JP7233141B2 - playground - Google Patents

Description

The present invention relates to amusement machines typified by reel game machines (slot machines) and pinball game machines (pachinko machines).

Conventionally, there is a game machine that executes a pseudo-game separately from the main game (for example, Patent Document 1).

JP 2016-36477 A

Conventional game machines have room for improvement in light emitting means.

SUMMARY OF THE INVENTION An object of the present invention is to provide a game machine characterized by light-emitting means.

According to the invention,
light emitting means;
a movable body unit having a first movable body operable by being driven by a first motor;
a main control board that controls the progress of the game;
A game machine comprising
The movable body unit has a third movable body operable by being driven by a third motor,
The first motor is electrically connected to the light emitting means via a first harness,
The third motor is electrically connected to the light emitting means via a third harness,
When the first motor is driven by manually operating the first movable body in a power-off state, a current generated by the back electromotive force generated by the first motor flows into the light-emitting means. may emit light,
When the third motor is driven by manually operating the third movable body in a power-off state, a current due to a back electromotive force generated by the third motor flows into the light emitting means. may emit light,
The light emitting means does not move even when the first motor is driven, and does not move when the third motor is driven,
The light emitting means is provided above the movable unit,
The light emitting means is provided on the main control board,
There is provided a game machine characterized by:

According to the present invention, it is possible to provide a game machine having a characteristic light-emitting means.

1 is an external perspective view of the slot machine 100 viewed from the front side (player side). FIG. It is a figure which shows an example of a winning line. 3 is an external perspective view showing a reel rotating device 185 of the slot machine 100. FIG. (a) is an exploded perspective view of the reel drive unit 25, and (b) is an LED arrangement diagram of a plurality of reel backlights 94 attached to the lighting base 90. FIG. It is a circuit block diagram of a control part. FIG. 10 is a diagram showing an arrangement of symbols applied to each reel in a planar development; FIG. 10 is a diagram showing types of winning combinations (including working combinations), symbol combinations corresponding to each winning combination, and payouts for each winning combination. FIG. 10 is a diagram showing a lottery table for internal winning combinations for each RT; 4 is a transition diagram of a game state (RT) of the slot machine 100. FIG. FIG. 10 is a diagram showing the transition of the game state regarding the advantageous section and the non-advantageous section of the slot machine 100; 4 is a flow chart showing a flow of main processing of a main controller; 7 is a flow chart showing the flow of main control unit timer interrupt processing; 11. It is a flowchart which shows the flow of pseudo-game related processing (step S109) in FIG. It is a flow chart showing the flow of the pseudo-game reel rotation start process (step S1003) in FIG. It is a flow chart showing the flow of the pseudo-game reel stop control process (step S1005) in FIG. FIG. 12 is a flowchart showing a flow of reel rotation start processing (step S113) in FIG. 11; FIG. FIG. 17 is a flow chart showing the flow of the 7-segment setting process (step S1305) in FIG. 16; FIG. 17 is a flow chart showing the flow of random delay rotation start processing (step S1311) in FIG. 16. FIG. (a) is a flowchart of the main processing executed by the CPU 404 of the first sub-controller 400, (b) is a flowchart of the command reception interrupt processing of the first sub-controller 400, and (c) is 4 is a flow chart of timer interrupt processing of the first sub-controller 400. FIG. (a) is a flowchart of the main processing executed by the CPU 504 of the second sub-controller 500, (b) is a flowchart of the command reception interrupt processing of the second sub-controller 500, and (c) is 10 is a flowchart of timer interrupt processing of the second sub-controller 500, and (d) is a flowchart of image control processing of the second sub-controller 500. FIG. It is a diagram showing an example of the operation of the pseudo-game of the embodiment. It is a figure which shows the pseudo-game lamp 190. FIG. (a) to (c) are diagrams showing an example of a pseudo stop. (a) to (c) are diagrams showing an example of a pseudo stop. (a) and (b) are diagrams showing examples of effects in a pseudo-game. (a) and (b) are diagrams showing examples of effects in a pseudo-game. (a) and (b) are diagrams showing examples of effects in a pseudo-game. (a) and (b) are diagrams showing examples of effects in a pseudo-game. (a) to (c) are diagrams showing examples of effects at the time of power failure and power recovery. (a) and (b) are diagrams showing an example of a pseudo-game. (a) and (b) are diagrams showing an example of a pseudo-game. (a) and (b) are diagrams showing an example of a pseudo-game. (a) and (b) are diagrams showing an example of a pseudo-game. It is a diagram showing an example of a pseudo-game. It is a diagram showing an example of a pseudo-game. It is a diagram showing an example of a pseudo-game. It is a diagram showing an example of a pseudo-game. FIG. 2 is a front view showing the slot machine 100 with its front door open, showing how the front door 102 of the slot machine 100 in a power-off state is opened and the left reel 110 is manually rotated. It is a figure which shows the connection example of each board|substrate and each unit. (a) is a perspective view of the hopper unit 180 shown in FIG. 38 as viewed obliquely from above, and (b) is a diagram showing how the hopper disc 182 is manually rotated. 40 is a diagram showing an example in which a relay board is provided between the main control board 300B shown in FIG. 39 and the hopper unit 180 and reel unit 700 also shown in FIG. 39. FIG.

A slot machine according to an embodiment of the gaming machine of the present invention will be described below with reference to the drawings.

In the slot machine of the present embodiment described below, a predetermined number of game media are inserted, and a plurality of reels each having a plurality of types of symbols are started to rotate when a predetermined rotation start instruction operation is received. At the same time, based on the reception of the rotation start instruction operation, the propriety of internal winning of a plurality of types of combinations is determined by lottery, and each of the plurality of reels receives a predetermined rotation stop instruction operation to individually rotate. If the condition determined by the winning combination based on the result of the lottery and the combination of symbols when the plurality of reels are stopped meets the predetermined payout condition, the game medium is paid out and the game ends. This is a game machine that progresses a series of games ending without paying out game media.

First, the basic configuration of the slot machine 100 will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is an external perspective view of the slot machine 100 viewed from the front side (player side). FIG. 2 is a diagram showing an example of winning lines.

The slot machine 100 shown in FIG. 1 corresponds to an example of the game table of the present invention, and includes a main body 101 and a front door 102 attached to the front side of the main body 101 and capable of being opened and closed with respect to the main body 101. Prepare. Three reels (a left reel 110, a middle reel 111, and a right reel 112) each having a plurality of patterns arranged on its outer peripheral surface are housed in the center of the main body 101 (not shown), and rotate inside the slot machine 100. configured to allow These reels 110 to 112 are rotationally driven by a driving device such as a stepping motor.

In this embodiment, an appropriate number of patterns are printed on strip-shaped members at equal intervals, and the strip-shaped members are attached to a predetermined circular cylindrical frame member to form reels 110 to 112 . As for the symbols on the reels 110 to 112, when viewed from the player, approximately three symbols are displayed in the vertical direction from the display window 113, so that a total of nine symbols can be seen. Specifically, with reference to FIG. 2, the symbols displayed on the upper row of the left reel 110 (position 1 shown in the drawing) are displayed on the left reel upper row symbols and the middle row of the left reel 110 (position 2 shown in the drawing). The symbol to be displayed is the left reel middle symbol, the symbol displayed on the lower stage of the left reel 110 (position 3 shown in the figure) is the left reel lower stage symbol, and the symbol displayed on the upper stage of the middle reel 111 (position 4 shown in the figure) is displayed. The symbol is the upper symbol of the middle reel, the symbol displayed on the middle stage of the left reel 111 (position 5 shown in the figure) is the middle reel symbol, and the symbol displayed on the lower stage of the middle reel 111 (position 6 shown in the figure) is the symbol. The bottom symbol of the middle reel, the top symbol of the right reel 112 (position 7 in the drawing) is the top symbol of the right reel, and the right reel 112 is the top symbol of the right reel 112 (position 8 in the figure). The symbols displayed on the middle row and the bottom row of the right reel 112 (the position of 9 shown in the figure) are called the right reel bottom row symbols, respectively, and the symbols on the reels 110 to 112 are displayed on the reels 110 to 112 through the display window 113. Three of each are displayed in the vertical direction, and a total of nine are displayed. By rotating the reels 110 to 112, the combination of symbols seen by the player changes. In other words, each of the reels 110 to 112 functions as a display device that variably displays a combination of a plurality of types of symbols. As such a display device, an electronic image display device such as a liquid crystal display device can be employed in addition to the reel. In addition, in the present embodiment, three reels are provided inside the central part of the slot machine 100, but the number of reels and the installation position of the reels are not limited to this.

A backlight (see FIG. 4, which will be described later) for illuminating each pattern displayed in the display window 113 is arranged on the back surface of each of the reels 110 to 112 . The backlight is desirably shielded for each pattern so that the individual patterns can be illuminated evenly. In the slot machine 100, near each reel 110 to 112, there is provided an optical sensor (not shown) consisting of a light projecting portion and a light receiving portion. A light-shielding piece of a certain length provided on the reel passes through the space between them. Based on the detection result of the optical sensor, the positions of the symbols on the reels in the rotational direction are determined, and the reels 110 to 112 are stopped so that the desired symbols are displayed on the winning line.

The winning line display lamp 120 is a lamp that indicates a valid winning line. The winning line is a line on which it is determined whether or not a combination of symbols corresponding to a winning combination, which will be described later with reference to FIG. 7, is displayed. Only one middle prize line L1 composed of reel middle symbols is provided. FIG. 2 shows this winning line L1. A valid winning line (hereinafter sometimes simply referred to as “valid line”) is determined in advance by the number of medals bet as game media. The slot machine 100 shown in FIG. 1 requires three medals, and when the number of inserted medals is less than three, none of the winning lines are activated. validate. When the winning line becomes valid, the game can be started by operating the start lever 135 . Note that the number of winning lines is not limited to one line. For example, in addition to the middle winning line L1, a right-down winning line composed of left reel upper symbols, middle reel middle symbols, and right reel lower symbols, or composed of left reel lower symbols, middle reel middle symbols, and right reel upper symbols. A total of 3 lines of the rising right pay lines may be set as valid pay lines, or the number of pay lines corresponding to the number of bets may be set as valid pay lines. Incidentally, the area on the winning line L1 (the area consisting of numbers 2, 5 and 8 in FIG. 2) may be referred to as an active line area S1. Also, the area other than the effective line area S1 of the pattern display window 113 (the area consisting of numbers 1, 3, 4, 6, 7 and 9 in FIG. 2) may be referred to as the non-effective line area S2.

The notification lamp 123 indicates, for example, that a specific winning combination (specifically, a special combination 1, a special combination 2) has been internally elected in an internal lottery to be described later, or a special combination internal winning state or special game to be described later. It is a lamp that informs the player of the status. The game medal insertable lamp 124 is a lamp for notifying that the player can insert game medals. The replay lamp 122 indicates that the current game can be replayed (no need to insert medals) when a replay combination (details will be described later), which is one of the winning combinations in the previous game, is won. ) is a lamp that informs the player. The reel panel lamp 128 is a lamp for effect.

The bet buttons 130 to 132 are buttons for inserting a predetermined number of medals (referred to as credits) electronically stored in the slot machine 100 . In this embodiment, one card is inserted each time the bet button 130 is pressed, two cards are inserted when the bet button 131 is pressed, and three cards are inserted when the bet button 132 is pressed. (up to 3 cards). The bet button 132 is hereinafter also referred to as a MAX bet button. The game medal insertion lamp 129 turns on the number of lamps corresponding to the number of inserted medals, and when the specified number of medals is inserted, the game starts to indicate that the game start operation is possible. Lamp 121 lights up.

The medal insertion slot 141 is an insertion slot for the player to insert medals when starting a game. That is, medals can be inserted electronically using the bet buttons 130 to 132, or actual medals can be inserted (insertion operation) from the medal insertion slot 141, and "insertion" includes both. be.

The stored number display 125 is a display for displaying the number of medals electronically stored in the slot machine 100 . The game information display 126 is a display for displaying various internal information (for example, the number of medals to be paid out during the special game state) numerically. The payout number display 127 is a display for displaying the number of medals to be paid out to the player as a result of winning a winning combination. In the following description, it may be expressed as “given to the player” in the same sense as “payout to the player”. In this embodiment, the accumulated number display 125, the game information display 126, and the payout number display 127 are composed of 7-segment (SEG) displays. Although not shown in FIG. 1, an advantageous zone lamp 191 is provided at the bottom right of the payout number indicator 127 to indicate that the advantageous zone is in progress (FIG. 33(b)). Note that the payout number indicator 127 and the advantageous section lamp 191 are arranged on the same substrate. This payout number display 127 corresponds to an example of operation navigation executing means. Also, the advantageous section lamp 191 corresponds to an example of advantageous section notification executing means.

The start lever 135 is a lever-type switch for starting rotation of the reels 110-112. That is, when a desired number of medals is inserted into the medal slot 141 or the bet buttons 130-132 are operated to operate the start lever 135, the reels 110-112 start rotating. An operation on the start lever 135 is called a game start operation.

The stop button unit 136 is provided with stop buttons 137 to 139 composed of a left stop button 137, a middle stop button 138 and a right stop button 139. As shown in FIG. The stop buttons 137-139 are button-type switches for individually stopping the reels 110-112 that have started rotating by operating the start lever 135, and are associated with the respective reels 110-112. More specifically, the left reel 110 can be stopped by operating the left stop button 137, the middle reel 111 can be stopped by operating the middle stop button 138, and the right stop button 139 can be stopped. By operating it, the right reel 112 can be stopped. Hereinafter, the operation of the stop buttons 137 to 139 is called stop operation, the first stop operation is called first stop operation, the next stop operation is called second stop operation, and the last stop operation is called third stop operation. Also, the reels that are stopped in response to these stop operations will be referred to as a first stop reel, a second stop reel, and a third stop reel, respectively. Further, the order in which the stop buttons 137 to 139 are stopped in order to stop all the rotating reels 110 to 112 is referred to as an operation order or a pressing order. Furthermore, the operation order in which the first stop operation is the stop operation of the left reel 110 is called "forward push operation order" or simply "forward push", and the stop operation in which the first stop operation is the stop operation of the right reel 112 is called " called "reverse push operation sequence" or simply "reverse push". A light emitter may be provided inside each of the stop buttons 137 to 139, and when the stop buttons 137 to 139 can be operated, the light emitter can be lit to inform the player.

The medal return button 133 is a button that is pressed to remove medals when the inserted medals are jammed. The settlement button 134 is a button for settlement of medals electronically stored in the slot machine 100 and medals placed on the slot machine 100 and ejecting the medals from the medal payout port 155 . The door key hole 140 is a hole into which a key for unlocking the front door 102 of the slot machine 100 is inserted.

A chance button 165 and a selection confirmation button 166 are provided between the bet button 132 and the medal slot 141 . The chance button 165 incorporates a performance lamp, and the selection confirmation button 166 incorporates a performance lamp. The chance button 165 is operation means operated by the player during the presentation. A left button 167 is provided on the left side of the selection confirmation button 166, and a right button 168 is provided on the right side thereof. By operating the left button 167 and the right button 168, there are cases where the cursor displayed on the effect image display device 157 can be moved. can.

Below the stop button unit 136, a title panel 162 is provided for displaying the model name and attaching various certificate stamps. A medal payout port 155 and a medal tray 161 are provided below the title panel 162 .

The sound hole 145 is a hole for outputting the sound of the speaker 277 (see FIG. 5) provided below inside the slot machine 100 to the outside. The side lamps 144 provided on the left and right portions of the front door 102 are decorative lamps for enlivening the game. A production device 160 is arranged above the front door 102. Above the production device 160, the sound of a speaker 272 (see FIG. 5) provided inside the slot machine 100 is output to the outside. A sound hole 143 is provided for this purpose. The production device 160 includes a shutter (shielding device) 163 consisting of two right and left shutters 163a and 163b that can be opened and closed in the horizontal direction, and a production image display device 157 (liquid crystal display device) disposed behind the shutter 163. When the right shutter 163a and the left shutter 163b open horizontally in front of the effect image display device 157, the display screen of the effect image display device 157 is displayed in front of the slot machine 100 (player side, front side). ). It should be noted that any display device other than the liquid crystal display device may be used as long as it is capable of displaying various effect images and various game information. , a reel (drum), or a display device comprising a projector and a screen. Also, the display screen has a rectangular shape, and the entirety of the screen is configured to be visible to the player. Although the display screen is rectangular in this embodiment, it may be square. In addition, a decoration (not shown) may be provided on the periphery of the display screen so that a part of the periphery of the display screen is hidden by the decoration, so that the display screen looks oddly shaped. Although the display screen is a flat surface in this embodiment, it may be a curved surface.

