crystal screen 202 to display it. The image with the image number “01” is an image showing the information of the upper ⅓ of the payout table.

The control LSI 201 also determines whether or not the external memory 203 stores image data of image numbers between the image number “01” of the start image and the image number “04” of the end image. For example, when the external memory 203 stores image data of image numbers "02" and "03", the control LSI 201 determines that the image data is stored. Then, as in this example, when there are a plurality of images that satisfy the determination condition, the control LSI 201 reads the image data of the image number having the smallest value, ie, "02", from the plurality of images.

After 10 milliseconds have passed since the image with the image number "01" was displayed, the control LSI 201 displays the read image with the image number "02" on the liquid crystal screen 202 as shown in FIG. 18(B). Let The control LSI 201 displays the display coordinates of the upper left corner, which is the reference point of the image with the image number "02", as (0, 0) as in the start image. The image with the image number “02” is an image showing 2/3 information of the payout table.

Also, the control LSI 201 determines whether or not the external memory 203 stores image data of image numbers between the image number “02” and the image number “04” of the end image. For example, when image data "03" is stored in the external memory 203, the control LSI 201 determines that the image data is stored, and reads the image data associated with the image number "03".

After 10 milliseconds from the display of the image with the image number "02", the control LSI 201 displays the read image with the image number "03" on the liquid crystal screen 202 as shown in FIG. 18(C). Let The control LSI 201 displays the display coordinates of the upper left corner, which is the reference point of the image with the image number "03", as (0, 0) as in the start image. The image with the image number “03” is an image showing the information of the payout table 5/6.

The control LSI 201 also determines whether or not the external memory 203 stores image data of image numbers between the image number “03” and the image number “04” of the end image. In this case, since there is no image that satisfies the conditions, the control LSI 201 determines that no image is stored, and reads the image data of image number "04", which is the end image.

After 10 milliseconds from the display of the image with the image number "03", the control LSI 201 displays the read image with the image number "04" on the liquid crystal screen 202 as shown in FIG. 18(D). Let The control LSI 201 displays the display coordinates of the upper left corner, which is the reference point of the image with the image number "04", as (0, 0) as in the start image. The image with the image number “04” is an image showing all the information of the payout table.

Each time an image is displayed on the liquid crystal screen 202, the control LSI 201 matches the image number of the displayed image with the image number (DAT6, 7) of the end image included in the received first image display command. Determine whether or not If they match, the control LSI 201 determines whether or not there is an image update loop based on the value of DAT9. In this example, when the image with the image number "04" is displayed, the image number of the displayed image matches the image number of the end image included in the received first image display command. , it is determined that there is an image update loop.

When determining that there is an image update loop, the control LSI 201 displays the image with image number "01", which is the start image, again on the liquid crystal screen 10 milliseconds after the image with image number "4", which is the end image, is displayed. 202. After that, the control LSI 201 sequentially displays the images with the image numbers "2" to "4" on the liquid crystal screen 202 every 10 milliseconds. That is, the control LSI 201 repeats displaying the images with the image numbers "01" to "04" on the liquid crystal screen 202 every 10 milliseconds.

As described above, the control LSI 201 sequentially displays the images with image numbers "01" to "04" on the liquid crystal screen 202 every 10 milliseconds, so that the player is watching flipbooks. Such an impression that the image changes with the passage of time can be given.
Further, as the display mode (effect mode) of the image based on the first image display command, for example, when the bonus is won, the characters "WIN" are displayed blinking in the center of the liquid crystal screen 202, or the ART (AT) There is a mode in which characters of "CHANCE" are displayed blinking in the center of the liquid crystal screen 202 when the game is confirmed. In these modes, DAT 0, 1 in the first image display command, in the case of bonus winning, the image number of the character image of "WIN", and in the case of finalization of the ART (AT) game, the image number related to the character image of "CHANCE". Set as the starting image number. Also, "170" is set as the display coordinate X of the start image in DATs 2 and 3, and "70" is set as the display coordinate Y of the start image in DATs 4 and 5. In addition, the image number related to the erasing image for erasing the character image of "WIN" or the character image of "CHANCE" is set in DAT6, 7 as the end image number, and "50" is set in DAT8 as the image update interval. set. This can be realized by setting DAT9 to "1" indicating that there is an image update loop.

[Second image display command]
Next, the second image display command will be described with reference to FIGS. 19 to 21. FIG. FIG. 19 is a diagram for explaining the second image display command. 20 and 21 are diagrams for explaining the display mode of the image based on the second image display command.
The second image display command is sent from the sub-control circuit 42 to the sub-liquid crystal unit 200 when displaying one image or when displaying a plurality of images at predetermined intervals on the sub-liquid crystal unit 200. .

The second image display command consists of STX, CRC, LEN, BLK, CNT, CMD, DAT (DAT0 to DAT127), and ETX codes. In FIG. 19, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the second image display command is variable according to the number of DATs, and ranges from "04" (hexadecimal notation) indicating 4 bytes to "84" (hexadecimal notation) indicating 132 bytes. Become.
The value of BLK is "02" (in hexadecimal notation) when another command related to this command is transmitted next, and "00" (16 notation).

The value of CNT is the number of counts at that time.
The value of CMD is "31" (hexadecimal notation) indicating the command ID of the second image display command.

The value of DAT0,1 is the image number of the first image to be displayed. The values of DAT2 and 3 are the display coordinate values in the X direction (horizontal direction) of the reference point (upper left corner in this embodiment) of the first image to be displayed. The values of DAT4 and 5 are the values of the display coordinates in the Y direction (vertical direction) of the reference point of the first image to be displayed.

Thereafter, when there are a plurality of images to be displayed, the data for each image continues in the same manner as DAT0 to DAT5 (image number, 6-byte data indicating display coordinate values). Note that in this embodiment, a total of 21 images can be continuously displayed with one second image display command.

The value of the second DAT from the end (DTAn*6+5 in FIG. 19) is a value indicating the image update interval, which is the timing of image switching. In this embodiment, the image update interval can be set between 10 milliseconds and 2.55 seconds.

The final DAT (DTAn*6+6 in FIG. 19) has a value indicating the presence or absence of coordinate movement. "01" (in hexadecimal notation) indicates that there is coordinate movement, and "00" (in hexadecimal notation) indicates that there is no coordinate movement. When there is no coordinate movement, the control LSI 201 displays each image based on the display coordinates of each image included in the second image display command. That is, the images are read out sequentially in the order of the DAT of this command, and the reference point (upper left corner of the image) of each image is aligned with the display coordinates of each image, and the images are continuously displayed at the image update interval included in this command. do.

On the other hand, when the coordinates are moved, the images are arranged at equal intervals based on the display coordinates of the first image and the display coordinates of the final image, which is the last image among the images to be continuously displayed. Determine the display coordinates to move with , and display it.