Although not shown in FIG. 1, a pseudo game lamp 190 indicating that a pseudo game is in progress is provided at the upper right portion of the effect device 160 (FIG. 22).

<Reel rotating device>
Next, the reel rotating device 185 for rotating the reels 110 to 112 of the slot machine 100 will be described in detail with reference to FIGS. 3 and 4. FIG.

FIG. 3 is an external perspective view showing the reel rotating device 185 of the slot machine 100. As shown in FIG. The reel rotation device 185 is generally composed of reel drive units 25, 26 and 27 and a case member 221 for housing them. The reel drive units 25, 26 and 27 are structurally made up of the same parts, with the only difference being the arrangement of patterns printed on the reel band 30 (see FIG. 6, which will be described later). Each of the reel drive units 25, 26 and 27 (because of the same configuration, the reel drive unit 25 will be described below) is individually detachably housed in the case member 221. As shown in FIG.

4A is an exploded perspective view of the reel driving unit 25. FIG. The reel driving unit 25 is composed of the mounting base 13, the sensor bracket 14, the stepping motor 20, the sensor 80, and the reel 110 composed of the belt-shaped member 30, the reel frame 40, the detection piece 50, and the reinforcing rim . It also has an illumination base 90 composed of a plurality of reel backlights 94 for illuminating the pattern from behind. An attachment member for attaching the illumination base 90 to the reel driving unit 25 is also provided, but is omitted in the figure. Further, the lighting base 90 is provided not only in the reel drive unit 25 but also in the reel drive units 26 and 27, and a plurality of reel backlights 94 are provided for each of them.

The mounting base 13 has a sensor bracket 14 and a stepping motor 20 formed on a flat plate. The sensor bracket 14 is mounted on the mounting base 13, and a sensor 80 for detecting the passage of the detection piece 50, which will be described later, is attached to the tip.

The stepping motor 20 is, for example, a four-phase type motor having a resolution of about 252 steps per rotation and is driven by a 1-2 phase excitation method. Therefore, one rotation can be controlled with 504 pulses, and the rotation angle can be controlled with 0.7 degrees/pulse.

A reel frame 40 is attached to the rotating shaft of the stepping motor 20 . The reel frame 40 includes a boss portion 42 attached to the rotating shaft of the stepping motor 20, a rim portion 44 to which the band-shaped member 30 is attached, and four connecting portions 43 for connecting the boss portion 42 and the rim portion 44. consists of With such a configuration, the weight of the reel frame 40 is reduced, and the load on the stepping motor 20 is reduced. The connecting portion 43 further has a screw hole 48 which is open for attaching the detection piece 50 with a screw 60 .

A band-shaped member 30 is adhered around the rim portion 44 of the reel frame 40 . At the same time, a reinforcing rim 70 is adhered to the opposite end of the strip-shaped member 30 for the purpose of reinforcing the strip-shaped member 30 .

The main control unit 300 detects the rotation of each reel based on the detection result of a sensor (index sensor) 80 that detects an index (detection piece 50) provided on each reel, and when each reel stops. In the case, the stop position of each rotating reel (symbol position displayed on the reel) is specified. Further, the main control section 300 transmits information regarding symbol positions displayed on the reels to the first sub-control section 400 .

A plurality of reel backlights 94 are composed of LEDs and are attached to the illumination base 90 . By turning on all the reel backlights 94 out of the plurality of reel backlights 94, all the symbols on the symbol display window 113 can be illuminated from behind. Also, by turning on some of the reel backlights 94, some of the patterns on the pattern display window 113 can be illuminated from behind. In this manner, the plurality of reel backlights 94 illuminate the patterns on the reels 110 to 112 from the back side toward the player side.

FIG. 4(b) is an LED layout diagram of a plurality of reel backlights 94 attached to the illumination base 90. FIG. More specifically, the plurality of reel backlights 94 are LED-01 and LED-02 that illuminate the upper position of the pattern display window 113, LED-03 and LED-04 that illuminate the middle position of the pattern display window 113, and a pattern display. It has LED-05 and LED-06 that illuminate the lower position of the window 113 . Therefore, in this embodiment, it is possible to control the lighting of the reels 110 to 112 for each of the upper, middle, and lower stages. In order to distinguish the backlight 94 of each reel 110-112, the LEDs 01-06 that illuminate the left reel 110 are denoted as LED-L01-L06, and the LEDs 01-06 that illuminate the middle reel 111 are denoted as LED-C01-C06. , and the LEDs 01 to 06 that illuminate the right reel 112 are denoted by LED-R01 to R06.

<Circuit Configuration of Control Unit>
Next, the circuit configuration of the control section of the slot machine 100 will be described in detail with reference to FIG. This figure shows a circuit block diagram of the control section.

The control unit of the slot machine 100 can be roughly divided into a main control unit 300 that controls the progress of a game, and a command signal (hereinafter simply referred to as “command”) transmitted by the main control unit 300. and a second sub-controller 500 that controls various devices based on commands sent from the first sub-controller 400 . Here, regarding the main control unit 300, if the data volume becomes large, it becomes difficult to confirm the program, and there is a problem of security deterioration such as becoming a hotbed for unauthorized modification. and the data capacity of the RAM 308 is limited.

<Main control part>
First, the main controller 300 of the slot machine 100 will be described. The main control unit 300 includes a basic circuit 302 that controls the entire main control unit 300. This basic circuit 302 includes a CPU 304, control program data, lottery data used in internal lottery for winning combinations, and reel patterns. A ROM 306 storing arrays, stop positions, etc., a RAM 308 for temporarily storing data, an I/O 310 for controlling input/output of various devices, and a counter timer 312 for measuring time, number of times, etc. and a WDT (watchdog timer) 314 are mounted. Note that other storage devices may be used for the ROM 306 and RAM 308, and this also applies to the first sub-controller 400 and the second sub-controller 500, which will be described later. The CPU 304 of the basic circuit 302 operates by inputting a clock signal having a predetermined cycle output from the crystal oscillator 315b as a system clock. Furthermore, when the power is turned on, the CPU 304 transmits data for frequency division stored in a predetermined area of the ROM 306 to the counter timer 312, and the counter timer 312 calculates an interrupt time based on the received data for frequency division. It determines and transmits an interrupt request to the CPU 304 for each interrupt time. The CPU 304 uses this interrupt request as a trigger to monitor each sensor and transmit drive pulses. For example, when the clock signal output from the crystal oscillator 315b is set to 8 MHz, the frequency division value of the counter timer 312 is set to 1/256, and the data for frequency division of the ROM 306 is set to 47, the interrupt reference time is 256×47÷8 MHz. = 1.504 ms.

The main control unit 300 includes a random number generation circuit 316 that is used as a hardware random number counter that varies the numerical value in the range of 0 to 65535 based on the clock signal input from the crystal oscillator 315a, and a start signal when the power is turned on. A start signal output circuit 338 that outputs (reset signal) is provided, and the CPU 304 starts game control when the start signal is input from the start signal output circuit 338 (main control unit main processing described later). Start).

In addition, the main control unit 300 has a sensor circuit 320, and the CPU 304 detects various sensors 318 (bet button 130 sensor, bet button 131 sensor, bet button 132 sensor, medal insertion slot 141) at each interrupt time. Medal reception sensor for medals, start lever 135 sensor, left stop button 137 sensor, middle stop button 138 sensor, right stop button 139 sensor, checkout button 134 sensor, medal payout sensor for medals paid out from hopper unit 180, reels 110-112 (index sensor 80, etc.).

When the sensor circuit 320 detects the H level of the start lever sensor, it outputs a signal indicating this detection to the random number generation circuit 316 . The random number generating circuit 316 that receives this signal latches the value at that timing and stores it in a register that stores the random number used for the lottery.

Two medal reception sensors are installed in the internal passage of the medal insertion slot 141, and detect the presence or absence of passage of medals. Two start lever 135 sensors are installed inside the start lever 135 and detect the start operation by the player. The left stop button 137 sensor, the middle stop button 138 sensor, and the right stop button 139 sensor are installed on the corresponding stop buttons 137 to 139, respectively, and detect the operation of the stop button by the player.

The bet button 130 sensor, the bet button 131 sensor, and the bet button 132 sensor are installed on the corresponding bet buttons 130 to 132, respectively, and the medals electronically stored in the RAM 308 are used as the medals to be inserted into the game. Detects the submit operation when submitting. The settlement button 134 sensor is provided on the settlement button 134 . When the settlement button 134 is pressed once, the electronically stored medals are settled. The medal payout sensor is a sensor for detecting medals paid out by the hopper unit 180 . Each sensor described above may be a non-contact type sensor or a contact type sensor.

The optical sensor (index sensor 80) of the reels 110 to 112 is installed at a predetermined position on the mounting base of each reel 110 to 112, and each time the light shielding piece (detection piece 50) provided on the reel frame passes, L become a level. Rotational position information indicating how much the reel rotates from the reference position from when it once goes to L level until it goes to L level again is calculated based on the value obtained by counting the clock signal output from the crystal oscillator 315b. be done. When the CPU 304 detects the L level signal, the CPU 304 determines that the reel has made one rotation, and resets the rotational position information of the reel to zero. This rotational position information is stored in the RAM 308 of the main control unit 300 .

The main control unit 300 includes a drive circuit 322 for driving the stepping motors provided on the reels 110 to 112, a drive circuit 324 for driving the solenoid provided in the medal selector 170 for sorting the inserted medals, and a motor provided in the hopper unit 180. , various lamps 336 (winning line display lamp 120, notification lamp 123, game medal insertion possible lamp 124, re-game lamp 122, game medal insertion lamp 129, game start lamp 121, accumulated number display 125 , game information display 126, payout number display 127, pseudo game lamp 190, advantageous section lamp 191).

An information output circuit 334 is connected to the basic circuit 302, and the main control section 300 outputs an information input circuit 652 provided in an external hall computer (not shown) or the like via the information output circuit 334. The game information of the machine 100 (for example, information indicating the state of the game) is output.

The main control unit 300 also includes a voltage monitoring circuit 330 that monitors the voltage value of the power supply supplied from the power management unit (not shown) to the main control unit 300. The voltage monitoring circuit 330 monitors the voltage of the power supply. If the value is less than a predetermined value (9v in this embodiment), it outputs a low voltage signal to the basic circuit 302 indicating that the voltage has dropped.

The main control section 300 also has an output interface for transmitting commands to the first sub-control section 400 and enables communication with the first sub-control section 400 . Information communication between the main control unit 300 and the first sub-control unit 400 is one-way communication, and the main control unit 300 is configured to be able to transmit signals such as commands to the first sub-control unit 400. However, the first sub-controller 400 is configured so that signals such as commands cannot be transmitted to the main controller 300 .

<Sub-controller>
Next, the first sub-controller 400 of the slot machine 100 will be described. The first sub-controller 400 receives control commands transmitted by the main controller 300 via the input interface. The first sub-controller 400 comprises a basic circuit 402 that controls the entire first sub-controller 400 based on this control command. , an I/O 410 for controlling input/output of various devices, and a counter timer 412 for measuring time, number of times, and the like. The CPU 404 of the basic circuit 402 operates by inputting a clock signal having a predetermined cycle output from the crystal oscillator 414 as a system clock. The ROM 406 stores a control program and data for controlling the entire first sub-controller 400, a lighting pattern of the backlight, data for controlling various displays, and the like.

The CPU 404 transmits data for frequency division stored in a predetermined area of the ROM 406 to the counter timer 412 via the data bus at predetermined timing. The counter timer 412 determines an interrupt time based on the received frequency division data, and transmits an interrupt request to the CPU 404 at each interrupt time. The CPU 404 controls each IC and each circuit based on the timing of this interrupt request.

A sound source IC 418 is provided in the first sub-control unit 400, and speakers 272 and 277 are provided in the sound source IC 418 via an output interface. The sound source IC 418 controls sound output from the amplifier and speakers 272 and 277 according to commands from the CPU 404 . An S-ROM (sound ROM) storing sound data is connected to the sound source IC 418 , and the sound data obtained from this ROM is amplified by an amplifier and output from the speakers 272 and 277 .

A drive circuit 422 is provided in the first sub-control unit 400, and various lamps 420 (upper lamp, lower lamp, side lamp 144, title panel lamp, bet button lamp, reel backlight 94, etc.) are connected.

Further, the first sub control unit 400 is provided with a drive circuit 424 for driving the motor of the shutter 163, and the drive circuit 424 is provided with the shutter 163 via an output interface. This drive circuit 424 outputs a drive signal to a stepping motor (not shown) provided in the shutter 163 according to a command from the CPU 404 .

A sensor circuit 426 is provided in the first sub control unit 400, and a shutter sensor 428 is connected to the sensor circuit 426 via an input interface. The CPU 404 monitors the state of the shutter sensor 428 every interrupt time. Further, the first sub-controller 400 is provided with a switch sensor 427 that detects pressing of the chance button 165 . The switch sensor 427 also detects pressing of each of the selection confirmation button 166 , the left button 167 , and the right button 168 . Detection signals from the shutter sensor 428 and switch sensor 427 are output to the basic circuit 402 by the sensor circuit 426 .

The CPU 404 also transmits and receives signals to and from the second sub-controller 500 via the output interface. The second sub-control section 500 performs various controls of the effect device 160 including display control of the effect image display device 157 . The second sub-control unit 500 includes, for example, a control unit that controls the display of the effect image display device 157, a control unit that controls various drive devices for effects (for example, a control unit that controls the motor drive of the shutter 163). ) may be configured with a plurality of control units.

The second sub-controller 500 includes a basic circuit 502 that receives control commands transmitted by the first sub-controller 400 via an input interface and controls the entire second sub-controller 500 based on the control commands. This basic circuit 502 includes a CPU 504, a RAM 508 for temporarily storing data, an I/O 510 for controlling input/output of various devices, and a counter timer for measuring time, number of times, etc. 512 and are installed. The CPU 504 of the basic circuit 502 operates by inputting a clock signal having a predetermined cycle output from the crystal oscillator 514 as a system clock. The ROM 506 stores control programs and data for controlling the entire second sub-control section 500, data for image display, and the like.

The CPU 504 transmits data for frequency division stored in a predetermined area of the ROM 506 to the counter timer 512 via the data bus at predetermined timing. The counter timer 512 determines an interrupt time based on the received frequency division data, and transmits an interrupt request to the CPU 404 at each interrupt time. The CPU 504 controls each IC and each circuit based on the timing of this interrupt request.

A VDP 516 (video display processor) is provided in the second sub-control unit 500, and a ROM 506 and a VRAM 518 are connected to the VDP 516 via a bus. The VDP 516 reads image data and the like stored in the ROM 506 based on a signal from the CPU 504 , generates a display image using the work area of the VRAM 518 , and displays the image on the effect image display device 157 .

<Pattern arrangement>
Next, with reference to FIG. 6, the pattern arrangement applied to each of the reels 110 to 112 will be described. In addition, this figure is a plan view showing the arrangement of symbols provided on each reel (the left reel 110, the middle reel 111, and the right reel 112).

On each of the reels 110 to 112, a predetermined number of symbols (20 frames numbered 0 to 19 in this embodiment) of a plurality of types (eight types in this embodiment) shown on the right side of the figure are arranged. Numbers 0 to 19 shown at the left end of the figure indicate the arrangement positions of symbols on the respective reels 110 to 112 . For example, in this embodiment, the frame numbered 18 on the left reel 110 has a "watermelon pattern", the frame numbered 0 on the middle reel 111 has a "bell pattern", and the frame numbered 17 on the right reel 112 has a "seven 1 Designs” are arranged respectively.

The slot machine 100 according to the present embodiment is configured to stop the corresponding reels 110 to 112 within the maximum retraction range (for example, less than 5 frames) from the position where the stop operation is performed, in order to improve the enjoyment of the game. there is

<Types of winning roles>
Next, the types of winning combinations of the slot machine 100 will be described with reference to FIG. This figure shows types of winning combinations (including working combinations), symbol combinations corresponding to each winning combination, and payouts (number of awards) for each winning combination.

Winning combinations of the slot machine 100 include a special combination 1, replay combinations 1-2, and small combinations 1-6. Note that the types of winning combinations are not limited to these combinations, and can be arbitrarily adopted.

Of the winning combinations in the present embodiment, the special combination 1 is a combination (actuating combination) that shifts to a special game state in which a predetermined profit is given to the player by winning. Further, replay combinations 1 and 2 are combinations that can be replayed without inserting new medals. These special roles 1 and 2 and replay roles 1 and 2 may be called "operating roles". Further, "winning" in the present embodiment includes the case where a symbol combination of an operating combination that does not involve a payout of medals (does not involve a payout of medals) is displayed on the activated line. Winning of replay hands 1 and 2 is included. The special role 1 is a special role that is carried over to the next game if it is not determined as winning, and the other roles are general roles that are not carried over to the next game if it is not determined as winning. be.

The special combination 1 is a combination (operating combination) that shifts to a special game state (RT2) by winning a prize. However, medals will not be paid out due to winning these roles themselves. The corresponding symbol combination is "seven 1-seven 1-seven 1" for special role 1. In the following description, the special role 1 may be referred to as "BB1" or "BB".

When the special combination 1 is internally won, the internal winning flag corresponding to the internally won special combination is set to ON (stored in a predetermined area of the RAM 308 of the main control unit 300). When the flag corresponding to the special combination 1 is set to ON, the main control unit 300 shifts the game state to the special combination internal winning state (RT1). This flag is maintained in the on state until the corresponding working role is won, and it becomes a state in which it is easy to win these working roles in the next and subsequent games. Specifically, even if the special role 1 is not won in the game in which the special role 1 is internally won, the same state as the special role 1 is internally won in the next and subsequent games, and the corresponding symbol combinations are all won. becomes easier.

The special role internally elected state will be described in detail later, but in the special role internally elected state, if a role other than the special role is internally elected, the symbols constituting the other role are arranged preferentially. , reel stop control is executed.

The re-playing hands 1 and 2 are prize-winning hands (operating hands) that can be played without inserting medals (game media) in the next game due to winning, and medals are not paid out. That is, the game can be played again with the same number of bets as the number of previously inserted coins. The corresponding symbol combination is "replay-replay-replay" for replay combination 1 and "replay-replay-watermelon" for replay combination 2. Among the replay hands, the replay hand 1 may be referred to as "normal replay" and the replay hand 2 may be referred to as "chance replay".

The replay hands 1 and 2 may be hands that allow the player to play the next game without inserting medals. Therefore, for example, if you win a replay, the insertion of medals in the next game may be automatically inserted (reset the number of inserted medals in the memory area for the number of inserted medals prepared in the RAM 308). The medals inserted in the winning game may be carried over to the next game and used as they are.

Small combinations 1 to 6 are winning combinations in which a predetermined number of medals are paid out upon winning. The corresponding symbol combinations are "ANY-Cherry-ANY" for the small combination 1, "Watermelon-Watermelon-Watermelon" for the small combination 2, and "Bell-Bell-Bell" for the small combination 3. 4 is "Replay-Bell-Bell", the small winning combination 5 is "Bell-Replay-Bell", and the small winning combination 6 is "Bell-Bell-Replay". Also, the corresponding number of payouts is as shown in FIG.

Among the above small roles, the small role 1 is "cherry", the small role 2 is "watermelon", the small role 3 is "bell", the small role 4 is "left bell", the small role 5 is "middle bell", and the small role 6 is sometimes referred to as the "right bell". In the case of "ANY-Cherry-ANY", the middle reel middle pattern of the middle reel 111 may be "Cherry", and the left reel 110 and the right reel 112 may have any pattern.

Here, the small winning combination 3 (bell) is a winning combination regardless of the order (push order) of the stop buttons 137 to 139, but the small winning combination 4 (left bell) and the small winning combination 5 (middle bell). And a small winning combination 6 (left bell) wins when the order of stop operations of the stop buttons 137 to 139 matches a predetermined order of stop operations. For example, a small win 4 (left bell) wins when the first stop operation is performed on the left reel 110, and a small win 5 (middle bell) wins when the first stop operation is performed on the middle reel 111. A small win 6 (right bell) is won when the first stop operation is performed on the right reel 112 . Hereinafter, the small wins 4 to 6 may be collectively referred to as push-order bells. In addition, the order of stop operation for winning the internal winning push order bell is also called the correct order of stop operation.

<Types of internally elected roles>
Next, types of internal winning combinations of the slot machine 100 will be described with reference to FIG. FIG. 8 is a diagram showing a lottery table for internal winning combinations for each RT.

FIG. 8 shows 12 types of internal winning combinations (condition device numbers 1 to 10), which are combinations of the combinations explained in FIG. The winning combination in the game is one of the combinations corresponding to this internal winning combination. These internal winning combinations are determined by lottery at the start of the game.

Condition device numbers 1 and 2 are both internally winning combinations including special combination 1. Of these, condition device number 1 is an internal winning combination in which special combination 1 is won alone and there is no duplication with other combinations. When this winning combination is won internally, it becomes possible to win a special winning combination 1 (transition to a special game state (RT2)), but if no prize is won, a transition is made to a special winning internal winning state (RT1). In this case, unless another winning combination is internally won in the next and subsequent games, the special winning combination 1 can be continuously won.

On the other hand, the condition device number 2 is an internal winning combination in which the special combination 1 and another combination are duplicated and internally won. In this embodiment, the small winning combination and the replay winning combination are stopped with priority over the special winning combination. Therefore, in a game in which the special role 1 and another role are duplicated and internally won, there is a possibility that this other role will win (in the case of a replay role, the prize will always be won), but the special role 1 will win. do not. It should be noted that the special combination internal winning state (RT1) is entered from the next game, and the special combination 1 can continue to be won as long as no other combination is internally won in the next and subsequent games.

Conditional device numbers 3 and 4 are internal winning hands made up of replayed hands.

In addition, in the condition device numbers 2 and 4, the replay combination 1 and the replay combination 2 are won in duplicate. When these conditional devices are internally won, if a predetermined stop operation is performed, the symbol combination corresponding to the replay combination 2 is displayed on the effective line, and if any other stop operation is performed, the replay combination 1 is displayed. Stop control is executed so that the corresponding symbol combination is displayed on the activated line. In the present embodiment, the predetermined stop operation is the left first stop, but the present invention is not limited to this, and for example, not only the first stop operation but also the second stop operation may be included in the predetermined stop operation. Alternatively, the timing of the stop operation may be the predetermined stop operation described above, or a combination thereof, and any operation condition may be adopted.

Condition device numbers 5 to 10 are internal winning hands made up of small hands. Of these, the condition device numbers 8 to 10 are provided with operation conditions (push order here, correct push order below) for winning the corresponding minor combination (left bell, middle bell, right bell). In the following description, conditional device numbers 8 to 10 may be collectively referred to as push order bells. In the above configuration, if the stop operation does not match the order of pressing the correct answer, it may be lost. It is good also as a structure which carries out.

In the internal winning combination lottery table shown in FIG. 8, the horizontal axis represents each game state (RT), and the vertical axis represents each lottery value (size of lottery data range). In each RT to be described later, the internal winning probability of a role is determined by selecting numerical data corresponding to the range of lottery data associated with each role from the lottery data prepared in the ROM 306, and using random values acquired during the internal lottery. is obtained by dividing by numerical data (for example, 65536) in the range of . For example, in the replay low probability state (RT0), the lottery value of special role 1 is 50, and the winning probability of special role 1 is 50/65536*100≈0.06%. The lottery data is divided in advance into several numerical ranges, and each numerical range is associated with each winning combination and loss. A random number value obtained as a result of executing an internal lottery is determined as a value corresponding to lottery data corresponding to which combination, and an internal lottery combination (internal winning combination) is determined. Setting 1 to setting 6 are prepared for the lottery data with different winning probabilities of at least one combination, and the staff of the game parlor can arbitrarily select and set any of the setting values.

In the present embodiment, the internal winning probabilities of the condition devices with condition device numbers 8 to 10 for each game state are uniform, but the internal winning probabilities may be biased.

If you do not win the role of each condition device, you will lose, and basically the symbol combination corresponding to the role will not be displayed. It should be noted that the fact that the symbol combination relating to the winning line is not stopped may be referred to as "losing". In addition, there is a case where the fact that you did not win the role of any of the conditional devices is expressed as "won wrong".

In the slot machine 100 shown in FIG. 1, set values are set for different degrees of advantage for the player. Setting values 1 to 6 are prepared. There is a tendency that the higher the set value, the higher the player's advantage.

<Types of game status (RT)>
Next, the types of game states of the slot machine 100 and their transitions will be described. FIG. 9 is a transition diagram of the gaming state (RT) of the slot machine 100. As shown in FIG.

The slot machine 100 is configured to be able to switch between a plurality of types of states with different degrees of advantage, namely, a replay low probability state, a special role internal winning state, and a special game state. The degree is changed to improve the amusement of the game. In the following description, this game state may be referred to as RT, and the replay low probability state, the special role internal winning state, and the special game state may be referred to as RT0, RT1, and RT2, respectively. be. Also, when these RTs are switched, the corresponding lottery table is changed (described later). RT is controlled by the main controller 300 .

FIG. 9 shows each of the RTs described above, and their transition conditions are indicated on the arrows. When the transition condition corresponding to each arrow is met, RT transitions in the direction of that arrow. These transition conditions include, for example, winning a predetermined winning combination, internal winning of a predetermined winning combination, stop display of a specific symbol combination on a specific winning line, and completion of a specified number of games. , and a predetermined number of coins may be paid out.

Hereinafter, each RT will be described with appropriate reference to the drawings.

<Replay low probability state (RT0)>
RT0 has a lower internal winning probability of a replay role than RT1, and is the most disadvantageous RT for the player.

There are conditional device numbers 1 to 10 for internally won hands in RT0. If the winning combination is not won, the combination of symbols corresponding to the winning combination is not displayed. It should be noted that the fact that the symbol combination relating to the winning line is not stopped may be referred to as "losing". In addition, the fact that the role was not won may be expressed as "won't win".

FIG. 9 shows that when the special combination 1 is internally won while RT0 is set, the state shifts to the special combination internal winning state, which will be described later.

<Special role internal elected state (RT1)>
RT1 is a state in which the internal winning flag corresponding to the special combination 1 is set to ON. Also, the probability of winning a replay role is higher than RT0, and RT is more advantageous than RT0.

There are condition device numbers 3 to 10 in RT1 for internally won hands.

FIG. 9 shows that when the special combination 1 is won in RT1 (when the corresponding symbol combination is displayed), the process proceeds to RT2.

<Special game state (RT2)>
RT2 is an advantageous RT in which the internal winning probability of Bell (small combination 3) is higher than in other RTs and medals can be easily obtained.

The condition device number 7 is the only internal winning combination in RT2. A small winning combination 3 that is internally won with the condition device number 7 is a winning combination that wins a bell regardless of operation conditions (operation timing, operation order) if internally won.

FIG. 9 shows that in RT2, when the payout exceeds the specified number (324, see the remarks column in FIG. 7), the process shifts to RT0.

It should be noted that in this embodiment, RT2 ends when a specified number of payouts or more is executed, but for example, it ends when a predetermined combination (eg, single bonus) is won, or a predetermined number of times (eg, 8 times), or when a predetermined number of times (for example, 6 times) is played, the game may end.

<Unadvantageous Sections and Advantageous Sections>
In the slot machine 100 of the present embodiment, apart from the above-described RT, the game state is divided into non-advantageous intervals and advantageous intervals for management. Of these, in the advantageous section, notification of the stop operation order for the internally won combination (hereinafter sometimes referred to as operation navigation) is allowed, and in the non-advantageous section, this operation navigation is not displayed. In addition, the operation navigation is displayed according to the conditions in the advantageous section, but the operation navigation may not be displayed even if the push order bell is internally elected. These states will be described below with reference to FIG. This figure shows the transition of the game state regarding the advantageous section and the non-advantageous section of the slot machine 100 .

In this embodiment, the initial state (for example, the state at the time of shipment from the factory) is set to the non-advantageous section. Also, when there is a RAM clear (setting change), this non-advantageous interval is set. The state of the non-advantageous section is referred to as normal state A. In addition, in this embodiment, three types of states of the advantageous section are provided: the normal state B, the chance state, and the AT state. FIG. 10 shows transitions between four states: normal state A, normal state B, chance state, and AT state. In this embodiment, the advantageous section flag is set to OFF for non-advantageous sections, and the advantageous section flag is set to ON for advantageous sections. distinguish. In addition, in order to prevent the gambling spirit, when the advantageous section continues over a predetermined number of games (for example, 1500 games), or when the predetermined net increase number (for example, 2400) is exceeded is configured to be a non-advantageous section.

It should be noted that the state of the advantageous section may be only the AT state, or, for example, a premonitory state before shifting to the AT state may be further provided, and is not limited to the configuration of the present embodiment. . Similarly, there may be multiple types of states for the states of the non-advantageous sections.

Since the non-advantageous section and the advantageous section are set separately from the RT, for example, there are cases where the transition to RT2 occurs during the advantageous section. However, in RT2, the push order bell is not internally won, and the operation navigation is not displayed, so for RT2, a non-advantageous section may be set once, and after RT2 is completed, it may return to the advantageous section. . Further, the configuration is not limited to the above, and it may be configured such that an internal winning is made to the pressing order bell at RT2 and an operation navigation is displayed. Note that the advantageous section lamp 191 may be turned on during the entire period of the advantageous section or during a part of the period. However, when a part of the advantageous section is in the AT state, if the advantageous section lamp 191 is lit in a section that is not in the AT state of the advantageous section, the impression that the AT state is imminent may give Therefore, it is preferable that the interval in which the advantageous interval lamp 191 is turned on is a minimum interval such as when the vehicle is in the AT state.

Each state of the non-advantageous section and the advantageous section will be described below.

<Normal state A>
In the non-advantageous section (normal state A), a lottery for transition to the advantageous section is executed based on the internal winning combination. If the lottery is won, the state shifts to the normal state B in the advantageous section.

<Normal state B>
In the normal state B, the state shifts to the chance state when the conditions for shifting to the chance state are satisfied. Further, when the transition condition is established, the number of games in the chance state is set. Regarding this transition condition, for example, a condition that is established by executing a predetermined number of games in the normal state B, a lottery for transition to each game chance state in the normal state B, and when this lottery is won , conditions to be established when points (any of 1 to 3) added according to the result of one game in normal state B accumulate up to a specified number (100 points), and so on. Conditions can be adopted.

<Chance state>
In the chance state, an AT lottery may be conducted according to the internally won combination. When the AT lottery is not won (the number of AT sets is 0) before the set number of games has passed, the game shifts to the normal state B, and when the number of AT sets is 0, the game shifts to the AT state. When shifting to the AT state, the AT set number is decremented by 1, and the AT remaining game number is set to a predetermined number of games (for example, 50).

In the slot machine 100 of the present embodiment, the AT lottery is executed in the chance state. The AT lottery timing and execution conditions can be arbitrarily adopted.

<AT state>
Next, the AT state will be explained. Below, the AT state may be simply referred to as AT.

In the AT state, when the push order bell (condition device numbers 8 to 10) is internally won, an operation navigation showing the correct push order corresponding to each is displayed. Note that this operation navigation is not limited to indicating the pressing order, and may indicate the timing of the stop operation, such as a display such as "Aim for...", or the pressing order and timing. may indicate both. In addition, on the payout number indicator 127, the 7 segments are lit up in a manner corresponding to the pressing order of the correct answer (hereinafter sometimes referred to as navigation lighting). The display on the payout number indicator 127 may also be illuminated in a mode corresponding to the timing of the stop operation, or may be illuminated in a mode corresponding to both the pressing order and the timing. .

In this embodiment, the number of AT remaining games is subtracted as the AT state game progresses. Then, when the AT remaining game number becomes 0, if the AT set number is greater than 0, the AT remaining game number is set to a predetermined value (eg, 50) again, and if the AT set number is 0, the chance state is entered. conduct a lottery. When the lottery is won, the state shifts to the chance state, and when the lottery is not won, the advantageous section is shifted to the non-advantageous section (parameters related to the advantageous section are initialized). Incidentally, when the special game state (RT2) is entered in the middle of the AT state, the subtraction of the number of remaining AT games is stopped, and the subtraction is resumed when RT0 is reached.