Specifically, the number of images to be continuously displayed is Z, the value of the display coordinate in the X direction of the first image is x1, the value of the display coordinate in the Y direction is y1, and the last image is the n-th image. Assuming that the value of the display coordinate in the X direction is xn and the value of the display coordinate in the Y direction is yn, the control LSI 201 calculates the moving distance of the reference point between the images (hereinafter sometimes referred to as "coordinate interval") by the following formula: Calculated by (1) and (2).
Coordinate interval in X direction=(xn-x1)/(z-1) Expression (1)
Coordinate interval in Y direction=(yn-y1)/(z-1) Expression (2)

Then, the control LSI 201 displays the X- and Y-direction reference points of the m-th image (between 1 and n) counted from the start image based on the calculated X-direction coordinate interval and Y-direction coordinate interval. The coordinates are calculated and determined using the following formulas (3) and (4).
Display coordinate in X direction=x1+Coordinate interval in X direction×(m−1) Expression (3)
Y-direction display coordinates=y1+Y-direction coordinate interval×(m−1) Equation (4)

When the control LSI 201 receives from the sub-control circuit 42 the second image display command including the DAT indicating that the coordinates have been moved, it identifies the number of images to be continuously displayed from the number of image numbers included in this command. Then, the display coordinates of each image are determined from the display coordinates of the start image and the end image, and are continuously displayed at the image update interval included in this command.

For example, six images shown in FIGS. 20A to 20C and FIGS. When displaying, the coordinate interval is calculated from the display coordinates of the start image shown in FIG. 20(A) and the display coordinates of the end image shown in FIG. 20(F).

If the display coordinates of the start image are (10, 10) (the value of the display coordinates in the X direction, the value of the display coordinates in the Y direction) and the display coordinates of the end image are (160, 60), the coordinate interval in the X direction is , 30 from equation (1). Also, the coordinate interval in the Y direction is 10 from equation (2).

The display coordinates of the image displayed on the second sheet shown in FIG. 20B are (40, 20) from equations (3) and (4). Similarly, the display coordinates of the third image shown in FIG. 20(C) are (70, 30), and the display coordinates of the fourth image shown in FIG. , 40). Similarly, the display coordinates of the fifth image shown in FIG. 21(E) are (130, 50).

As described above, when the control LSI 201 receives the second image display command including the DAT indicating that the coordinates have been moved, it determines the display coordinates for each image between the start image and the end image. Then, as shown in FIGS. 20 and 21, the control LSI 201 displays the reference point of each image according to the determined display coordinates at the image update interval included in this command. By doing so, the image changes with the passage of time as if the player were watching a flipbook (in FIGS. 20 and 21, the character moves from the upper left to the center of the liquid crystal screen 202). (Raise your right hand and your left hand in turn).
Based on such a second image display command, for example, when a state in which no game has been played for a certain period of time (for example, 3 minutes) or longer (no game medals have been bet) continues, images such as those shown in FIGS. 20 and 21 are displayed. By changing , it is also possible to play the role of a screen saver for the sub liquid crystal unit 200 .

The second image display command including DAT indicating the presence of coordinate movement also includes the display coordinates for each image. are used with priority.

[ACK command]
Next, the ACK command will be explained with reference to FIG. FIG. 22 is a diagram for explaining the ACK command.
The ACK command is transmitted from the sub liquid crystal unit 200 to the sub control circuit 42 .

The ACK command consists of codes of STX, CRC, LEN, BLK, CNT, CMD, DAT and ETX. In FIG. 22, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the ACK command is variable according to the number of DATs, and is a value from "06" (hexadecimal notation) indicating 6 bytes to "0E" (hexadecimal notation) indicating 14 bytes.
The value of BLK is normally "00" (hexadecimal notation) indicating the end because there is no next command related to this command.

The value of CNT is the number of counts at that time.
The value of CMD is "06" (hexadecimal notation) indicating the command ID of the ACK command.

The value of DAT differs according to the type of command received from the sub-control circuit 42 immediately before.
The DAT when the all image information request command is received from the sub-control circuit 42 consists of DAT0 to DAT9. The value of DAT0,1 is a value indicating the version of the firmware. The values of DAT2-5 are values indicating the magic code of the external memory 203. FIG. The values of DAT 6 and 7 are the maximum number of images that can be stored in the external memory 203 . The values of DAT 8 and 9 are sum values of the entire external memory 203 .

The DAT when the image checksum request command is received from the sub-control circuit 42 consists of DAT0,1. The value of DAT0,1 is the sum value of the image data to which the image number to be checked included in the received image checksum request command is assigned.

The DAT when the first image display command or the second image display command is received from the sub-control circuit 42 is composed of DAT0 and DAT1. The value of DAT0,1 is the image number of the start image included in the received first image display command or the image number of the first image included in the received second image display command.

The DAT when other commands are received from the sub-control circuit 42 consists of DAT0,1. The values of DAT0 and 1 are fixed dummy data "0000" (hexadecimal notation).

[NAK command]
Next, the NAK command will be explained with reference to FIG. FIG. 23 is a diagram for explaining the NAK command.
The NAK command is sent from the sub-liquid crystal unit 200 to the sub-control circuit 42 when an error occurs, for example, when the command sent from the sub-control circuit 42 cannot be received normally, or when the command sent is processed. Sent when the

The NAK command consists of codes of STX, CRC, LEN, BLK, CNT, CMD, DAT and ETX. In FIG. 23, illustration of STX, CRC, and ETX is omitted.

The value of LEN in the NAK command is "06" (hexadecimal notation) indicating 6 bytes.
The value of BLK is normally "00" (hexadecimal notation) indicating the end because there is no next command related to this command.

The value of CNT is the number of counts at that time.
The value of CMD is "15" (hexadecimal notation) indicating the command ID of the NAK command.

The DAT consists of DAT0,1. The value of DAT0 is a value indicating the number of consecutive NAK command transmissions.
The value of DAT1 is a value corresponding to the type of error that has occurred, as shown in FIG. For example, "0B" (hexadecimal notation) is a value indicating an image size error. The image size error corresponds to an error due to the size of an image related to display exceeding the size of the liquid crystal screen 202 or an error in which the image size is 0 in the X direction/Y direction.

<ACK/NAK command transmission timing>
Next, ACK/NAK command transmission timing will be described with reference to FIGS. 24 and 25 are timing charts showing the transmission timing of ACK/NAK commands when image display related commands are received. FIG. 26 is a timing chart showing transmission timing of ACK/NAK commands when a QR request command is received.

In the sub-liquid crystal unit 200 according to the present embodiment, when an image display-related command, that is, a first image display command or a second image display command is received from the sub-control circuit 42, the command can be received normally, and An ACK command is sent when the DMA transfer is successful.

When an image display command is received from the sub-control circuit 42, the host controller 210 of the control LSI 201 in the sub-liquid crystal unit 200 first performs command consistency determination (receive (determines whether received data is error-free or corrupted).

If it is determined to be normal in consistency determination, the host controller 210 issues a transfer instruction to the DMAC 215 as indicated by "transfer successful" in FIG. After instructing the transfer, the host controller 210 monitors the status of the DMAC 215 and detects whether the DMA transfer has been completed normally or abnormally. In addition, the host controller 210 can execute other processing such as reception interrupt and timer interrupt processing in parallel with this status monitoring.

Upon receiving the transfer instruction, the DMAC 215 reads the image data associated with the received command from the external memory 203 and performs DMA transfer to transfer the image data to the image recognition DSP 212 . When the DMA transfer ends normally, the fact is reflected in the status of the DMAC 215 . The host controller 210 transmits an ACK command to the sub-control circuit 42 when the status of the DMAC 215 reflects that the DMA transfer has ended normally.

On the other hand, as indicated by "abnormal reception" in FIG. 24, when the host controller 210 detects an error when receiving an image display command from the sub-control circuit 42, that is, as a result of consistency determination, the received data When an abnormality is detected, a NAK command is transmitted to the sub-control circuit 42 at that timing.