The AT state may be started and ended according to a predetermined condition (for example, when a specific game state is reached) without being limited to the configuration using the AT set number or the AT remaining game number.

In the case of this embodiment, there are two types of AT states: pseudo BB state and pseudo RB state. The pseudo BB state is an AT state in which the player is more advantageous than the pseudo RB state. A favorable AT state may be, for example, an AT state in which a larger number of AT sets is set. Alternatively, it may be an AT state in which a larger number of games are set for one set. Alternatively, it may be an AT state in which the probability of notifying the correct pressing order is higher. Whether the AT state becomes the pseudo BB state or the pseudo RB state may be determined by a lottery in the chance state, or may be determined by the number of games played in the chance state. Alternatively, it may be determined by the selection result of the reel stop data of the pseudo-game (S1001 in FIG. 13). The probability that the AT state will be in the pseudo BB state may be lower than the probability that it is in the pseudo RB state.

Moreover, in the present embodiment, both the pseudo BB state and the pseudo RB state are the AT state, but the pseudo BB state may be the AT state, and the pseudo RB state may be a state different from the AT state. Another state may be more disadvantageous to the player than the pseudo BB state, but more advantageous to the player than another state (eg normal state A).

<Overview of processing>
The processing of the main control unit 300, the first sub-control unit 400, and the second sub-control unit 500 will be described below with reference to the drawings.

<Main control unit main processing>
First, main control unit main processing executed by the CPU 304 of the main control unit 300 will be described with reference to FIG. It should be noted that this figure is a flow chart showing the flow of the main processing of the main controller.

As described above, the main control unit 300 is provided with the activation signal output circuit (reset signal output circuit) 338 that outputs the activation signal (reset signal) when the power is turned on. The CPU 304 of the basic circuit 302 that has received this activation signal is reset-started by the reset interrupt and executes the main control section main processing shown in FIG.

When the power is turned on, first, in step S101, initial setting processing of the main control unit is performed. In this main control unit initial setting process, the stack initial value is set to the stack pointer (SP) of the CPU 304, interrupt inhibition is set, the I/O 310 is initialized, various variables stored in the RAM 308 are initialized, and the WDT 314 is initialized. Allow operation and set initial values.

In step S103, a game start process is executed. In this process, it is checked whether or not medals have been inserted (maintenance or operation of the bet buttons 130 to 132), and the winning line display lamp 120 is lit according to the insertion of medals. Also, when medals have been inserted, preparations are made to send an insertion command indicating that medals have been inserted to the first sub-control section 400 . If the player wins the replay in the previous game, the same number of medals as the medals inserted in the previous game are inserted, so the player does not need to insert medals. In addition, it is checked whether or not the start lever 135 has been operated while the specified number (three) of medals has been used. Confirm and start playing.

In step S105, various lottery processes including internal winning combination lottery process and the like are executed. In this process, the internal winning combination lottery table stored in the ROM 306 is read according to the current RT, and an internal lottery (lottery for the combination) is performed using this table and the random number obtained from the random number generation circuit 316. Determine internal winners. As a result of the internal lottery, if any combination (including the active combination) is internally won, the flag for that combination is turned on. Also, in this step S105, preparations are made to transmit an internal lottery command including internal winning information indicating the result of the internal winning combination lottery to the first sub-control section 400. FIG. For example, when a replay is internally won, preparations are made to transmit an internal lottery command indicating that the replay is internally won to the first sub-control unit 400, and the winning combination is executed. If the result of the internal lottery is a loss (non-winning role), preparations are made to transmit an internal lottery command indicating a loss to the first sub-control unit 400 . The internal winning command includes information on the internal winning combination, information on the current advantageous section (if the period is finite, including information on the number of remaining games such as the number of remaining AT games), and AT lottery. And information that can specify the result of the AT addition lottery is included. Of the above information, the information relating to the number of AT remaining games may not be included in the internal winning command in the non-AT state, and may be included in the internal winning command only in the AT state. Furthermore, in the AT state, the internal winning command including that the condition device numbers 8 to 10 have been internally won also includes operation instruction information representing the correct operation order of the operation order (push order) of the stop buttons 137 to 139. .

In step S107, it is determined whether or not the pseudo-game flag is set to ON. If this condition is satisfied, the process proceeds to step S109; otherwise, the process proceeds to step S111.

In step S109, a pseudo-game related process is executed. Details of this process will be described later with reference to FIG.

In step S111, reel stop data corresponding to the first stop operation is prepared based on the result of the internal winning combination lottery. This reel stop data is stored in the ROM 306 of the main control section 300 .

In step S113, reel rotation start processing is executed on the condition that the game interval timer (subtracted in timer update processing, which will be described later) is 0, and the reels 110 to 112 are started to rotate. Also, when the reels 110 to 112 start rotating, preparations are made to transmit a reel rotation start command to the first sub-controller 400 . After that, when the reels 110-112 reach a predetermined rotational speed, the optical sensors provided on each reel are detected, and the symbol position of each reel is grasped, the stop operation to the stop buttons 137-139 is enabled. The game interval counter secures the minimum time required for one game (4.1 seconds in this embodiment) to suppress gambling. Details of this process will be described later with reference to FIG.

In step S115, a reel stop control process is executed. In this processing, when one of the stop buttons 137-139 is pressed after the stop operation is validated, the reels 110-112 corresponding to the pressed stop button 137-139 are stopped. Specifically, every time a stop operation is performed, the stop table of the reel stop data is referred to, and the reels 110 to 112 corresponding to the stop operation are stopped according to the number of pull-in frames set in the stop table. Further, reel stop data corresponding to the second stop operation is prepared for the first stop operation, and reel stop data corresponding to the third stop operation is prepared for the second stop operation. For each stop operation, preparations are made to send the corresponding command (first to third press commands) to the first sub-control unit 400, and each time the reels 110 to 112 stop, the corresponding command (first 1st to 3rd stop commands) to the first sub-controller 400. When all the reels 110-112 are stopped, the process proceeds to step S117.

In step S117, a winning determination process is performed. Here, when a symbol combination corresponding to some winning combination is displayed on the activated winning line, it is determined that the winning combination has been won. For example, if "watermelon-watermelon-watermelon" is aligned on the activated pay line, it is determined that the small win 2 has been won. After determining the winning combination, preparations are made to transmit the winning command to the first sub-control unit 400 .

In step S119, if the player wins any winning combination with a payout, the number of medals corresponding to the winning combination is given (paid out), and the payout number indicator 127 is used to display the given number.

In step S121, RT update processing is performed. In this process, RT is transitioned based on the conditions shown in the state transition diagram shown in FIG.

In step S123, game state update processing is performed. Here, based on the result of the game, the status regarding the non-advantageous section and the advantageous section explained in FIG. 10 is updated. For example, when the normal state A shifts to the normal state B, the advantageous section flag is set to ON, and when the AT state shifts to the normal state A, the advantageous section flag is set OFF. In addition, a pseudo-game flag is set to ON when the state is shifted from the chance state to the AT state. Further, when the AT state is shifted to the normal state A, the advantageous section lamp 191 is extinguished. In addition, preparations are made for transmission of the game state update command. This command includes information on RT, information on non-advantageous intervals and advantageous intervals (for example, advantageous interval flag, number of AT sets and number of AT remaining games).

One game is completed by the above. Thereafter, the game progresses by returning to step S103 and repeating the above-described processing.

<Main control unit 300 timer interrupt processing>
Next, the main controller timer interrupt processing executed by the CPU 304 of the main controller 300 will be described with reference to FIG. This figure is a flow chart showing the flow of the main controller timer interrupt processing.

The main control unit 300 includes a counter timer 312 that generates a timer interrupt signal at a predetermined cycle (about once every 2 ms in this embodiment). Processing is started at a predetermined cycle.

In step S201, timer interrupt start processing is performed. In this timer interrupt start processing, processing such as temporarily saving the values of each register of the CPU 304 to the stack area is performed.

In step S203, the WDT 314 is periodically turned on so that the count value of the WDT 314 does not exceed the initial set value (32.8 ms in this embodiment) and a WDT interrupt does not occur (so that an abnormality in processing is not detected). In the embodiment, a restart is performed once every 2 ms, which is the cycle of the main controller timer interrupt.

In step S205, input port state update processing is performed. In this input port state update processing, the detection signals of the sensor circuits 320 of the various sensors 318 are input via the input port of the I/O 310 to monitor the presence or absence of the detection signals. It is stored in the provided signal state storage area. Note that the state of the optical sensor is confirmed in this process.

In step S207, various game processes are executed, and processes corresponding to interrupt statuses (acquiring various interrupt statuses based on signals from various sensors 318) are executed. For example, if the interrupt status is medal insertion processing, medal insertion acceptance processing is performed, and if the interruption status is payout processing, medal payout processing is performed.

In step S209, timer update processing is performed. For example, a process of updating various timers in units of time, such as subtracting a game interval timer, is executed.

In step S<b>211 , command setting transmission processing is performed, and various commands that have been prepared for transmission in main processing, timer interrupt processing, etc. of the main control section 300 are transmitted to the first sub-control section 400 . The output schedule information to be transmitted to the first sub-control unit 400 includes strobe information (if it is ON, it indicates that data is set), command type (in this embodiment, basic command, input command, start lever Acceptance command, internal winning command, production command accompanying production lottery processing, reel rotation start command accompanying start of rotation of reels 110-112, pseudo game rotation start command, stop buttons 137-139 First to accompanying acceptance of operation Third press command, first to third stop commands associated with stopping reels 110 to 112, winning command, payout number command and payout end command accompanying medal payout processing, status update command), command data (corresponding to command type predetermined information).

In the first sub-control unit 400, the command type included in the received output schedule information enables the determination of the effect control according to the change in the game control in the main control unit 300, and is included in the output schedule information. Based on the information of the command data, it becomes possible to determine the effect control contents.

In step S213, an external signal setting process is performed. In this external signal setting process, the game information stored in the RAM 308 is output to the information input circuit 652 separate from the slot machine 100 via the information output circuit 334 .

In step S215, device monitoring processing is performed. In this device monitoring process, first, in step S205, the signal states of the various sensors 318 stored in the signal state storage area are read out, and the presence or absence of an error related to medal insertion abnormality, medal payout abnormality, etc. is monitored. (Not shown) Execute error processing. Further, the medal selector 170 (a medal blocker operated by a solenoid provided in the medal selector 170), various lamps 339, and various 7-segment (SEG) indicators are set according to the current game state.

In step S217, it is monitored whether the low voltage signal is on. If a low voltage signal is received (power cutoff is detected), the process proceeds to step S221, and if a low voltage signal is not received (power cutoff is not detected), the process proceeds to step S219. move on.

In step S219, timer interrupt end processing is performed. In this timer interrupt end processing, processing such as setting the value of each register temporarily saved in step S201 to each original register is performed. After that, the process returns to the main control unit main process shown in FIG.

On the other hand, in step S221, information that needs to be saved, such as specific variables and stack pointers for returning to the state at the time of power failure when power is restored, is saved in a predetermined area of RAM 308. A checksum value for the area is derived and stored in the RAM 308, and a power supply flag indicating that power-off processing has been performed is set to ON.

<Pseudo-game related processing>
Next, using FIG. 13, pseudo-game related processing (step S109) in the main control unit main processing of FIG. 11 will be described. FIG. 13 is a flow chart showing the flow of pseudo-game related processing (step S109) in FIG.

In step S1001, pseudo-game reel stop data is prepared. Specifically, reel stop data is prepared for pseudo-stopping when seven 2 symbols are aligned on the winning line L1. It should be noted that reel stop data for stopping an arbitrary combination of symbols can be used as long as the combination of symbols is different from the combination established in this game. Also, a plurality of types of such reel stop data may be prepared and one of the plurality of types may be selected.

In step S1003, pseudo-game reel rotation start processing is executed. Details of this process will be described later with reference to FIG.

In step S1005, a pseudo-game reel stop control process is executed. Details of this process will be described later with reference to FIG.

In step S1007, the random delay flag is set to ON.

In step S1009, the pseudo-game flag is set to off.

<Pseudo game reel rotation start processing>
Next, with reference to FIG. 14, the pseudo-game reel rotation start processing (step S1003) in the pseudo-game related processing of FIG. 13 will be described. FIG. 14 is a flow chart showing the flow of the pseudo-game reel rotation start process (step S1003) in FIG.

In step S1101, acceleration parameters for each reel are set.

In step S1103, preparation for transmitting a pseudo-game rotation start command to the first sub-control unit 400 is executed.

In step S1105, the reels 110-112 are started to rotate using the acceleration parameters set in step S1101.

In step S1107, it is determined whether or not the rotational speeds of the reels 110-112 are constant. If the rotational speeds of the reels 110-112 are constant, the process proceeds to step S1109; otherwise, step S1107 is repeated.

In step S1109, the operation of the stop buttons 137-139 is validated.

<Pseudo-game reel stop control processing>
Next, with reference to FIG. 15, the pseudo-game reel stop control process (step S1005) in the pseudo-game related process of FIG. 13 will be described. FIG. 15 is a flow chart showing the flow of the pseudo-game reel stop control process (step S1005) in FIG.

In step S1201, a pseudo-game regulation timer is set. The pseudo-game regulation timer is a timer that measures the time of one pseudo-game. In this embodiment, using a pseudo-game regulation timer, the execution time of one pseudo-game is limited to a predetermined time TA (specifically about 20 seconds). In step S1201, a timer value corresponding to a predetermined time TA is set as an initial value to the pseudo-game regulation timer. This timer value is decremented each time the timer interrupt processing (timer update processing in step S209) of the main control unit 300 is executed.

In step S1203, it is determined whether or not the stop buttons 137-139 have been operated. If the stop buttons 137 to 139 have been operated, the process proceeds to step S1205; otherwise, the process proceeds to step S1209.

In step S1205, the reels 110 to 112 corresponding to the stop buttons 137 to 139 that have been stopped are quasi-stopped.

In step S1207, it is determined whether or not all the reels 110 to 112 are quasi-stopped. If all the reels 110 to 112 are pseudo-stopped, the process proceeds to step S1213; otherwise, the process returns to step S1203.

In step S1209, it is determined whether or not the pseudo-game regulation timer has timed out, that is, the predetermined time TA corresponding to the set timer value has elapsed. If the pseudo-game regulation timer times out, proceed to step S1211, otherwise return to step 1203.

In step S1211, all the reels 110-112 are quasi-stopped because the predetermined time TA has elapsed without any of the stop buttons 137-139 being operated. Thus, in the pseudo-game of this embodiment, in order to promote the progress of the pseudo-game, it has a function of automatically pseudo-stopping the reels 110 to 112 when there is no stop operation.

In step S1213, a pseudo game end timer is set. The pseudo-game end timer is a timer that measures the time interval between the pseudo-game and the main game, and a predetermined effect (for example, the effect that the pseudo-game has ended, the effect that the main game is started, etc.) It is provided to reserve time for execution. In this embodiment, since the time interval between the pseudo-game and the main game is set to a predetermined time TC (specifically about 1 second), in step S1213, the pseudo-game end timer corresponds to the predetermined time TC as an initial value. A timer value is set. This timer value is decremented each time the timer interrupt process of the main control unit 300 is executed. In addition, in step S1213, preparations are made to transmit a pseudo-game end command indicating that the pseudo-game has ended to the first sub-control unit 400.

<Reel rotation processing>
Next, the reel rotation start process (step S113) in the main control unit main process of FIG. 11 will be described with reference to FIG. FIG. 16 is a flowchart showing the flow of reel rotation start processing (step S113) in FIG.

In step S1301, acceleration parameters for each reel are set.

In step S1303, preparation for transmission of the game rotation start command to the first sub-control unit 400 is executed.

In step S1305, 7 segment setting processing is executed. Details of this process will be described later with reference to FIG.

In step S1307, it is determined whether or not the random delay flag is set to ON. If this condition is satisfied, the process proceeds to step S1311; otherwise, the process proceeds to step S1309.

In step S1309, the reels 110-112 are started to rotate using the acceleration parameters set in step S1301.

In step S1311, random delay rotation start processing is executed. Details of this process will be described later with reference to FIG.

In step S1313, it is determined whether or not the rotational speeds of the reels 110-112 are constant. If the rotational speeds of the reels 110 to 112 are constant, the process proceeds to step S1315; otherwise, step S1313 is repeated.

At step S1315, the operation of the stop buttons 137-139 is validated.

<7 segment setting processing>
Next, the 7-segment setting process (step S1305) in the reel rotation start process of FIG. 16 will be described with reference to FIG. FIG. 17 is a flow chart showing the flow of the 7-segment setting process (step S1305) in FIG.

In step S1401, it is determined whether or not there is operation navigation information indicating the pressing order. If this condition is satisfied, the process proceeds to step S1403; otherwise, the 7-segment setting process ends. The operation navigation information is set when the condition device numbers 8 to 10 are internally won in the AT state.

In step S1403, display setting of operation navigation (navi lighting) by the payout number display 127 is executed.

In step S1405, it is determined whether or not the advantageous section flag is set to ON. If this condition is satisfied, the process proceeds to step S1407; otherwise, the 7-segment setting process ends.

In step S1407, it is determined whether or not the advantageous interval display by the advantageous interval lamp 191 is set to off (extinguished). If this condition is satisfied, the process advances to step S1409; otherwise, the 7-segment setting process ends.

In step S1409, the advantageous section display by the advantageous section lamp 191 is set to ON (lit).

<Random delay rotation start processing>
Next, random delay rotation start processing (step S1311) in the reel rotation start processing of FIG. 16 will be described with reference to FIG. FIG. 18 is a flow chart showing the random delay rotation start process (step S1311) in FIG.

In step S1501, it is determined whether or not a predetermined time TC has elapsed by measuring the pseudo-game end timer. When the predetermined time TC has passed by measuring the pseudo-game end timer, the process proceeds to step S1503, otherwise step S1501 is repeated.

In step S1503, the left reel 110 starts rotating.

In step S1505, it is determined whether or not the left reel 110 has finished accelerating. If the left reel 110 has finished accelerating, the process proceeds to step S1507; otherwise, the process returns to step S1505.

In step S1507, a rotation start timer for the middle reel 111 is set. Specifically, a timer value corresponding to 0 to 756.512 ms is obtained by lottery, and this value is set. The value of the rotation start timer of the middle reel 111 is decremented each time the main controller timer interrupt process is executed.

In step S1509, it is determined whether or not the rotation start timer of the middle reel 111 has timed out, that is, whether or not the standby time corresponding to the initially set timer value has elapsed. If the rotation start timer of the middle reel 111 times out, the process proceeds to step S1511; otherwise, the process returns to step S1509.

In step S1511, rotation of the middle reel 111 is started. Although the middle reel 111 starts rotating in step S1511, the middle reel 111 is in a pseudo stop state until the rotation starts.

In step S1513, it is determined whether or not the acceleration of the middle reel 111 has ended. If the acceleration of the middle reel 111 is completed, the process proceeds to step S1515, and if not, the process returns to step S1513.

In step S1515, a rotation start timer for the right reel 112 is set. Specifically, a timer value corresponding to 0 to 756.512 ms is obtained by lottery, and this value is set. The value of the rotation start timer of the right reel 112 is decremented each time the main controller timer interrupt process is executed.

In step S1517, it is determined whether or not the rotation start timer of the right reel 112 has timed out, that is, whether or not the standby time corresponding to the initially set timer value has elapsed. If the rotation start timer of the right reel 112 has timed out, the process proceeds to step S1519; otherwise, the process returns to step S1517.

In step S1519, the right reel 112 starts rotating. Although the right reel 112 starts rotating in step S1511, the right reel 112 is in a pseudo stop state until it starts rotating.

In step S1521, the random delay flag is set off.

<Processing of first sub-controller 400>
Next, the processing of the first sub-controller 400 will be described with reference to FIG. FIG. 19A is a flowchart of main processing executed by the CPU 404 of the first sub-controller 400. FIG. FIG. 19(b) is a flowchart of command reception interrupt processing of the first sub-controller 400. FIG. FIG. 19(c) is a flowchart of timer interrupt processing of the first sub-controller 400. FIG.

First, in step S301, various initial settings are performed. This initialization is performed when the power is turned on. In this processing, initial setting of input/output ports, initialization processing of storage areas in the RAM 408, and the like are performed. In this process, the RAM 408 is provided with an area for storing internal winning information representing the result of internal winning and an area for storing RT update information representing the game state.

In step S303, it is determined whether or not the timer variable is 10 or more, and this process is repeated until the timer variable reaches 10. When the timer variable becomes 10 or more, the process proceeds to step S305.

In step S305, 0 is substituted for the timer variable.

In step S307, command processing, which is processing corresponding to each command received from the main control unit 300, is executed.

In step S309, effect control processing is performed. Here, the effect data is expanded, the processing of setting the device data in the effect execution area provided in the RAM 408, the process of setting the effect data in the effect reservation area provided in the RAM 408, and the received command And based on the information contained in the command, it performs processing such as setting effect data and executing control processing. Note that the effect data set in the effect reservation area and the device data set in the effect execution area may be updated (overwritten) with different data. In this case, the effect contents are changed based on the overwritten data.

In step S311, sound control processing is performed based on the processing result of step S309. For example, by acquiring control data from the device data set in the effect execution areas corresponding to the speakers 272 and 277 and outputting the acquired control data to the sound source IC 418, sound effects are executed.

In step S313, lamp control processing is performed based on the processing result of step S309. For example, by acquiring control data from device data set in the effect execution area corresponding to various lamps 420 and outputting the acquired control data to the driving circuit 422, the effect by the lamp is executed.

In step S315, shutter control processing is performed based on the processing result of step S309. For example, the control data is acquired from the device data set in the effect execution area corresponding to the shutter 163, and the acquired control data is output to the driving circuit 424, thereby executing the effect by the shutter 163.

In step S317, information output processing is performed to set transmission of the control command to the second sub-controller 500 based on the processing result of step S309. For example, if there is device data set in the effect execution area corresponding to the effect image display device 157, preparations are made to transmit this device data to the second sub-controller 500, and the process returns to step S303.

Next, command reception interrupt processing of the first sub-controller 400 will be described with reference to FIG. 19(b). This command reception interrupt process is a process executed when the first sub-controller 400 detects a strobe signal output by the main controller 300 . In step S321 of the command reception interrupt process, the command output by the main control unit 300 is stored in the command storage area provided in the RAM 408 as an unprocessed command.

Next, the first sub-controller timer interrupt processing executed by the CPU 404 of the first sub-controller 400 will be described with reference to FIG. 19(c). The first sub-control unit 400 includes a hardware timer that generates a timer interrupt at a predetermined period (once every 2 ms in this embodiment). period.

In step S331, 1 is added to the value in the timer variable storage area of RAM 408 described in step S303 in the first sub-controller main process shown in FIG. 19A, and the result is stored in the original timer variable storage area. Therefore, in step S303, the value of the timer variable is determined to be 10 or more every 20 ms (2 ms×10).

In step S333, transmission of the device data to the second sub-control section 500 set in step S315, update processing of the random number value for effect, and the like are performed.

<Processing of second sub-controller 500>
Next, the processing of the second sub-controller 500 will be described with reference to FIG. FIG. 20(a) is a flowchart of the main process executed by the CPU 504 of the second sub-controller 500. FIG. FIG. 20(b) is a flowchart of command reception interrupt processing of the second sub-controller 500. FIG. FIG. 20(c) is a flowchart of the timer interrupt processing of the second sub-controller 500. FIG. FIG. 20(d) is a flowchart of the image control processing of the second sub-controller 500. FIG.

First, in step S401 of FIG. 20A, various initial settings are performed. When power is turned on, initialization processing is first executed in step S401. In this initialization processing, input/output port initialization processing, initialization processing of storage areas in the RAM 508, and the like are performed.

In step S403, it is determined whether the timer variable is 10 or more, and this process is repeated until the timer variable reaches 10. When the timer variable becomes 10 or more, the process proceeds to step S405.

In step S405, 0 is substituted for the timer variable.

In step S407, command processing is performed. In command processing, the CPU 504 of the second sub-controller 500 determines whether or not a command has been received from the CPU 404 of the first sub-controller 400 .

In step S409, effect control processing is performed. Specifically, when there is a new command in step S407, processing corresponding to this command is performed. For example, a process of reading effect data for performing image control on a background image from the ROM 506 is executed. In addition, processing such as reading other effect data from the ROM 506 is performed, and when the effect data needs to be updated, the effect data is updated.

In step S411, image control processing is performed based on the processing result of step S409. For example, if there is an instruction for image control in the effect data read in step S409, image control corresponding to this instruction is performed. For example, image control is performed on display images (notification images, background images). This image control processing will be described later with reference to FIG. When this image control processing ends, the process returns to step S403.

Next, the command reception interrupt processing of the second sub-controller 500 will be described with reference to FIG. 20(b). This command reception interrupt process is a process executed when the second sub-controller 500 detects the strobe signal output by the first sub-controller 400 . In step S415 of the command reception interrupt process, the command output by the first sub-controller 400 is stored in the command storage area provided in the RAM 508 as an unprocessed command.

Next, the second sub-controller timer interrupt processing executed by the CPU 504 of the second sub-controller 500 will be described with reference to FIG. 20(c). The second sub-control unit 500 includes a hardware timer that generates a timer interrupt at a predetermined cycle (once every 2 ms in this embodiment). period.

In step S417, 1 is added to the value in the timer variable storage area of RAM 508 described in step S403 in the second sub-controller main process shown in FIG. 20A, and the result is stored in the original timer variable storage area. Therefore, in step S403, the value of the timer variable is determined to be 10 or more every 20 ms (2 ms×10).

In step S419, processing for updating the random number value for effect, etc. is performed.

Next, the image control processing of step S411 in the main processing of the second sub-controller 500 will be described with reference to FIG. 20(d). This figure is a diagram showing a flowchart showing the flow of image control processing.

In step S421, an instruction to transfer image data is issued. Here, the CPU 504 first swaps designation of the drawing areas of the display area A and the display area B of the VRAM 518 . As a result, the effect image display device 157 displays the one-frame image stored in the display area that is not designated as the drawing area. Next, the CPU 504 sets the ROM coordinates (the transfer source address of the ROM 506), the VRAM coordinates (the transfer destination address of the VRAM 518), and the like in the attribute register of the VDP 516 based on the position information table, and then transfers the image from the ROM 506 to the VRAM 518. Set an instruction to start data transfer. The VDP 516 transfers the image data from the ROM 506 to the VRAM 518 based on the command set in the attribute register. After that, the VDP 516 outputs a transfer end interrupt signal to the CPU 504 .

At step S423, it is determined whether or not a transfer end interrupt signal has been input from the VDP 516. If a transfer end interrupt signal has been input, the process proceeds to step S425, otherwise a transfer end interrupt signal has been input. wait for

In step S425, parameters are set based on the production scenario configuration table, attribute data, and the like. Here, in order to form a display image in the display area A or B of the VRAM 518 based on the image data transferred to the VRAM 518 in step S421, the CPU 504 obtains information of the image data forming the display image (coordinate axes of the VRAM 518, image size, and so on). , VRAM coordinates (placement coordinates), image overlay and transparency, etc.) to the VDP 516 . The VDP 516 sets parameters according to the attributes based on the instructions stored in the attribute registers.

In step S427, a drawing instruction is given. In this drawing instruction, the CPU 504 instructs the VDP 516 to start drawing an image. The VDP 516 starts drawing an image in the frame buffer according to instructions from the CPU 504 .

In step S429, it is determined whether or not a generation end interrupt signal has been input from the VDP 516 based on the end of image rendering. If a generation end interrupt signal has been input, the process proceeds to step S431. wait for is entered.

In step S431, a scene display counter, which is set in a predetermined area of the RAM 508 and counts how many scenes of images have been generated, is incremented (+1), and the process ends.

≪Explanation of operation≫
The features of the above-described slot machine 100 will be described below using an operation example.

[About pseudo-games]
In the slot machine 100, the reels 110 to 112 are rotated by inserting medals and operating the start lever 135, the winning combination is internally determined by an internal lottery, and the reels 110 to 112 are stopped by operating the stop buttons 137 to 139. , a combination is established when a combination of symbols corresponding to internal determination is displayed on the symbol display window. Then, when a winning combination involving payout of medals is established, a specified number of medals corresponding to the established winning combination is paid out. This series of actions is a normal game, but this normal game is called a main game in order to distinguish it from the pseudo-game described below.

On the other hand, pseudo-game means that the rotated reels 110-112 are stopped by operating the stop buttons 137-139 (pseudo-stop in this embodiment), and some symbol combination is displayed on the symbol display window. It is a kind of reel production that lets you play. In this pseudo game, the reels 110 to 112 can be stopped in the same way as in the main game, but unlike the main game, medals are not paid out as a result of the reels 110 to 112 stopping. In this embodiment, in the pseudo game, the reels 110 to 112 are not completely stopped like this game, and the reels 110 to 112 are pseudo-stopped (for example, continue microvibration), so that it is a pseudo game. (It is not a main game) is made to be understood. When the pseudo game ends, the reels 110 to 112 rotate again and the main game is started. That is, the pseudo-game, after operating the start lever 135 until the speed of rotation of the reels 110-112 in this game becomes constant, for the spinning reels 110-112 stop button 137 ~ This is a game as an effect in which the reels 110 to 112 are quasi-stopped by the operation of 139 to display an arbitrary symbol combination.

It should be noted that the pseudo-game in the present embodiment is an effect game that can be executed until the speed of rotation of all the reels 110 to 112 in this game becomes constant. It is good also as a production game which can be performed by the time it becomes constant. For example, when the rotated reels 110 to 112 are stopped by operating the stop buttons 137 to 139, only the reel 110 is caused to stop the pseudo game, and the reels 111 and 112 are allowed to stop the main game. Alternatively, the pseudo game may be stopped for the reels 110 and 111, and the real game may be stopped only for the reel 112.

In addition, in this embodiment, when shifting to the AT state, a configuration is adopted in which a pseudo game is executed before the reel rotation of this game is started. That is, when the pseudo-game ends, the rotation of the reels 110 to 112 in the main game is started, and the normal game progress is resumed. When the pseudo game is not performed, when the start lever 135 is operated, the rotation of the reels 110 to 112 in this game is started. In addition, in this embodiment, "Seven 2-Seven 2-Seven 2", which is not aligned in this game, stops in the pseudo-game. Therefore, the symbol combination of "seven-two-seven-two-seven-two" suggests a transition to the AT state. In addition, the pattern combination of "Seven 2 - Seven 2 - Seven 2" will stop regardless of the order and timing of the stop operation (unlimited withdrawal), but it will stop when these operation conditions are met. good too. Further, after all the reels 110 to 112 are temporarily temporarily stopped, the symbol combination of "seven 2-seven 2-seven 2" may be displayed by the reel action.

Here, an example of the operation of the pseudo-game of this embodiment will be specifically described with reference to FIG. 21 . First, in the case of the AT state from the next game (pseudo game flag ON), when the start lever 135 is operated (STA1 in FIG. 21(a)), the reels 110 to 112 start rotating. Next, the corresponding first stop reel (the left reel 110 in FIG. 21(a)) is pseudo-stopped based on the first stop operation (STO1-1 in FIG. 21(a), operation of the left stop button 137 here). . Then, the corresponding second stop reel (middle reel 111 in FIG. 21(a)) is pseudo-stopped based on the second stop operation (STO1-2 in FIG. 21(a), operation of the middle stop button 138 here). . Then, the corresponding second stop reel (middle reel 111 in FIG. 21(a)) is pseudo-stopped based on the second stop operation (STO1-2 in FIG. 21(a), operation of the middle stop button 138 here). . Then, the corresponding third stop reel (the right reel 112 in FIG. 21(a)) is pseudo-stopped based on the third stop operation (STO1-3 in FIG. 21(a), operation of the right stop button 139 here). .