Also, as indicated by "transfer failure" in FIG. 24, when the host controller 210 determines that the consistency is normal, and after instructing the transfer to the DMAC 215, some abnormality (for example, noise on the bus) occurs in the DMA transfer. , the status of the DMAC 215 is set to abnormal. When the host controller 210 detects that the status of the DMAC 215 is set to abnormal, the host controller 210 transmits a NAK command to the sub-control circuit 42 at this timing to initialize the DMAC 215 .

Also, as indicated by "no response for 0.5 seconds or longer" in FIG. , the ACK or NAK command cannot be received from the sub-liquid crystal unit 200 even after a predetermined time (0.5 seconds in this embodiment) has elapsed since the image display command was transmitted. In this case, the sub-control circuit 42 retransmits the previously transmitted image display system command.

When the sub-liquid crystal unit 200 receives the resent image display-related command, the host controller 210 performs consistency determination. When the host controller 210 determines that the transfer is normal, the host controller 210 cancels the transfer instruction based on the previously transmitted command and instructs the DMAC 215 to transfer based on the retransmitted command if the status of the DMAC 215 indicates that the transfer is in progress. When the status of the DMAC 215 reflects that the DMA transfer has ended normally, the host controller 210 transmits an ACK command to the sub-control circuit 42 .

The transmission timing of the ACK command will be explained in more detail. As shown in FIG. 25, when the sub liquid crystal unit 200 receives an image display command for continuously displaying a plurality of images from the sub control circuit 42, the host controller 210 changes the status of the DMAC 215 to the start image. Alternatively, an ACK command is transmitted to the sub-control circuit 42 at the timing reflecting that the DMA transfer of the image data of the first image has been completed normally.

Next, the transmission timing of the ACK/NAK command when the QR request command is received will be described.
FIG. 26 shows an example in which the QR request command is transmitted multiple times because the QR data is 128 bytes or more. When the sub-liquid crystal unit 200 receives the first (initial) QR request command from the sub-control circuit 42, the host controller 210 determines the consistency of the command (received command) by cyclic redundancy check using the CRC code included in the received command. (determines whether received data is error-free or corrupted).

In the consistency determination, if the match is determined to be normal, the host controller 210 transmits an ACK command to the sub control circuit 42 at that timing. The host controller 210 determines whether the received QR request command is the first QR request command, and whether the value of the BLK code of the received command is "01" (hexadecimal notation) indicating continuation. to judge.

After receiving the ACK command, the sub-control circuit 42 transmits the subsequent QR request command.
When the sub-liquid crystal unit 200 receives the last (last) QR request command from the sub-control circuit 42, the host controller 210 performs consistency determination, and if it determines that it is normal, it instructs the DMAC 215 to transfer. This transfer instruction instructs the DMAC 215 to perform DMA transfer for transferring all the QR data contained in the QR request commands received up to that point and stored in the SRAM 213 to the image recognition DSP 212 . The host controller 210 checks whether the received QR request command is the last QR request command, and whether the value of the BLK code of the received command is other than "01" (hexadecimal notation) indicating continuation. Judge whether or not.

DMAC215 which received the transfer instruction|indication reads all the QR data which concerns on the QR request command received from SRAM213, and performs DMA transfer which transfers to image recognition DSP212. When the DMA transfer ends normally, the fact is reflected in the status of the DMAC 215 . The host controller 210 transmits an ACK command to the sub-control circuit 42 when the status of the DMAC 215 reflects that the DMA transfer has ended normally.

Although illustration is omitted, since the QR data does not exceed 128 bytes, if the QR request command can be transmitted only once, the value of the BLK code of the command is "00" (hexadecimal notation) indicating the end Therefore, as in the case of receiving the last (final) QR request command described above, when the status of the DMAC 215 reflects that the DMA transfer has been successfully completed, the host controller 210 issues an ACK command to the sub-controller. Send to circuit 42 .

In addition, when the host controller 210 detects an error when receiving the QR request command from the sub-control circuit 42 (for example, when an abnormality is detected in consistency determination), or when there is some abnormality in the DMA transfer (for example, when the bus The transmission timing of NAK when "noise is added" occurs is the same as the mode described in "abnormal reception" and "failure in transfer" in FIG. 24, so the description is omitted here.
When the sub-control circuit 42 receives a NAK command, or when it cannot receive an ACK or NAK command after a predetermined period of time has passed, it resends the previously transmitted command, but the value of DAT0 of the NAK command indicates. , if the number of consecutive transmissions of the NAK command exceeds a predetermined number (for example, 128 times), it is determined that some abnormality has occurred in the sub liquid crystal unit 200 and the transmitted command cannot be processed normally, Retransmission may be canceled.

<Description of the operation of the main control circuit>
Next, with reference to FIG. 27, the contents of various processes executed by the main CPU 51 of the main control circuit 41 using programs will be described.

[Main Pachislot Operation Process Controlled by Main CPU]
First, the procedure of the main operation processing of pachi-slot 1 under the control of the main CPU 51 will be described with reference to the main flow chart (hereinafter referred to as main flow) shown in FIG.

First, when the pachi-slot machine 1 is powered on, the main CPU 51 performs an initialization process when the power is turned on (S1). In this initialization process, it is determined whether the backup has been performed normally, whether the setting has been changed appropriately, etc., and the initialization corresponding to the determination result is performed.

Next, the main CPU 51 performs initialization processing when one game ends (S2). In this initialization process, the data in the designated storage area in the main RAM 53 is cleared. The designated storage area referred to here is, for example, a storage area such as an internal winning combination storage area or a display combination storage area, the data of which needs to be erased for each game.

Next, the main CPU 51 performs medal acceptance/start check processing (S3). In this process, the inputs of the medal sensor 35S and the start switch 16S are checked.
Specifically, the main CPU 51 counts the number of medals inserted by automatic insertion when a display combination related to a replay (replay combination) is established in the previous game, and counts the number of medals inserted from the medal slot 13. , and counting the number of inserted coins based on the pressing of the BET buttons (MAXBET, 1BET), etc., and when the number of inserted coins has reached the game-startable number, the state of the start switch is determined.

Next, the main CPU 51 extracts a random number value (0 to 65535) and stores the extracted random number value in a random number storage area (not shown) provided in the main RAM 53 (S4). Next, the main CPU 51 extracts an effect random number value used in reel effect and lock control, and stores the extracted effect random number value in an effect random value storage area (not shown) provided in the main RAM 53 ( S5). In this embodiment, the random number for effect is extracted from the range of 0-127.

When the extracted random number values are stored in a predetermined random number storage area, the main CPU 51 performs an internal lottery process (S6). In this process, an internal winning combination is determined by lottery based on the random numbers extracted in S4.

Next, the main CPU 51 performs game lock lottery processing (S7).
In the game lock lottery process, a game lock lottery table (not shown) corresponding to the game state is referred to, and a game lock lottery is performed based on the effect random number value.

Next, the main CPU 51 performs reel stop initialization processing (S8).
The reel stop initial setting process acquires various information related to reel stop control from a reel stop initial setting table (not shown) based on the internal winning combination.

Next, the main CPU 51 performs start command transmission processing (S9). Specifically, the main CPU 51 transmits a start command to the sub control circuit 42 . The start command includes a parameter specifying an internal winning combination and the like, a game lock type, a lock time, and the like.

Next, the main CPU 51 performs wait processing (S10). In this process, if a predetermined time (for example, 4.1 seconds) has not passed since the start of the previous game, the main CPU 51 consumes the waiting time until the predetermined time elapses.

Next, the main CPU 51 performs reel rotation start processing (S11). In this process, the main CPU 51 requests the start of rotation of all reels.
The reel rotation start process requests the start of rotation of all reels. When the start of rotation of all reels is requested, the driving of the three stepping motors 61L, 61C, 61R is controlled by an interrupt process (see FIG. 28) which is executed at a constant cycle (1.1172 msec). The rotation of the left reel 3L, middle reel 3C and right reel 3R is started.

Next, the main CPU 51 performs attraction priority storage processing (S12). In this process, the main CPU 51 acquires attraction priority data and stores it in an attraction priority data storage area (not shown).

Next, the main CPU 51 performs reel stop control processing (S13). In this process, the rotation of the relevant reel is stopped based on the timing at which the left stop button 17L, the middle stop button 17C and the right stop button 17R are pressed and the internal winning combination. Also, the main CPU 51 transmits a reel stop command to the sub-control circuit 42 . The reel stop command transmitted in this process includes information such as the type of reel to be stopped, the symbol position when the stop switch is turned on, and the number of sliding symbols until the reel stops.

Next, the main CPU 51 performs game lock processing (S14). In this process, the main CPU 51 nullifies or delays the progress of the game.
The main CPU 51 sets a value corresponding to the period during which the determined game lock type is executed in the lock timer, and waits until the value of the lock timer becomes "0". During that time, the player's stop operation is not accepted.

Next, the main CPU 51 performs winning search processing (S15). In this process, the main CPU 51 stores the data in the symbol code storage area (not shown) in the display combination storage area (not shown). Also, in this process, after all the left reel 3L, the middle reel 3C and the right reel 3R are stopped, the combination of symbols displayed on the effective line (win determination line) is collated with a symbol combination table (not shown). Then, the main CPU 51 may determine whether or not a display combination is displayed on the activated line, and store the determination result in the display combination storage area.

Next, the main CPU 51 performs medal payout processing (S16). The medal payout process represents a specific example of the game medium provision means according to the present invention. In this process, the hopper 33 is driven and the number of credits is updated based on the number of payouts for the display combination determined in S15, and medals are paid out. At this time, in this embodiment, as shown in the symbol combination table (not shown), the number of inserted medals is 1 to 3, and the number of paid out medals varies depending on the display combination. The payout upper limit) is 15 sheets.

Next, the main CPU 51 performs RT control processing (S17). In this process, the main CPU 51 manages the RT gaming state.
The main CPU 51 refers to an RT transition table (not shown), checks the RT game state transition conditions that can be established in the transition source (current) RT game state, and determines that the RT game state transition conditions are satisfied. When it is determined, an RT transition table (not shown) is referred to, and based on the transition conditions, transition is made to the RT game state of the transition destination. Also, the main CPU 51 transmits a display command to the sub-control circuit 42 . The display command includes parameters for specifying the display combination, the number of payouts, and the like.

Next, the main CPU 51 performs payout end command transmission processing (S18). Specifically, the main CPU 51 transmits a payout end command to the sub-control circuit 42 .

Next, the main CPU 51 performs bonus end check processing (S19). In this process, the main CPU 51 refers to various counters for managing the trigger for ending the bonus game, and checks whether or not to end the operation of the bonus game.

Next, the main CPU 51 performs bonus activation check processing (S20). In this process, the main CPU 51 checks whether or not to start the operation of the bonus game and whether or not to play again. When the bonus operation check process ends, the main CPU 51 returns the process to S2, and repeats the processes after S2.

[Interrupt processing under control of main CPU (1.1172 msec)]
Next, with reference to FIG. 28, interrupt processing performed at regular intervals (every 1.1172 msec) under the control of a timer (not shown) incorporated in the main CPU 51 will be described.

First, the main CPU 51 saves the register (S351). Next, the main CPU 51 performs input port check processing (S352). In this process, signals input from various switches such as the stop switch 17S are checked.

Next, the main CPU 51 performs timer update processing (S353). In this process, the main CPU 51 performs, for example, a process of subtracting the value of the lock timer for each interrupt process. Next, the main CPU 51 performs communication data transmission processing (S354). In this process, various commands are mainly sent to the sub-control circuit 42 as appropriate. A no-operation command, which will be described later, is a command sent to the sub-control circuit 42 when various commands such as a start command have not been sent to the sub-control circuit 42 .

Next, the main CPU 51 performs reel control processing (S355). In this process, the main CPU 51 starts rotating the left reel 3L, the middle reel 3C and the right reel 3R when it is requested to start rotating all the reels, and then rotates the reels at a constant speed. It drives and controls the three stepping motors 61L, 61C and 61R. Also, when the number of sliding symbols is determined, the main CPU 51 updates the symbol counter of the corresponding reel by the number of sliding symbols. Then, the main CPU 51 waits for the updated symbol counter to match the value corresponding to the expected stop position (the symbol at the expected stop position reaches the area on the effective line (win determination line) of the display window). , drives and controls the corresponding stepping motor so that the rotation of the relevant reel is decelerated and stopped. In addition, in the present embodiment, in the processing of S355, in addition to the above-described normal acceleration processing, constant speed processing, and stop processing, if a reel performance pattern is set during acceleration processing, it corresponds to the reel performance pattern. It also performs reel performance (reel action) and lock control processing.

Next, the main CPU 51 performs lamp/7 segment drive processing (S356). In this process, the main CPU 51 drives and controls the 7-segment display 6 to display the number of payouts, the number of credits, and the like. Next, the main CPU 51 performs register restoration processing (S357). After that, the main CPU 51 terminates the interrupt processing.

<Description of the operation of the sub-control circuit>
Next, contents of various processes (tasks) executed by the sub CPU 81 of the sub control circuit 42 using programs will be described with reference to FIGS. 29 to 33. FIG.

[Main board communication task]
First, the main board communication task performed by the sub CPU 81 will be described with reference to FIG.

First, the sub CPU 81 performs reception check of a command transmitted from the main control circuit 41 (S501). Next, when receiving a command, the sub CPU 81 extracts the type of the received command (S502).

Next, the sub CPU 81 determines whether or not a command different from the previous one has been received (S503). In S503, when the sub CPU 81 determines that a command different from the previous one has not been received (when the determination in S503 is NO), the sub CPU 81 returns the process to S501, and repeats the processes after S501.

On the other hand, when the sub CPU 81 determines in S503 that a command different from the previous one has been received (if determined as YES in S503), the sub CPU 81 stores a message in the message queue based on the received command (S504 ). A message queue is a mechanism for exchanging information between processes. After the process of S504, the sub CPU 81 returns the process to S501 and repeats the processes after S501.

[Production registration task]
Next, the effect registration task performed by the sub CPU 81 will be described with reference to FIG.

First, the sub CPU 81 retrieves a message from the message queue (S511). Next, the sub CPU 81 determines whether or not there is a message in the message queue (S512). When the sub CPU 81 determines in S512 that there is no message in the message queue (when S512 determines NO), the sub CPU 81 performs the processing of S515, which will be described later.

On the other hand, when the sub CPU 81 determines in S512 that there is a message in the message queue (when S512 determines YES), the sub CPU 81 copies game information from the message (S513). In this process, for example, various data such as the internal winning combination, the type of reel whose rotation has stopped, the display combination, and the game state flag specified by the parameters are copied to a storage area (not shown) provided in the sub-RAM 83. be.