As shown in FIG. 21(b), the reels 110 to 112 that are in a pseudo-stop state are not completely stationary, and the reels 110 to 112 do not maintain the same state for more than 500 ms. As shown in the figure, it is in a state in which the state is changed at a timing of 500 ms or less. Specifically, the reels 110 to 112 vibrate slightly up and down between a predetermined position A and a position A' slightly away from the position A. The state in which the reels 110 to 112 are not completely stationary means the state in which the reels 110 to 112 are not stationary when viewed macroscopically (in units of seconds). It includes a moving state (swaying state) and a stationary state when viewed microscopically (in units of several hundred milliseconds). In other words, the minute vibration may include a period in which the reels 110 to 112 are in a stationary state, and in this embodiment, the period between movements in the minute vibration is less than 500 ms. ing. That is, in the present embodiment, if there is a stationary state of 500 ms or more between movement and movement in microvibration, it is assumed that the reels 110 to 112 are stationary, and there was a stationary state of less than 500 ms. In this case, the reels 110 to 112 are defined as being stationary. In addition, the pseudo-stop in the pseudo-game is that if the reels 110 to 112 are completely stopped, the player misunderstands that the game is stopped, ends the game, and may leave the table. It is from. In other words, this is to prevent a situation in which the privilege that would have been obtained in the subsequent game is discarded. In the above example, each of the reels 110 to 112 is respectively pseudo-stopped. After the operation, all the reels 110 to 112 may be brought into a pseudo stop state all at once. Also, the vibrations of the reels 110 to 112 may be synchronous or asynchronous.

It should be noted that the state of micro-vibration is a state close to the shaking fluctuation of the decorative pattern image displayed on the pachinko display device. However, pachinko has a specification in which the result of the main game is notified by stopping the shaking after shaking and fluctuating the decorative pattern image. It is not intended to notify the result of this game by stopping the micro-vibration. When the reels 110 to 112 are completely stopped in the main game executed after this pseudo game, the result of the game is notified.

Also, in this embodiment, when all the reels 110 to 112 are pseudo-stopped, the pseudo-game ends and the main game is started. there is In the pseudo-game, since the specific numbers are aligned, if the reels 110 to 112 start rotating all at once in the following main game, depending on the player, it may be easier to stop aiming at the symbol. . That is, when the reels 110 to 112 start spinning all at once when a specific number is aligned, and when the reels 110 to 112 start rotating all at once when a particular number is not aligned, Advantages/disadvantages may occur in the operation of this game. In this embodiment, as shown in FIG. 21(c), when the reel rotation of the main game after the pseudo game is started, the reels 110 to 112 are sequentially rotated in the order of the left reel 110, the middle reel 111, and the right reel 112. As for the middle reel 111 and the right reel 112, the reels 110 to 112 are rotated after the lapse of a random predetermined time determined by lottery. With this configuration, the positions of the left reel 110, the middle reel 111, and the right reel 112 are varied without starting the rotation of the reels 110 to 112 all at once from the state in which specific numbers are aligned. In addition, as a configuration for distributing the positions, rotation may be started in an order other than the above order, and after individually setting a timer for the rotation start delay time for each reel 110 to 112, each timer may be counted down at the same time. After the left reel 110, the middle reel 111, and the right reel 112 start rotating, the operation of the stop buttons 137 to 139 in this game becomes valid after the rotation of all the reels becomes constant.

It should be noted that, in the present embodiment, the operation of the start lever 135 at the start of the pseudo-game is actually the operation of the start lever 135 for starting the game, and immediately after that, the process of the pseudo-game interrupts. There is no need to operate the start lever 135 immediately before the start of reel rotation. That is, after the pseudo stop, the reel rotation of this game is started without intervention of the player's operation. If the start lever 135 is operated within this period, the start timing of reel rotation (including random delay) in this game may be advanced.

In this embodiment, a configuration is adopted in which a pseudo-game is executed when shifting to the AT state, but for example, it may be executed in a state in which a special role is internally elected. By executing the pseudo-game in such a state that is advantageous to the player, it may be possible to improve the interest of the game. In addition, pseudo-games may be executed under certain conditions even in states other than such advantageous states. In this case, it may be possible to increase the interest in the game by making the player expect an advantageous situation.

In addition, the pseudo-game, for example, reel rotation and reel stop that are difficult to realize in this game (for example, reel control different from reel control in this game, such as reverse rotation of reels 110 to 112) Alternatively, for example, by increasing the number of games including pseudo-games, gambling properties may be reduced as a result. Moreover, it is good also as a structure by which a pseudo|simulation game is continuously performed several times.

[Notification of pseudo-games other than pseudo-stop]
In the pseudo-game explained in FIG. 21, it can be grasped that the pseudo-game is not the main game but the pseudo-game by the pseudo-stop. That is, it can be said that the pseudo-stop is one aspect of the notification that it is a pseudo-game (hereinafter referred to as pseudo-game notification).

In addition, in this embodiment, as shown in FIG. 22, a pseudo-game lamp 190 is provided on the right side of the shutter 163, and by turning on the pseudo-game lamp 190, it is possible to grasp that it is a pseudo-game. 22(a) shows the shutter 163 closed, FIG. 22(b) shows the shutter 163 half-open, and FIG. 22(c) shows the shutter 163 closed. is shown, the state of the pseudo-game lamp 190 can be confirmed in any state. Lighting of this pseudo-game lamp 190 is also one aspect of pseudo-game notification.

In this embodiment, when the image of the effect image display device 157 is visually recognized by the player, the shutter 163 is in an open state, and the shutter 163 is positioned between the effect image display device 157 and the pseudo game lamp 190. becomes (FIG. 22(c)). At this time, when the player gazes at the image of the performance image display device 157, the pseudo game lamp 190 is located outside the field of view across the shutter 163, so that the pseudo game lamp 190 is made inconspicuous as a result. can be done.

As for the pseudo-game lamp 190, as shown in FIG. 22(d), it may be described so that it can be understood that it is a lamp that lights up during the pseudo-game. This description is not limited to "during pseudo-game", but may be, for example, "free" or "free play". Further, in the present embodiment, the pseudo-game lamp 190 is controlled by the main control unit 300, but not limited to this configuration, it may be configured to be controlled by the first sub-control unit 400.

<Example of pseudo stop>
An example of the pseudo stop control during the pseudo game will be described with reference to FIGS. 23 and 24. FIG. FIG. 23(a) shows an example of pseudo-stopping with all BAR symbols (referred to as BAR pseudo-stop control). In the illustrated example, after the operation (start operation) of the start lever 135, the stop operation for the stop buttons 137 to 139 is performed in the order of left → middle → right, and the left reel 110 → middle reel 111 → right reel 112 is simulated in order. A stop is being made. However, the BAR pseudo-stop control does not care about the order of the stop operation, and when the BAR pseudo-stop control is selected, the BAR symbols are aligned and pseudo-stopped regardless of the stop timing of each reel. A pseudo RB game is started when the BAR symbols are aligned and the game is pseudo-stopped. Conversely, it can be said that the simulated stop of the BAR symbols is a notification effect suggesting the start of the simulated RB game.

FIG. 23(b) shows an example in which seven symbols are aligned and a pseudo stop is performed (referred to as seven pseudo stop control). Although the illustrated example shows an example in which the seven 1 symbols are aligned and the virtual stop is performed, the seven 2 symbols may be aligned and the pseudo stop is performed. It may be selected by lottery whether the target of the pseudo stop is the Seven 1 symbol or the Seven 2 symbol.

In the illustrated example, after the start operation, the stop operation is performed in the order of left → middle → right, and the pseudo stop is performed in the order of left reel 110 → middle reel 111 → right reel 112 . However, in the seven pseudo-stop control, the order of the stop operation does not matter, and when the seven pseudo-stop control is selected, the seven symbols are pseudo-stopped regardless of the stop timing of each reel. A pseudo BB game is started when the seven symbols are aligned and the game is pseudo-stopped. Conversely, it can be said that the quasi-stopping of the seven symbols is a notification performance suggesting the start of the quasi-BB game.

FIG. 23(c) shows an example in which after the BAR symbols are aligned and pseudo-stopped, the reels are rotated again and the seven symbols are aligned and pseudo-stopped (referred to as re-rotation seven pseudo-stop control). Although the illustrated example shows an example in which the seven 1 symbols are aligned and the virtual stop is performed, the seven 2 symbols may be aligned and the pseudo stop is performed. It may be selected by lottery whether the target of the pseudo stop is the Seven 1 symbol or the Seven 2 symbol.

In the illustrated example, after the start operation, the stop operation is performed in the order of left → middle → right, the pseudo stop of the BAR symbol is performed in the order of the left reel 110 → middle reel 111 → right reel 112, and then the seven symbol is stopped. All of them are pseudo-stopped. However, in the re-spin seven pseudo-stop control, the order of the stop operation is irrelevant, and when the re-spin seven pseudo-stop control is selected, regardless of the stop timing of each reel, the BAR symbols are aligned and pseudo-stopped. After that, the reels are rotated again, and the seven symbols are aligned and pseudo-stopped. A pseudo BB game is started when the seven symbols are aligned and the game is pseudo-stopped. Conversely, it can be said that the quasi-stopping of the seven symbols is a notification performance suggesting the start of the quasi-BB game. FIG. 23(c) illustrates an example in which after the BAR symbols are aligned and pseudo-stopped, the seven symbols are aligned and pseudo-stopped. may be pseudo-stopped.

FIGS. 24A to 24C show an example of automatic quasi-stop when the player does not perform the stop operation for a predetermined time after the start operation in the quasi-stop control. This may allow the game to proceed smoothly.

FIG. 24(a) shows an example of BAR pseudo stop control. If the stop operation is not performed for a predetermined time after the start operation, the pseudo stop is performed in the order of the left reel 110→middle reel 111→right reel 112, and the BAR symbols are aligned and the pseudo stop is performed. The first time is the time from the start operation until the BAR symbols are aligned and the game is pseudo-stopped.

FIG. 24(b) shows an example of seven pseudo-stop control. If the stop operation is not performed for a predetermined time after the start operation, the pseudo-stop is performed in the order of the left reel 110 → middle reel 111 → right reel 112, and the seven symbols (seven 1 symbol in the example of the figure) are aligned and pseudo-stopped. be. The second time is defined as the time from the start operation to the time when the seven symbols are aligned and the game is pseudo-stopped. The second time can be the same or different than the first time. The second time period may be longer than the first time period. If the second time is the same as the first time, it may be possible to smoothly proceed with the game regardless of the type of pseudo-stop symbol. Sometimes you can.

FIG. 24(c) shows an example of re-rotation seven pseudo-stop control. If the stop operation is not performed for a predetermined time after the start operation, the left reel 110→middle reel 111→right reel 112 are pseudo-stopped in this order. In Seven 1 pattern) are aligned and pseudo-stopped. The third time is the time from the starting operation to the time when the BAR symbols are aligned and the game is pseudo-stopped. The third time may be the same as at least one of the first time or the second time, may be the same as both, or may be different from both. The third period of time may be longer than the first period of time and the second period of time. If the third time is the same as the first time or the second time, it may be possible to smoothly proceed with the game, and if it is different, it may be possible to suggest the type of pattern that will be pseudo-stopped. In particular, if the third time is longer than the first time, the times when the same BAR symbols are aligned and the pseudo-stops are different, so it may be possible to suggest whether or not the reels will spin again.

<Direction in pseudo-game>
During the pseudo-game, various effects using images, light emission, and sound can be performed. Here, an example of an effect by an image displayed on the effect image display device 157 will be described.

FIG. 25(a) shows an example of displaying an effect image (referred to as BAR effect image) for instructing the player to stop the BAR design on the effect image display device 157 (referred to as BAR effect). The BAR effect is started by a start operation, and a BAR effect image is displayed during the period of the pseudo game stop operation.

During the BAR effect, when the chance button 165 is operated by the player, the effect image may be changed. FIG. 25(b) shows an example thereof. In the illustrated example, when the chance button 165 is operated by the player, the BAR effect image is terminated and switched to a effect image (referred to as a seven effect image) instructing the player to stop the Seven 1 symbol or Seven 2 symbol. . Such switching of effect images may allow the player to positively operate the chance button 165 . When the effect image is switched to the seven effect image, the seven effect image is displayed during the period of the stop operation of the pseudo game. In the case of this embodiment, even if the chance button 165 is operated after that, the effect image is not switched, but it may be switched under a specific condition.

During the BAR effect, even if the chance button 165 is operated by the player, the effect image may not be changed. FIG. 26(a) shows an example thereof. In the illustrated example, even if the chance button 165 is operated by the player, the BAR effect image is maintained. In the BAR effect, whether to switch the effect image triggered by the operation of the chance button 165 as shown in FIG. 25(b) or to maintain the effect image without switching as shown in FIG. 26(a) can be selected as the effect pattern. For example, the example of FIG. 25(b) may be selected with a probability of 50%, and the example of FIG. 26(a) may be selected with a probability of 50%. 25(b) and the example of FIG. 26(a) with a probability of 20%.

The switching of the effect image triggered by the operation of the chance button 165 illustrated in FIG. 25B may be performed when the chance button 165 is operated at any timing during the pseudo game, but this embodiment After the start operation, it is limited to the period before the first stop operation in the pseudo-game. Therefore, for example, even if the chance button 165 is operated after the first stop operation as in the example of FIG. 26(b), the effect image is not switched. By limiting the period during which the operation of the chance button 165 is valid, it may be possible to force the player to actively operate the chance button 165 . In particular, an advanced player who knows the effective section of the game can positively operate the chance button 165, and a beginner can be surprised when he accidentally operates the chance button 165 in the effective section. Sometimes we can.

Note that the chance button 165 may emit light in an operable manner from the start operation to the first stop operation. you can go

After the switching of the effect image triggered by the operation of the chance button 165 illustrated in FIG. 25(b), the effect image may be further switched by the stop operation in the pseudo game. FIG. 27(a) shows an example thereof. In the example of FIG. 27(a), the BAR effect image is displayed by the start operation, and the seven effect image is displayed with the chance button 165 as a trigger. Furthermore, triggered by the first stop operation,
Switching to a performance image (referred to as a single Seven performance image) for instructing the player to stop only the Seven 1 symbol.

Such switching of effect images may improve the interest of the player in the stop operation. In the illustrated example, the player is suggested to stop the Seven 1 symbol in the single Seven effect image, but the player may be suggested to stop only the Seven 2 symbol. Also, the trigger for switching from the seven effect image to the single seven effect image may be the second stop operation or the third stop operation instead of the first stop operation. The display of a single seven effect image is premised on the display of the seven effect image in the case of this embodiment, but it does not have to be premised.

FIG. 27(b) shows an example of a seven effect. The seven effect is started by a start operation, and a seven effect image is displayed on the effect image display device 157 unlike the BAR effect. In the seven effect, the seven effect image is displayed during the period of the stop operation of the pseudo game. In the present embodiment, in the seven effect, switching of the effect image triggered by the operation of the chance button 165 and switching of the effect image triggered by the stop operation are not performed. However, at least one of these switching may be performed, and in that case, the seven effect image may be switched to the single seven effect image. Alternatively, the seven effect image may be switched to the BAR effect image.

<Other production examples in pseudo-games>
In the present embodiment, the effect in the pseudo game does not prompt the player to operate the chance button 165 . By not performing such an effect, it may be possible to allow only those who have a lot of knowledge about the slot machine 100, such as advanced players, to actively operate the chance buttons 165. FIG. Moreover, when a game beginner accidentally operates the chance button 165, a surprise can be given.

On the other hand, it is of course possible to perform an effect to prompt the operation of the chance button 165 . FIG. 28(a) shows an example thereof. In the illustrated example, an effect image prompting the operation of the chance button 165 is displayed on the effect image display device 157 in response to the start operation. Triggered by the operation of the chance button 165, the seven effect image is displayed.

Next, in the present embodiment, in the effect in the pseudo-game, even if the stop operation is not performed, the effect to prompt the player to stop operation is not performed. By not performing such an effect, the effect data can be reduced.

On the other hand, it is of course possible to perform an effect to prompt the player to perform a stop operation. FIG. 28(b) shows an example thereof. In the illustrated example, an effect image prompting a stop operation is displayed on the effect image display device 157 when a predetermined time (time shorter than the time for automatic pseudo-stop) has elapsed since the start operation. The effect of prompting such a stop operation may be performed in the game.

<Processing when power is cut off or restored>
A description will be given of a case where the slot machine 100 is powered off due to a power outage or the like during a pseudo-game, and then restarted when the power supply is restored. When the power is cut off, each control unit saves the control information in the memory and shuts down, and when the power is restored, the saved control information can be read out to reproduce the state at the time of the power cut. However, if the state at the time of the power failure cannot be reproduced well for the performance during the pseudo-game, there is a case where the performance with a sense of discomfort is executed. Therefore, the performance during the pseudo-game may be interrupted by power failure, or the subsequent processing may be simplified.

FIGS. 29(a) to (c) show an example of an effect when power is cut off during a pseudo-game and then power is restored. FIG. 29(a) exemplifies a case in which, in a pseudo-game, a BAR effect is started by a start operation, and after a BAR effect image is displayed on the effect image display device 157, a power failure occurs.

FIG. 29(b) shows an example of an effect at the time of power recovery, in which the BAR effect is stopped and another image is displayed on the effect image display device 157. FIG. Other images are displayed until the end of the pseudo-game. Other images may be so-called demo screens or character images.

FIG. 29(c) shows another example of the effect at the time of power recovery. It is assumed that the chance button 165 has been operated in the BAR effect, and the effect image display device 157 displays the seven effect image triggered by this. ing. The seven effect image is displayed until the end of the pseudo-game. In some cases, it is possible to give the player the impression that the original state has been restored.

<Example of pseudo-game progress>
An example of a combination of pseudo stop control and effects in a pseudo game will be described with reference to FIGS. 30 to 37. FIG. The type of effect during the pseudo-game can be selected according to the type of pseudo-stop control, for example.

FIG. 30(a) shows an example in which the pseudo stop control is the seven pseudo control (FIG. 23(b)) and the effect is the BAR effect (switching by operating the chance button 165: FIG. 25(b)). showing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . Before the stop operation, the player operates the chance button 165, thereby switching the BAR effect image to the seven effect image. After that, the player sequentially performs a stop operation of the left reel 110 (left stop operation), a stop operation of the middle reel 111 (middle stop operation), and a stop operation of the right reel 112 (right stop operation), and seven 1 symbols are completed. is pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is displayed, and the player may have a premonition that the seven symbols will be aligned and the pseudo stop will be made. You may be able to operate it. In particular, an advanced game player who knows that the performance is switched (updated) can be made to positively operate the chance button 165, and a game beginner with poor knowledge of the game accidentally operates the chance button 165.例文帳に追加Sometimes you can give a surprise.

FIG. 30(b) also shows an example in which the pseudo stop control is the seven pseudo control (FIG. 23(b)) and the effect is the BAR effect (switching by operating the chance button 165: FIG. 25(b)). showing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . The player operates the chance button 165 after the player has performed the left stop operation and the Seven 1 symbol has been pseudo-stopped on the left reel 110 . However, since the operation of the chance button 165 is after the first stop operation, the effect image is not switched to the seven effect image, and remains the BAR effect image. After that, the player sequentially performs a middle stop operation and a right stop operation, and the Seven 1 symbols are aligned and pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is not displayed, so that the player may have a premonition that the seven symbols are aligned and the pseudo stop will not occur. Therefore, there are cases where the player can be given a sense of surprise and joy.

FIG. 31(a) also shows an example in which the pseudo stop control is the seven pseudo control (FIG. 23(b)) and the effect is the BAR effect (switching by operating the chance button 165: FIG. 25(b)). showing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . During the pseudo-game, the player does not operate the chance button 165, but sequentially performs the left stop operation, middle stop operation, and right stop operation. The effect image remains the BAR effect image, and the Seven 1 symbols are aligned and the game is pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

Since the BAR effect image is displayed and the seven effect image is not displayed, the player may have a premonition that the seven symbols are aligned and the pseudo stop will not occur. Therefore, there are cases where the player can be given a sense of surprise and joy.

FIG. 31(b) is an example in which the pseudo stop control is the seven pseudo control (FIG. 23(b)) and the effect is the BAR effect (no switching by operating the chance button 165: FIG. 26(a)). is shown.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . Although the player operates the chance button 165 before the stop operation, the effect image is not switched to the seven effect image and remains the BAR effect image. After that, the player sequentially performs a left stop operation, a middle stop operation, and a right stop operation. The effect image remains the BAR effect image, and the Seven 1 symbols are aligned and the game is pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is not displayed, so that the player may have a premonition that the seven symbols are aligned and the pseudo stop will not occur. Therefore, there are cases where the player can be given a sense of surprise and joy.

In FIG. 32(a), pseudo stop control is seven pseudo control (FIG. 23(b)), and the effect is BAR effect (switching by operation of chance button 165 and switching by first stop operation: FIG. 27(a)). is selected.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . Before the stop operation, the player operates the chance button 165, thereby switching the BAR effect image to the seven effect image. Thereafter, the player performs a left stop operation, and the effect image is further switched to a single Seven effect image (Seven 1 symbol). After that, the player sequentially performs a middle stop operation and a right stop operation, and the Seven 1 symbols are aligned and pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is displayed, and the player may have a premonition that the seven symbols will be aligned and the pseudo stop will be made. You may be able to operate it. Furthermore, by displaying a single Seven effect image triggered by the first stop operation, it may be possible for the player to have a premonition that the Seven 1 symbols will be aligned and the pseudo stop will be made, which improves the interest of the game. Sometimes we can.

FIG. 32(b) shows an example in which the pseudo stop control is the seven pseudo control (FIG. 23(b)) and the effect is the seven effect (FIG. 27(b)).

The start operation causes the reels 110 to 112 to rotate, and a seven effect image is displayed on the effect image display device 157 . The player sequentially performs a left stop operation, a middle stop operation, and a right stop operation, and the Seven 1 symbols are aligned and pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By displaying the seven effect image at the stage of the start operation, the player may have a premonition that the seven symbols are aligned and the game will be stopped, and the interest in the game can be improved.

FIG. 33(a) is an example in which the pseudo stop control is the BAR pseudo control (FIG. 23(a)) and the effect is the BAR effect (no switching by operating the chance button 165: FIG. 26(a)). is shown.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . The player sequentially performs a left stop operation, a middle stop operation, and a right stop operation, and the BAR symbols are aligned and the virtual stop is made. After that, the game is started, and an image suggesting the start of pseudo RB is displayed on the effect image display device 157 .

FIG. 33(b) also shows an example in which the pseudo stop control is the BAR pseudo control (FIG. 23(a)) and the effect is the BAR effect (no switching by operating the chance button 165: FIG. 26(a)). is shown.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . The player operates the chance button 165 before the stop operation, but the effect image is not switched to the seven effect image, and the BAR effect image is maintained. A left stop operation, a middle stop operation, and a right stop operation are sequentially performed, and the BAR symbols are aligned and pseudo-stopped. After that, the game is started, and an image suggesting the start of pseudo RB is displayed on the effect image display device 157 .

Since a pseudo-game such as that shown in FIG. 33(b) can also be executed, the player may positively operate the chance button 165 in order to predict the result of the pseudo-game, which may improve the interest in the game. be.

FIG. 34 shows an example in which the pseudo stop control is the re-rotation seven pseudo control (FIG. 23(c)) and the effect is the BAR effect (switching by operating the chance button 165: FIG. 25(b)). ing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . The player operates the chance button 165 after the player has performed the left stop operation and the BAR symbol has been pseudo-stopped on the left reel 110 . However, since the operation of the chance button 165 is after the first stop operation, the effect image is not switched to the seven effect image, and remains the BAR effect image. After that, the player sequentially performs a center stop operation and a right stop operation, the BAR symbols are aligned, and the reels 110 to 112 are spun again, and the seven 1 symbols are aligned, and the reels 110 to 112 are simulated to be stopped. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is not displayed, so that the player may have a premonition that the seven symbols are aligned and the pseudo stop is not performed. , the reels 110 to 112 are rotated again, and the Seven 1 symbols are aligned and pseudo-stopped.

FIG. 35 also shows an example in which the pseudo stop control is the re-rotation seven pseudo control (FIG. 23(c)) and the effect is the BAR effect (switching by operating the chance button 165: FIG. 25(b)). ing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . The player operates the chance button 165 before the stop operation, thereby switching the BAR effect image to the seven effect image. After that, the player sequentially performs a left stop operation, a middle stop operation, and a right stop operation, and the BAR symbols are aligned, resulting in a pseudo stop. there is After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is not displayed, so that the player may have a premonition that the seven symbols are aligned and the game is pseudo-stopped, but the BAR symbols are aligned and the pseudo-stop is made. By doing so, the player can recognize that the premonition is off, and the reels 110 to 112 are spun again and the Seven 1 symbols are aligned and pseudo-stopped, so that the player can have a sense of surprise and joy. Also, when the display of the seven effect image and the result of the pseudo-stop of the pseudo-game match, the chance button 165 can be positively operated by the player.

FIG. 36 also shows an example in which the pseudo stop control is the re-rotation seven pseudo control (FIG. 23(c)) and the effect is the BAR effect (switching by operating the chance button 165: FIG. 25(b)). ing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . The player performs a left stop operation and a right stop operation sequentially without operating the chance button 165, the BAR patterns are aligned and pseudo-stopped while the BAR effect image is continued, and the reels 110 to 112 are rotated again. The seven 1 symbols are aligned and the pseudo-stop is made. After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

When the BAR effect image is displayed and the BAR symbols are aligned and pseudo-stopped, the player has a premonition and recognizes that the seven symbols are not aligned and pseudo-stopped. Since the game is pseudo-stopped with the Seven 1 symbols aligned, the player may be given a sense of surprise and joy.

FIG. 37 shows an example in which the pseudo stop control is the re-rotation seven pseudo control (FIG. 23(c)) and the effect is the BAR effect (no switching by operating the chance button 165: FIG. 26(a)). showing.

The start operation causes the reels 110 to 112 to rotate, and the BAR effect image is displayed on the effect image display device 157 . Although the player operates the chance button 165 before the stop operation, the effect image is not switched to the seven effect image, and remains the BAR effect image. After that, the player sequentially performs a left stop operation, a middle stop operation, and a right stop operation, and the BAR symbols are aligned, resulting in a pseudo stop. there is After that, the game is started, and an image suggesting the start of pseudo BB is displayed on the effect image display device 157 .

By operating the chance button 165, the seven effect image is not displayed, so that the player may have a premonition that the seven symbols are aligned and the pseudo stop is not performed, and the BAR symbols are aligned and the pseudo stop is performed. In this case, the reels 110 to 112 are rotated again, and the Seven 1 symbols are aligned to make the player recognize that the player has a premonition. be.

<Internal structure>
FIG. 38 is a front view showing the slot machine 100 with its front door opened. The main body 101 is a box-shaped body surrounded by an upper plate 261, a left side plate 260, a right side plate 260, a lower plate 264 and a rear plate 242, and having an open front. Inside the main body 101, a main control board housing case 210 containing a main control board 300B (see FIG. 39) is arranged at a position that does not overlap with the ventilation port 249 provided on the upper part of the rear plate 242. A reel unit 700 having three reels 110 to 112 is arranged below the control board housing case 210 . On the side of the main control board storage case 210 and the reel unit 700, that is, on the left side plate 260, a sub control board storage case 220 containing the sub control board 400B (see FIG. 39) is arranged. be. A first selection switch 190 is provided in the sub control board housing case 220 . Since the first selection switch 190 is provided inside the main body 101, a person who can unlock the front door 102 (for example, a store clerk at an amusement shop, etc.) can open the front door 102. However, a person (for example, a player) who cannot unlock the front door 102 cannot operate. That is, the first selection switch 190 is provided at a position where the player cannot operate it. Details of the first selection switch 190 will be described later. Also, on the side plate 260 on the right side, an external centralized terminal board 248 is attached which is connected to the main control board 300B (see FIG. 39) and outputs information of the slot machine 100 to an external device.

A hopper unit 180 (a device for dispensing medals accumulated in a bucket) is arranged on the lower plate 264. Above the hopper unit 180, that is, below the reel unit 700, a power supply control board 252B (see FIG. 39) is provided. ) is provided, and a power switch 244 is provided in front of the power supply device 252 . The power supply device 252 converts AC power supplied from the outside to the slot machine 100 into DC power, converts it into a predetermined voltage, and supplies it to each control unit such as the main control unit 300 and the first sub-control unit 400, and each device. In addition, a power storage circuit (for example, a capacitor) is provided for supplying power to predetermined parts (for example, the RAM 308 of the main control unit 300, etc.) for a predetermined period (for example, 10 days) even after external power is cut off. there is

A medal auxiliary storage box 240 is arranged on the right side of the hopper unit 180, and an overflow terminal is arranged behind it (not shown). The power supply device 252 is provided with a power cord connection portion for connecting a power cord 265 , and the power cord 265 connected here extends to the outside through a power cord hole 262 opened in the back plate 242 of the main body 101 . there is

The front door 102 is hinged to the side plate 260 on the left side of the main body 101 via a hinge device 276, and above the pattern display window 113 is a production device 160 and a production control board ( not shown), and an upper speaker 272 is provided. Below the pattern display window 113, there are provided a medal selector 170 for sorting inserted medals, and a path 266 through which the medals pass when the medal selector 170 drops illegal medals onto the medal receiving tray 161. there is Furthermore, a bass speaker 277 is provided at a position corresponding to the sound hole 145 .

Each component of the main control section 300 described above is mounted on the main control section board 300B (see FIG. 39). Further, each component of the first sub-controller 400 described above is mounted on the first sub-controller board 400B (see FIG. 39).

Next, an example of connection between each board such as the power control board, the main control board and the first sub-control board and each unit such as the reel unit, the hopper unit and the effect movable body unit will be described.

FIG. 39 is a diagram showing an example of connection between each board and each unit. This FIG. 39 shows a power supply control board 252B, a main control board 300B, a first sub-control board 400B, a reel unit 700, a hopper unit 180, and an effect movable body unit 160U. The effect movable body unit 160U is a unit that is incorporated in the effect device 160 and moves the shutter 163 . The shutter 163 corresponds to an example of a movable body.

A plurality of connectors PC1 to PC4, MC1 to MC6 and SC1 to SC4 are shown on each of the power control board 252B, the main control board 300B and the first sub-control board 400B. Also, one or a plurality of connectors HC1, RC1 to RC3, DC1 are shown in each of the reel unit 700, the hopper unit 180 and the effect movable body unit 160U.

An island facility installed in a game machine installation office steps down a 100V AC power supply to a voltage of 24V, and a 24V AC current is supplied to the slot machine 100 through a power cord 265 connected to a connector PC1. The 24V AC current is converted into a 24V DC voltage, a 12V DC voltage and a 5V DC voltage in the power control board 252B. In addition, although it may be converted into other DC voltages, the DC voltage of 24V and the DC voltage of 5V will be explained here.

The power control board 252B shown in FIG. 39 shows a 24V power line and a 5V power line, and a power control 24V monitor LED 24PL and a power control 24V capacitor 24PC connected to the 24V power line and connected to the 5V power line. Also shown are power control 5V monitor LED 5PL and power control 5V capacitor 5PC. The power control 24V monitor LED 24PL is a power monitoring LED lamp that lights or blinks while a 24V DC current is flowing, and the power control 5V monitor LED 5PL lights or blinks while a 5V DC current is flowing. LED lamp for power supply monitoring. A power switch 244 is also shown.

A 24V power line and a 5V power line are connected to the connector PC2 of the power control board 252B. The connector PC2 and the connector MC5 of the main control board 300B are connected by a harness PM, and the main control board 300B is supplied with a direct current of 24 V and a direct current of 5 V through the harness PM. .

A 24V power line is connected to the connector PC3 of the power control board 252B. The connector PC3 and the connector SC1 of the first sub-control board 400B are connected by a harness PS1, and a 24V direct current is supplied to the first sub-control board 400B through this harness PS1. A 5V power line is connected to the connector PC4 of the power control board 252B. The connector PC4 and the connector SC2 of the first sub-control board 400B are connected by a harness PS2, and a direct current of 5V is supplied to the first sub-control board 400B through this harness PS2.

The main control board 300B may also be supplied with 24V and 5V through separate harnesses, like the first sub-control board 400B. Also, 24V and 5V may be supplied to the first sub-control board 400B through a common harness, like the main control board 300B.

The main control board 300B shown in FIG. 39 also shows a 24V power line and a 5V power line. A 24V DC current supplied through the harness PM flows through the 24V power supply line of the main control board 300B, and a 5V DC current also supplied through the harness PM flows through the 5V power supply line of the main control board 300B. . The main control board 300B shown in FIG. 39 also shows a main control 24V monitor LED 24ML and a main control 24V capacitor 24MC connected to the 24V power line, and a main control 5V monitor LED 5ML connected to the 5V power line. ing. The main control 24V monitor LED24ML is a power monitoring LED lamp that lights or blinks while a 24V DC current is flowing, and the main control 5V monitor LED5ML lights or blinks while a 5V DC current is flowing. LED lamp for power supply monitoring. Note that no capacitor is provided on the 5V power supply line.