Next, the sub CPU 81 performs effect content determination processing (S514). In this process, the sub CPU 81 determines the contents of the effect, selects the effect data, etc. according to the type of the received command. Details of the effect content determination process will be described later with reference to FIG. 31, which will be described later.

Next, the sub CPU 81 registers sound data (S515). Next, the sub CPU 81 registers the LED data (S516). These registration processes are performed based on the effect data selected in the effect content determination process of S514. channels, etc.), lamp pattern data (LED effect data), and various parameters (brightness, etc.) related to patterns are registered. Although not shown, the sub CPU 81 also registers effect data related to the sub liquid crystal unit 200 linked to the selected effect data and various parameters related thereto. Further, after the effect data related to the sub liquid crystal unit 200 and various parameters related thereto are registered, the sub CPU 81 executes an image control task at a predetermined timing, and executes a first image display command according to the registered effect data and parameters. Alternatively, it transmits the second image display command to the sub liquid crystal unit 200 . After S516, the sub CPU 81 returns the process to S511 and repeats the processes after S511. In addition to the above example, when a predetermined operation is performed on various devices (for example, the enter button 21 and the select button 22) to be operated by the player, the sub CPU 81 A one-image display command or a second image display command is transmitted to the sub liquid crystal unit 200 .

[Production content determination process]
Next, with reference to FIG. 31, the effect content determination process performed at S514 in the flow chart of the effect registration task (see FIG. 30) will be described.

First, the sub CPU 81 determines whether or not it is time to receive a start command (S521).

In S521, when the sub CPU 81 determines that it is time to receive the start command (if determined as YES in S521), the sub CPU 81 performs processing when receiving the start command (S522). In this process, the sub CPU 81 extracts a random value for effect, determines the effect number by lottery based on the internal winning combination, game state, RT state, etc., and stores it. Here, the effect number is data specifying the content of the effect to be executed this time.

Next, the sub CPU 81 selects the effect data at the start according to the stored effect number (S523). The performance data is data specifying sound data and LED data. Therefore, when the effect data is registered, the corresponding LED data and the like are determined, and the effect such as display by the light-emitting display device 11 is executed. After the process of S523, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

On the other hand, when the sub CPU 81 determines in S521 that the start command has not been received (NO in S521), the sub CPU 81 determines whether or not the reel stop command has been received (S524).

In S524, when the sub CPU 81 determines that it is time to receive the reel stop command (if determined as YES in S524), the sub CPU 81 determines the time of stopping according to the stored effect number and the type of the operation stop button. Effect data is selected (S525). Thereafter, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

On the other hand, when the sub CPU 81 determines in S524 that the reel stop command has not been received (NO in S524), the sub CPU 81 determines whether or not the display command has been received (S526).

In S526, when the sub CPU 81 determines that it is time to receive the display command (if determined as YES in S526), the sub CPU 81 selects the effect data of the display combination according to the stored effect number and display combination. do. Thereafter, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

On the other hand, when it is determined in S526 that the display command is not received (NO determination in S526), the sub CPU 81 determines whether or not the payout end command is received (S528). In S528, when the sub CPU 81 determines that it is time to receive the payout end command (if the determination in S528 is YES), the sub CPU 81 performs payout end command reception processing (S529). Thereafter, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

On the other hand, when the sub CPU 81 determines in S528 that the payout end command has not been received (NO in S528), the sub CPU 81 determines whether or not the bonus start command has been received (S530).

In S530, when the sub CPU 81 determines that it is time to receive the bonus start command (if determined as YES in S530), the sub CPU 81 selects effect data for starting the bonus (S531). Thereafter, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

On the other hand, when the sub CPU 81 determines in S530 that the bonus start command has not been received (NO in S530), the sub CPU 81 determines whether or not the bonus end command has been received (S532). In S532, when the sub CPU 81 determines that it is time to receive the bonus end command (if determined as YES in S532), the sub CPU 81 selects effect data for ending the bonus (S533). Thereafter, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

When the sub CPU 81 determines in S532 that the bonus end command has not been received (NO in S532), the sub CPU 81 determines whether or not the no-operation command has been received (S534). In S534, when the sub CPU 81 determines that it is not time to receive the no-operation command (when the determination in S534 is NO), the sub CPU 81 ends the effect content determination process, and performs the process as part of the effect registration task (see FIG. 30). Move to S515.

On the other hand, when the sub CPU 81 determines in S534 that it is time to receive a no-operation command (if determined as YES in S534), the sub CPU 81 performs processing when no-operation command is received (S535). After the process of S535, the sub CPU 81 ends the effect content determination process, and shifts the process to S515 of the effect registration task (see FIG. 30).

[Sound control task]
Next, the sound control task performed by the sub CPU 81 will be described with reference to FIG.

First, the sub CPU 81 retrieves the sound data registered in S515 (see FIG. 30) of the effect registration task (S581). This sound data is data for driving and controlling the speakers 20L and 20R (see FIG. 1) during a certain period. Next, the sub CPU 81 determines whether or not there is registered sound data (S582).

When the sub CPU 81 determines in S582 that there is registered sound data (when S582 determines YES), the sub CPU 81 creates sound control data according to the sound data (S583). After that, the sub CPU 81 performs the process of S585, which will be described later.

When the sub CPU 81 determines in S582 that there is no registered sound data (NO determination in S582), the sub CPU 81 creates update sound control data (S584).

When the sub CPU 81 determines that there is registered sound data, it turns off the registered sound data flag to eliminate the registered sound data. Therefore, when the registered sound data is extracted, the sub CPU 81 determines that there is registered sound data, and thereafter determines that there is no registered sound data until a certain period of time has passed.

The sound control data is data for driving and controlling the speakers 20L and 20R for each predetermined cycle. That is, the sub CPU 81 creates sound control data by dividing sound data, which is data for driving and controlling the speakers 20L and 20R in a certain period, for each predetermined period.

After the processing of S583 or S584, the sub CPU 81 determines whether or not the sound being reproduced is loop reproduction and cue reproduction (S585). In S585, when the sub CPU 81 determines that the sound being reproduced is loop reproduction and cue reproduction (when S585 determines YES), the sub CPU 81 adds 1 to the loop counter of the sound management information ( S586).

In S585, when the sub CPU 81 determines that the sound being played back is loop playback and not cue playback (when S585 determines NO), or after the processing of S586, the sub CPU 81 starts the sound control data transmission processing. It does (S587). After the process of S587, the sub CPU 81 returns the process to S581, and repeats the processes after S581.

[LED control task]
Next, the LED control task performed by the sub CPU 81 will be described with reference to FIG.

First, the sub CPU 81 takes out the LED data registered in S516 (see FIG. 30) of the effect registration task (S601). This LED data is data for driving and controlling the light source unit associated with each port (337 ports) in a certain period. Next, the sub CPU 81 determines whether or not there is registered LED data (S602).

When the sub CPU 81 determines in S602 that there is registered LED data (when S602 determines YES), the sub CPU 81 creates LED control data according to the LED data (S603). After that, the sub CPU 81 performs the processing of S605, which will be described later.

When the sub CPU 81 determines that there is registered LED data, it turns off the registered LED data flag to eliminate the registered LED data. Therefore, when the registered LED data is extracted, the sub CPU 81 determines that there is registered LED data, and then determines that there is no registered LED data until a certain period of time has passed.

The LED control data indicates a specific example of the effect control data according to the present invention, and is data for driving and controlling the light source unit associated with each port for each predetermined cycle. That is, the sub CPU 81 creates LED control data by dividing the LED data, which is data for driving and controlling the light source unit associated with each port in a certain period, for each predetermined cycle.

On the other hand, when the sub CPU 81 determines in S602 that there is no registered LED data (NO determination in S602), the sub CPU 81 creates LED control data for updating (S604).

After the process of S603 or S604, the sub CPU 81 acquires the value of the loop counter from the sound management information (S605). Next, the sub CPU 81 determines whether or not the loop counter has been incremented (S606).

In S606, when the sub CPU 81 determines that the loop counter has been incremented (when S606 determines YES), the sub CPU 81 interrupts the LED (lamp) effect being executed and creates LED control data for cueing. (S607).

When the sub CPU 81 determines in S606 that the loop counter has not been incremented (NO determination in S606), or after the processing of S607, the sub CPU 81 sets the check counter to 337 (S608).

Next, the sub CPU 81 determines whether or not the check counter is 0 (S609). When determining in S609 that the check counter is 0 (when S609 determines YES), the sub CPU 81 returns the process to S601, and repeats the processes after S601.

On the other hand, when determining in S609 that the check counter is not 0 (NO determination in S609), the sub CPU 81 subtracts 1 from the value of the check counter (S610). Next, the sub CPU 81 determines whether or not there is a change in the LED control data (S611). That is, it is determined whether or not there is a difference (change) between the LED control data created this time and the LED control data created last time.

When the sub CPU 81 determines in S611 that there is no change in the LED control data (NO determination in S611), the sub CPU 81 returns the process to S609 and repeats the processes after S609. On the other hand, when the sub CPU 81 determines in S611 that there is a change in the LED control data (when the determination in S611 is YES), the sub CPU 81 determines the difference between the LED control data created this time and the LED control data created last time. Based on this, difference data is created (S612).

That is, the sub CPU 81 determines whether or not there is a change in the LED control data corresponding to the light source unit associated with each port (337 port), and only when there is a change in the LED control data, the difference data with respect to the previous data. create. This difference data represents one specific example of effect execution data according to the present invention.

Next, the sub CPU 81 performs transmission processing of the difference data created in S612 (S613). After that, the sub CPU 81 returns the process to S609 and repeats the processes after S609. Therefore, when there is a change in the LED control data, the sub CPU 81 transmits the difference data to each substrate 121, 127, 128, 129 (see FIG. 6), and 119 is turned on or off.

<Action>
In the pachi-slot machine 1 of this embodiment, the sub-liquid crystal unit 200 that receives the QR request command including the QR code data based on the door opening/closing history from the sub-control circuit 42 displays the QR code on the liquid crystal screen 202 . For example, the administrator of the pachislot machine 1 can check the door opening/closing history data with the portable terminal device by reading it with the above-described portable terminal device. Therefore, regardless of the size of the liquid crystal screen 202, the administrator can easily check the door opening/closing history with the portable terminal device.

Also, the sub-control circuit 42 transmits binarized data (binarized data) of the created QR code in the QR request command. Also, the control LSI 201 of the sub-liquid crystal unit 200 restores the binarized data of the QR code contained in the received QR request command and displays the QR code. Therefore, the communication load between the sub-control circuit 42 and the sub-liquid crystal unit 200 can be reduced as compared with the case where the sub-control circuit 42 transmits the QR code as it is the image data.

In addition, the sub-control circuit 42 performs the binarization process on the area excluding the rectangular cutout symbols (position detection pattern) at the three corners of the QR code. Therefore, the communication load between the sub-control circuit 42 and the sub-liquid crystal unit 200 can be further reduced.

In addition, in the pachi-slot machine 1 of the present embodiment, the sub liquid crystal unit 200 continuously displays images on the liquid crystal screen 202 based on the first image display command or the second image display command, thereby providing the player with a flipping image. It is possible to give an impression that the image changes with the passage of time, just like watching a cartoon, and enhance the production effect. Since such continuous display of images can be handled by a low-performance liquid crystal display device, a high-performance liquid crystal display device is not required. Therefore, the development cost and manufacturing cost can be suppressed, and an efficient and highly effective performance can be achieved. In addition, when displaying images continuously, the exchange of commands between the sub-control circuit 42 and the sub-liquid crystal unit 200 is compared with the case where a command requesting the display of each image is required. becomes less meaningful. Therefore, more efficient and highly effective production can be achieved.

Further, when the sub-liquid crystal unit 200 receives the second image display command with coordinate movement, the display coordinates of the first image and the display coordinates of the final image, which is the last image among the continuously displayed images, are displayed. Then, the display coordinates are determined so that the images in between are moved at equal intervals, and displayed. Therefore, it is possible to give the player the impression that the image moves smoothly, thereby enhancing the effect of presentation.

Further, in the pachislot machine 1 of the present embodiment, when the sub liquid crystal unit 200 receives an image display command, that is, the first image display command or the second image display command from the sub control circuit 42, the command can be received normally. And, when the DMA transfer (at least for the start image or the first image) related to the command is successful, the ACK command is transmitted. Therefore, transfer omission can be suppressed.

<Modification>
In the above embodiment, a specific example of the pachislot 1 was shown, but there may be a pachinko machine, a parrot that is a pachislot machine that uses game balls, an enclosed game machine that circulates enclosed game media, a mahball game machine, or the like. may be applied to other types of gaming machines.

Also, in the above embodiment, the manner in which the sub-control circuit 42 creates the QR code has been described. However, instead of this, the sub-control circuit 42 may transmit the door opening/closing history data to the sub liquid crystal unit 200, and the QR code may be created based on the door opening/closing history data received by the sub liquid crystal unit 200.

The value of DAT in this case will be described with reference to FIG. FIG. 34 is a diagram for explaining a QR request command according to a modification; FIG. 34 shows only the DAT in the QR request command according to the modification. Other codes are the same as those in the above-described embodiment, so descriptions thereof are omitted here.

The values of DAT0 to 4 are the values of the display coordinates (DAT0 to 3) of the QR code and the QR magnification (DAT4), as in the above embodiment.

The value of DAT5 is a value indicating a decode level (error correction level, one of L, M, Q and H) preset in the sub ROM 82 or stored in the SRAM 213 .
DAT6 to DAT127 are values indicating text data of door opening/closing history data, for example, "20180918 1030 OPEN". Although illustration is omitted, if the data related to the QR code exceeds 128 bytes, the QR request command will be transmitted continuously, but the value of DAT0 to 127 of the second and subsequent QR request commands are all text data of the door opening/closing history data.
In the above description, the manner in which the text data of the door opening/closing history data is set in DAT0-127 has been described. Alternatively, the text data may be converted into binary data, set in DAT 0 to 127 of the QR request command, and transmitted to the sub liquid crystal unit 200 .

When the sub-liquid crystal unit 200 receives the last (last) QR request command from the sub-control circuit 42, the host controller 210 performs consistency determination, and if it determines that it is normal, it instructs the DMAC 215 to transfer. This transfer instruction instructs the DMAC 215 to perform DMA transfer for transferring all the QR data contained in the QR request commands received up to that point and stored in the SRAM 213 to the image recognition DSP 212 .

DMAC215 which received the transfer instruction|indication reads all the QR data which concerns on the QR request command received from SRAM213, and performs DMA transfer which transfers to image recognition DSP212. When the DMA transfer ends normally, the image recognition DSP 212 creates a QR code based on all the QR data transferred by DMA, and displays it on the liquid crystal screen 202 .

Specifically, the image recognition DSP 212 first determines the version of the QR code to any one of 1 to 40 from the capacity of the text data in the QR data and the decoding level. Next, the text data is QR coded with the determined version to create a QR code. Then, the created QR code is displayed on the liquid crystal screen 202 at the display coordinates and magnification in the QR data.

<Summary>
Among gaming machines, there are known gaming machines that do not have a liquid crystal display device for effects (see, for example, Japanese Patent Laid-Open No. 2017-169812) and gaming machines that do not have a high-performance liquid crystal display device.
Further, a technique of monitoring the opening and closing of the door of the gaming machine and storing the history of opening and closing is disclosed in order to monitor fraudulent acts on the gaming machine (see, for example, Japanese Unexamined Patent Application Publication No. 2005-342020).

However, it is difficult to check the opening/closing history in a game machine equipped with a liquid crystal display device having a relatively small display screen and not having high functionality.

SUMMARY OF THE INVENTION The present invention has been made to solve the first problem described above, and a first object of the present invention is to provide a game machine and a game machine capable of easily confirming the opening/closing history in consideration of the actual situation of the above-mentioned prior art. It is to provide a system.

In order to solve the above first problem, the present invention provides a first gaming machine having the following configuration.

a game machine main body (for example, an exterior body 2 described later);
a front door (for example, a front door 2b to be described later) attached to the game machine main body so as to be opened and closed;
an opening/closing monitoring unit (for example, a sub-door monitoring switch to be described later) for monitoring opening/closing of the game machine main body and the front door;
a display unit (for example, a sub-liquid crystal unit 200 to be described later) arranged at a predetermined position of the front door;
a control unit (for example, a sub-control circuit 42 to be described later) connected to the opening/closing monitoring unit and the display unit and for controlling the opening/closing monitoring unit and the display unit;
The control unit
an opening/closing state recording means (for example, a sub RAM 83 described later) for recording information about the opening/closing state of the front door;
two-dimensional code conversion means (for example, a sub CPU 81 to be described later) that converts information on the open/close state of the front door recorded by the open/close state recording means into a two-dimensional code;
Binary information conversion means (for example, a sub CPU 81 to be described later) for converting the two-dimensional code converted by the two-dimensional code conversion means into binary information;
a display unit transmission unit (for example, a sub CPU 81 described later) that transmits the binary information converted by the binary information conversion unit to the display unit;
The display unit
Having an image display means (for example, a liquid crystal screen 202 described later) for displaying an image in the display area,
A gaming machine, wherein the binarized information transmitted by the display unit transmission means is converted into a two-dimensional code, and the converted two-dimensional code is displayed in the display area of the image display means.

Further, in order to solve the first problem, the present invention provides a first gaming system having the following configuration.

A gaming system comprising the gaming machine and a mobile terminal device,
The mobile terminal device
A gaming system, wherein the two-dimensional code displayed on the display unit is read, and information regarding the open/closed state of the front door is displayed based on the read two-dimensional code.

Further, in order to solve the above first problem, the present invention provides a second gaming machine having the following configuration.

a game machine main body (for example, an exterior body 2 described later);
a front door (for example, a front door 2b to be described later) attached to the game machine main body so as to be opened and closed;
an opening/closing monitoring unit (for example, a sub-door monitoring switch to be described later) for monitoring opening/closing of the game machine main body and the front door;
a display unit (for example, a sub-liquid crystal unit 200 to be described later) arranged at a predetermined position of the front door;
a control unit (for example, a sub-control circuit 42 to be described later) connected to the opening/closing monitoring unit and the display unit and for controlling the opening/closing monitoring unit and the display unit;
The control unit
an opening/closing state recording means (for example, a sub RAM 83 described later) for recording information about the opening/closing state of the front door;
a two-dimensional code conversion means (for example, a sub CPU 81 described later) that converts the information on the open/close state of the front door recorded by the open/close state recording means into a two-dimensional code including a position detection pattern;
Binary information conversion means (for example, a sub CPU 81 to be described later) for converting a portion of the two-dimensional code converted by the two-dimensional code conversion means, excluding the position detection pattern, into binary information;
a display unit transmission unit (for example, a sub CPU 81 described later) that transmits the binary information converted by the binary information conversion unit to the display unit;
The display unit
Having an image display means (for example, a liquid crystal screen 202 described later) for displaying an image in the display area,
converting into a two-dimensional code including a position detection pattern based on the binarized information transmitted by the display section transmitting means, and displaying the converted two-dimensional code in the display area of the image display means; Characteristic game machine.

Also, in order to solve the first problem, the present invention provides a second game system having the following configuration.

A gaming system comprising the gaming machine and a mobile terminal device,
The mobile terminal device
A game system characterized by: inputting the two-dimensional code displayed on the display unit, and displaying information about the opening/closing state of the front door based on the input two-dimensional code.

According to the first and second game machines and the first and second game systems, it is possible to confirm information about the open/closed state of the front door with the portable terminal device that reads the two-dimensional code displayed on the display unit. Therefore, regardless of the size of the display screen of the display unit installed in the game machine, the opening/closing history can be easily confirmed.

By the way, among game machines, there is known a game machine that is not equipped with a liquid crystal display device (see, for example, Japanese Patent Application Laid-Open No. 2017-169812).

However, a game machine without a liquid crystal display device has a problem of poor performance. On the other hand, a gaming machine equipped with a high-performance large-screen liquid crystal display device capable of performing various effects has the problem of increased development costs and manufacturing costs.

SUMMARY OF THE INVENTION The present invention has been made to solve the second problem, and an object of the present invention is to provide a game machine capable of efficiently and highly effective presentation in consideration of the actual situation of the conventional technology. It is in.

In order to solve the above second problem, the present invention provides a third gaming machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and instructs the display unit to display an image,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
Display control means (for example, a control LSI 201 described later) that controls the display of the display means;
an image storage means (for example, an external memory 203 to be described later) for storing a plurality of images with image numbers;
The control unit
When instructing the display unit to display a plurality of images in succession, a first image number that is an image number related to the image to be displayed first, a last image number that is an image number to designate the image to be displayed last, and transmitting a display command (for example, a first image display command to be described later) including interval designation data that designates a display interval to the display unit,
The display control means is
When the display unit receives the display command, the images assigned with the image numbers from the first image number to the last image number are sequentially read out from the image storage means, and the images specified by the interval designation data of the display command are read out. A gaming machine characterized by displaying on the display means at display intervals.

Also, in order to solve the second problem, the present invention provides a fourth gaming machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and instructs the display unit to display an image,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
Display control means (for example, a control LSI 201 described later) that controls the display of the display means;
an image storage means (for example, an external memory 203 to be described later) for storing a plurality of images with image numbers;
The control unit
When instructing the display unit to display a plurality of images in succession, a first image number that is an image number related to the image to be displayed first, a last image number that is an image number to designate the image to be displayed last, sending a display command (for example, a first image display command described later) including interval designation data designating a display interval and loop data indicating whether or not there is a loop instruction to the display unit;
The display control means is
When the display unit receives the display command, the images assigned with the image numbers from the first image number to the last image number are sequentially read out from the image storage means, and the images specified by the interval designation data of the display command are read out. performing display processing for displaying on the display means at display intervals;
A gaming machine, wherein the display processing is repeated when the loop data indicates that there is a loop.

Further, in order to solve the second problem, the present invention provides a fifth gaming machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and instructs the display unit to display an image,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
Display control means (for example, a control LSI 201 described later) that controls the display of the display means;
an image storage means (for example, an external memory 203 to be described later) for storing a plurality of images with image numbers;
The control unit
When instructing the display unit to display a plurality of images in succession, the image number of each image, the display coordinates indicating the position of each image on the display means, and the interval designation data for designating the display interval. Sending a display command (for example, a second image display command without coordinate movement described later) to the display unit,
The display control means is
When the display unit receives the display command, the images to which the image numbers included in the display command are assigned are sequentially read out from the image storage means, and displayed at intervals specified by the interval specification data of the display command. A gaming machine, wherein an image is displayed on the display means based on the display coordinates of the image.

Also, in order to solve the second problem, the present invention provides a sixth game machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and instructs the display unit to display an image,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
Display control means (for example, a control LSI 201 described later) that controls the display of the display means;
an image storage means (for example, an external memory 203 to be described later) for storing a plurality of images with image numbers;
The control unit
When instructing the display unit to display a plurality of images consecutively in a predetermined order, an initial display indicating the image number of each image and the position on the display means of the first image, which is the first image to be displayed. coordinates, last display coordinates indicating the position on the display means of the last image which is the image to be displayed last, and display commands including interval designation data for designating display intervals (for example, a second image with coordinate movement, which will be described later). display command) to the display unit;
The display control means is
When the display unit receives the display command, the display coordinates indicating the position on the display means of each image to be displayed between the first image and the last image are determined based on the first display coordinates and the last display coordinates. death,
A game characterized in that the images to which the image numbers included in the display command are attached are sequentially read out from the image storage means and displayed on the display means at display intervals designated by the interval designation data of the display command. machine.

Further, in order to solve the second problem, the present invention provides a seventh game machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and instructs the display unit to display an image,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
Display control means (for example, a control LSI 201 described later) that controls the display of the display means;
an image storage means (for example, an external memory 203 to be described later) for storing a plurality of images with image numbers;
The control unit
When instructing the display unit to display a plurality of images consecutively in a predetermined order, an initial display indicating the image number of each image and the position on the display means of the first image, which is the first image to be displayed. coordinates, last display coordinates indicating the position on the display means of the last image which is the image to be displayed last, and display commands including interval designation data for designating display intervals (for example, a second image with coordinate movement, which will be described later). display command) to the display unit;
The display control means is
when the display unit receives the display command, display coordinates indicating positions on the display means of each image to be displayed between the first image and the last image based on the first display coordinates and the last display coordinates, determining that the image moves between the first display coordinates and the last display coordinates at equal intervals;
A game characterized in that the images to which the image numbers included in the display command are attached are sequentially read out from the image storage means and displayed on the display means at display intervals designated by the interval designation data of the display command. machine.

According to the third to seventh game machines, by continuously displaying images, the player is given the impression that the images change with the passage of time, as if he or she is watching a flipbook, and the production effect is achieved. can increase Since such continuous display of images can be performed even with a low-performance liquid crystal display device, a high-performance liquid crystal display device is not required. Therefore, the development cost and manufacturing cost can be suppressed, and an efficient and highly effective performance can be achieved. Further, when displaying images continuously, exchange of commands between the control unit and the display unit is relatively small compared to the case where a command requesting image display is required for each image. Therefore, an efficient and highly effective performance can be achieved.

By the way, among game machines, there is disclosed a game machine provided with a display control device that receives a command from a main control device and performs DMA transfer to the VDP (see, for example, Japanese Unexamined Patent Application Publication No. 2005-160828).

However, in the game machine described above, although commands from the main control unit can be normally received, if an error occurs during DMA transfer, the DMA transfer may not be completed normally, resulting in transfer omission. there were.

The present invention has been made to solve the third problem described above, and an object of the present invention is to provide a game machine capable of suppressing transfer omissions in consideration of the actual situation of the above-described conventional technology.

In order to solve the third problem, the present invention provides an eighth gaming machine having the following configuration.

a display unit (for example, a sub-liquid crystal unit 200 described later);
A control unit (for example, a sub-control circuit 42 described later) that is connected to the display unit and transmits an instruction command for instructing the display unit to display an image,
The display unit
display means for displaying an image (for example, a liquid crystal screen 202 described later);
an image control means (for example, an image recognition DSP 212 described later) that controls the display of an image by the display means;
image storage means for storing a plurality of images (for example, an external memory 203 to be described later);
a transfer control means (for example, a DMAC 215 described later) that performs a transfer process of reading an image from the image storage means and transferring the image to the image control means;
Display control means (for example, a host controller 210 described later) connected to the image control means and the transfer control means,
When the instruction command is received, the display control means performs a consistency determination process for determining consistency of the received instruction command, causes the transfer control means to perform the transfer process for an image to be displayed,
monitoring whether the transfer process by the transfer control means has been completed normally;
A game characterized by making it possible to request the control unit to resend the instruction command when the result of the consistency determination process is abnormal or when the transfer process does not end normally. machine.

According to the eighth game machine, when the result of the consistency determination process is abnormal, or when the transfer process is not completed normally, the controller is requested to resend the instruction command, so that the transfer omission is prevented. can be suppressed.

DESCRIPTION OF SYMBOLS 1... Pachislot (gaming machine) 2... Exterior body 2a... Cabinet 2b... Front door 3L... Left reel 3C... Middle reel 3R... Right reel 4L... Display window 4C... Middle display window 4R... Right display window 31 Main board 32 Sub board 41 Main control circuit 42 Sub control circuit 51 Main CPU 81 Sub CPU 101 Upper display section 102 Reel lighting section 103 Reel side effect display units 103A, 103B Reel side effect display units 104A, 104B Edge effect display units 105 Lower reel display units 106 Waist panel display units 111 First LED group 112 Second LED group , 113... Third LED group, 114... Fourth LED group, 115... Fifth LED group, 116... Sixth LED group, 117... Seventh LED group, 118... Eighth LED group, 119... Dot matrix section, 121... Upper display LED board , 127 7SEG drive board 128 LED drive board 129 matrix drive board 200 sub liquid crystal unit 201 control LSI 202 liquid crystal screen 203 external memory 210 host controller 211 Video output circuit 212 Image recognition DSP 213 SRAM 214 Flash memory 215 DMAC 216 SPI 217 UART

Claims (1)

a display unit;
a control unit connected to the display unit and transmitting a plurality of types of instruction commands to the display unit;
The display unit
display means for displaying an image;
an image control means for controlling display of an image by the display means;
an image storage means in which a plurality of images are stored in advance;
a transfer control means for performing a transfer process of reading an image from the image storage means and transferring the image to the image control means;
a display control means connected to the image control means and the transfer control means;
The display control means is
consistency determination means for determining consistency of the instruction based on the type of the received instruction;
when the type of the received instruction command is related to an image, causing the transfer control means to perform the transfer processing of the image corresponding to the instruction command from among the plurality of images stored in the image storage means. a transfer processing means for causing
a transfer process monitoring means for monitoring whether or not the transfer process by the transfer control means has been completed normally;
reply command transmission means for transmitting a reply command according to the judgment result of the consistency judgment means or the monitoring result of the transfer process monitoring means to the control unit;
The types of the reply command include a normal reply command and an abnormal reply command,
The normal reply command has a different data length depending on the type of the instruction command received,
The reply command for the time of abnormality has the same data length regardless of the type of the instruction command received, and the reply command for the time of abnormality includes the number of times the reply command for the time of abnormality is continuously transmitted. and abnormal contents.

Images