A hopper motor driving IC 326i and a reel motor driving IC 322i are mounted on the main control board 300B. The hopper motor drive IC 326i is an integrated circuit that constitutes the drive circuit 326 shown in FIG. The reel motor drive IC 322i is an integrated circuit forming the drive circuit 322 shown in FIG. Both the hopper motor drive IC 326i and the reel motor drive IC 322i are supplied with a 24V DC current and a 5V DC current, respectively. Although not shown, the main control board 300B includes the above-described basic circuit 302, and integrated circuits that configure other drive circuits 324, 328, etc. are also mounted.

The connector MC1 of the main control board 300B, to which the hopper motor drive IC 326i is connected, and the connector HC1 of the hopper unit 180 are connected by a harness MH. The 24 V DC current and the 5 V DC current supplied to the hopper motor drive IC 326i are supplied to the hopper unit 180 through the harness MH, and the motor 180m provided in the hopper unit 180 can be driven. A control signal (command) for controlling the motor 180m is sent from the main control board 300B through the harness MH.

The connector MC2 connected to the reel motor drive IC 322i of the main control board 300B and the connector RC1 of the reel unit 700 are connected by a harness MR1. A connector RC2 of the reel unit 700 is connected by a harness MR2, and a connector MC4, to which the reel motor drive IC 322i is also connected, and a connector RC3 of the reel unit 700 are connected by a harness MR3. The reel unit 700 is supplied with the 24 V DC current and the 5 V DC current supplied to the reel motor drive IC 322i through these harnesses MR1 to MR3, respectively, and the motors 110m to 112m provided for each reel are driven. become drivable. Control signals (commands) for controlling the motors 110m to 112m are sent from the main control board 300B through the harnesses MR1 to MR3, respectively. Although a harness is connected to each motor, the connectors RC1 to RC3 on the reel unit 700 side are made into one connector, and the connectors MC2 to MC4 on the main control board 300B side are also made into one connector, and one common harness is used. You can connect with However, one common harness is a collection of three harnesses MR1 to MR3.

Furthermore, the connector MC6 of the main control board 300B and the connector SC4 of the first sub-control board 400B are connected by a harness MS. This harness MS is a harness for control signals (for command transmission) and is not used for current supply.

The first sub-control board 400B shown in FIG. 39 also shows a 24V power line and a 5V power line. A 24V direct current supplied through the harness PS1 flows through the 24V power supply line of the first sub-control board 400B, and a 5V direct current supplied through the harness PS2 flows through the 5V power supply line of the first sub-control board 400B. current flows. In addition, the first sub-controller board 400B shown in FIG. 39 also has a sub-control 24V monitor LED 24SL and a sub-control 24V capacitor 24SC connected to the 24V power supply line, and a sub-control 5V monitor LED 5SL connected to the 5V power supply line. It is shown. The sub-control 24V monitor LED 24SL is a power monitoring LED lamp that lights or blinks while a 24V DC current flows, and the sub-control 5V monitor LED 5SL lights or blinks while a 5V DC current flows. LED lamp for power supply monitoring. Also in the first sub-control board 400B, no capacitor is provided on the 5V power supply line.

A movable body motor drive IC 424i is mounted on the first sub-control board 400B. The movable body motor drive IC 424i is an integrated circuit that constitutes the drive circuit 424 described above. A DC current of 24V and a DC current of 5V are supplied to the movable body motor drive IC 424i. Although not shown here, the basic circuit 402 described above is configured on the first sub-control board 400B, and integrated circuits that configure other drive circuits 424 and 426 are also mounted.

The connector SC3 of the first sub-control board 400B, to which the movable body motor drive IC 424i is connected, and the connector DC1 of the effect movable body unit 160U are connected by a harness SD. The direct current of 24V and the direct current of 5V supplied to the movable body motor drive IC 424i are supplied to the movable body unit 160U through the harness SD, and the motor 163m provided in the movable body unit 160U is driven. be possible. A control signal (command) for controlling the motor 163m is sent from the first sub-control board 400B through the harness SD.

The slot machine 100 shown in FIG. 1 also includes the above-described second sub-control section 500, and although not shown in FIG. A direct current of 24V and a direct current of 5V are supplied respectively. Also, the second sub-control board is connected to the first sub-control board 400B with a harness for control signals (for command transmission). Furthermore, the second sub-control board is also connected to the effect device (effect image display device 157) in the same manner as the first sub-control board 400B.

As described above, the main control board 300B and the hopper unit 180 are electrically connected by the harness MH, and the main control board 300B and the reel unit 700 are also electrically connected by the harnesses MR1-MR3. Also, the first sub-control board 400B and the effect movable body unit 160U are electrically connected by a harness SD.

Here, FIG. 38 is a diagram showing how the front door 102 of the slot machine 100 in the power-off state is opened and the left reel 110 is manually rotated. The power-off state may be a state in which the power switch 244 is turned off, or a state in which the power switch 244 is turned on but the power cord 265 is not connected to the outlet. However, it may be in a state where no power is supplied from the island facility (the same shall apply hereinafter). If power is not supplied from the island facility, the power is cut off even if the power cord 265 is connected to the outlet and the power switch 244 is on. Each reel 110-112 can be manually rotated in either the forward or reverse direction even in such a power failure condition.

Any of the monitor LEDs (power control 24V monitor LED 24PL, power control 5V monitor LED 5PL, main control 24V monitor LED 24ML, main control 5V monitor LED 5ML, sub-control 24V monitor LED 24SL, sub-control 5V monitor LED 5SL shown in FIG. 39 that lights up in the energized state ) are also extinguished in the power failure state.

However, as shown in FIG. 38, when the left reel 110 is manually rotated, the motor 110m (see FIG. 39) that rotates the left reel 110 generates a current (induced current) due to back electromotive force. Continuing the description with reference to FIG. 39, the induced current generated by the motor 110m flows through the harness MR1 into the main control board 300B and is supplied from the reel drive IC 322i to the 24V power line and the 5V power line respectively. A main control 24V adjustment resistor 24MR is provided between the main control 24V monitor LED 24ML and the ground, and a main control 5V adjustment resistor 5MR is provided between the main control 5V monitor LED 5ML and the ground. The main control 24V monitor LED 24ML has its resistance adjusted by the main control 24V adjustment resistor 24MR, so that it is lit by the induced current, and the main control 5V monitor LED 5ML has its resistance adjusted by the main control 5V adjustment resistor 5MR. Lights up due to induced current. Further, even if manual rotation is stopped, the main control 24V monitor LED 24ML continues lighting for a while because the main control 24V capacitor 24MC is provided in the 24V power supply line. On the other hand, since the 5V power supply line is not provided with a capacitor, the main control 5V monitor LED 5ML immediately turns off when the manual rotation is stopped. That is, when manual rotation is stopped, the main control 5V monitor LED 5ML is turned off before the main control 24V monitor LED 24ML. A capacitor having a lower capacity than the main control 24V capacitor 24MC may also be provided on the 5V power supply line.

The induced current that has flowed into the main control board 300B this time flows through the harness PM into the power supply control board 252B, and is supplied from the connector PC2 to the 24V power line and the 5V power line. A power control 24V adjustment resistor 24PR is provided between the power control 24V monitor LED 24PL and the ground, and a power control 5V adjustment resistor 5PR is provided between the power control 5V monitor LED 5PL and the ground.

The power control 24V monitor LED 24PL has its resistance adjusted by the power control 24V adjustment resistor 24PR, so that it is lit by the induced current, and the power control 5V monitor LED 5PL has its resistance adjusted by the power control 5V adjustment resistor 5PR. Lights up due to induced current. Here, the LEDs of a plurality of boards such as the LEDs (24ML, 5ML) of the main control board 300B and the LEDs (24PL, 5PL) of the power supply control board 252B emit light.

Further, even if manual rotation is stopped, the power control 24V monitor LED 24PL continues lighting for a while because the power control 24V capacitor 24PC is provided in the 24V power line. In addition, since the power control 5V capacitor 5PC is also provided on the 5V power line, the power control 5V monitor LED 5PL also continues lighting for a while.

The induced current that has flowed into the power control board 252B further flows through the harness PS1 into the first sub-control board 400B and is supplied from the connector SC1 to the 24V power line. A secondary control 24V adjustment resistor 24SR is provided between the secondary control 24V monitor LED 24SL and the ground. A sub-control 5V adjustment resistor 5SR is provided between the sub-control 5V monitor LED 5SL and the ground. The secondary control 24V monitor LED 24SL is lit by an induced current due to the resistance value being adjusted by the secondary control 24V adjustment resistor 24SR.

Also, the induced current that has flowed into the power control board 252B flows through the harness PS2 into the first sub-control board 400B, and is supplied from the connector SC2 to the 5V power line. A sub-control 5V adjustment resistor 5SR is provided between the sub-control 5V monitor LED 5SL and the ground. The sub-control 5V monitor LED 5SL is lit by an induced current due to the resistance value being adjusted by the sub-control 5V adjustment resistor 5SR. Here, the LEDs of a plurality of substrates such as the LEDs (24ML, 5ML) of the main control substrate 300B, the LEDs (24PL, 5PL) of the power supply control substrate 252B, and the LEDs (24SL, 5SL) of the first sub-control substrate 400B emit light. There will be

Even if manual rotation is stopped, the sub-control 24V monitor LED 24SL continues lighting for a while because the sub-control 24V capacitor 24SC is provided in the 24V power supply line. On the other hand, since the 5V power supply line is not provided with a capacitor, the sub-control 5V monitor LED 5SL immediately turns off when the manual rotation is stopped.

The above description is a description of the phenomenon that occurs when the harnesses MR1, PM, PS1, and PS2 are normally connected to the connectors and are not disconnected. On the other hand, if the harness MR1 is broken or not properly connected to the connector RC1 and/or the connector MC2 (disconnected or insufficiently inserted), no matter how much the left reel 110 is manually rotated, the None of the monitor LEDs shown at 39 are illuminated, and the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML remain off.

As a result, even if the left reel 110 is manually rotated, if none of the monitor LEDs, the main control 24V monitor LED 24ML, and the main control 5V monitor LED 5ML shown in FIG. connection failure can be suspected.

Also, if the harness PM is disconnected or is not properly connected to the connector MC5 and/or the connector PC2, when the left reel 110 is manually rotated, the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML lights up, but the sub-control 24V monitor LED 24SL, the sub-control 5V monitor LED 5SL, the power control 24V monitor LED 24PL and the power control 5V monitor LED 5PL do not light up.

As a result, when the left reel 110 is manually rotated, although the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML are lit, the sub-control 24V monitor LED 24SL, sub-control 5V monitor LED 5SL, power control 24V monitor LED 24PL and If the power supply control 5V monitor LED 5PL is not lit, an abnormality in the harness PM or poor connection with the connectors MC5 and PC2 can be suspected.

Even when the main control board 300B is not connected to the power supply control board 252B during cleaning, maintenance, or manufacturing, the LEDs (24ML, 5ML) of the main control board 300B are lit by manually rotating the left reel 110. It is possible.

Also, if the harness PS1 is broken or not properly connected to the connector PC3 and/or the connector SC1, when the left reel 110 is manually rotated, the secondary control 24V of the monitor LEDs shown in FIG. Only the monitor LED 24SL does not light up. As a result, even if the left reel 110 is manually rotated, if only the sub-control 24V monitor LED 24SL among the monitor LEDs shown in FIG. can be done.

Furthermore, if the harness PS2 is disconnected or not normally connected to the connector PC4 and/or the connector SC2, when the left reel 110 is manually rotated, the sub control 5V of the monitor LEDs shown in FIG. Only the monitor LED5SL does not light up. As a result, even if the left reel 110 is manually rotated, if only the sub-control 5V monitor LED 5SL among the monitor LEDs shown in FIG. can be done.

Here, the case where the left reel 110 is manually rotated in the power failure state has been described, but even when the middle reel 111 is manually rotated in the power failure state, the right reel 112 can be manually rotated in the power failure state. The same is true when rotating. In addition, when the number of reels to be manually rotated increases, the monitor LED emits bright light. For example, when the left reel 110, middle reel 111 and right reel 112 are manually rotated at the same time, the monitor LED emits brighter light than when only the left reel 110 is manually rotated.

In addition, the main control 24V monitor LED24ML, the main control 5V monitor LED5ML, the sub-control 24V monitor LED24SL, the sub-control 5V monitor LED5SL, the power control 24V monitor LED24PL and the power control 5V monitor LED5PL LEDs used for different purposes from the monitor LED ( For example, even if an error monitoring LED that emits light when an error occurs, or a signal monitoring LED, etc.), if it is provided with an adjustment resistor on the 24V power line or 5V power line, it can be manually operated in the power failure state. When the left reel 110 is rotated, light is emitted if there is no electrical connection failure. Therefore, even if the LED is used for a purpose other than the monitor LED, it is possible to check for an electrical connection failure.

FIG. 40(a) is a perspective view of the hopper unit 180 shown in FIG. 38 as viewed obliquely from above. The connector HC1 shown in FIG. 39 is also shown in the hopper unit 180 shown in FIG. 40(a). The hopper unit 180 has a storage tank 181 for storing medals and a disk-shaped hopper disc 182 provided on the bottom surface of the storage tank 181 . Part of the hopper disk 182 is visible in FIG. 40(a). The hopper disk 182 is provided with six medal passing holes 1821 spaced apart in the circumferential direction. The medal passage hole 1821 is a hole of a size through which medals, which are game media, can pass. The hopper disk 182 is rotated by the motor 180m (see FIG. 39), and the medals stored in the storage tank 181 are dispensed through the medal passing holes 1821.

FIG. 40(b) is a diagram showing how the hopper disk 182 is manually rotated.

FIG. 40(b) shows the hopper disk 182 viewed from directly above, and six medal passage holes 1821 can be seen. Even in the power-off state, the hopper disk 182 can be manually rotated in both forward and reverse directions by inserting a finger into the medal passage hole 1821 .

When the hopper disk 182 is manually rotated, the motor 180m (see FIG. 39) that rotates the hopper disk 182 generates a current (induced current) due to back electromotive force. Continuing the description with reference to FIG. 39, the induced current generated by the motor 180m flows through the harness MH into the main control board 300B and is supplied from the hopper motor drive IC 326i to the 24V power line and the 5V power line. The main control 24V monitor LED 24ML has its resistance adjusted by the main control 24V adjustment resistor 24MR, so that it is lit by the induced current, and the main control 5V monitor LED 5ML has its resistance adjusted by the main control 5V adjustment resistor 5MR. Lights up due to induced current.

On the other hand, if the harness MH is disconnected or is not properly connected to the connector HC1 and/or the connector MC1, no matter how much the hopper disk 182 is manually rotated, none of the monitor LEDs shown in FIG. However, the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML remain off. As a result, even if the hopper disk 182 is manually rotated, if none of the monitor LEDs, the main control 24V monitor LED 24ML, and the main control 5V monitor LED 5ML shown in FIG. connection failure can be suspected.

After that, the induced current generated by the motor 180m of the hopper disk 182 flows through the power control board 252B to the first sub-control board 400B in the same way as the induced current generated by the motor 110m of the left reel 110 described above. If so, the monitor LEDs (24PL, 5PL, 24SL, 5SL) provided on the boards 252B and 400B are lit. Therefore, similarly to when the left reel 110 is manually rotated, even when the hopper disk 182 is manually rotated, it is possible to check for an electrical connection failure on the downstream side of the main control board 300B.

When the hopper disk 182 is manually rotated and the left reel 111 is also manually rotated while the power is off, the number of movable bodies to be manually rotated increases, so that the monitor LED emits bright light. Become.

Moreover, even in the power-off state, the shutter 163 shown in FIG. 1 can be manually opened and closed. When the shutter 163 is manually opened and closed, the motor 163m (see FIG. 39) that opens and closes the shutter 163 generates a current (induced current) due to back electromotive force. Continuing the description with reference to FIG. 39, the induced current generated by the motor 163m flows through the harness SD into the first sub-control board 400B, and is supplied from the movable body motor drive IC 424i to the 24V power line and the 5V power line respectively. be done. The secondary control 24V monitor LED 24SL is lit by the induced current because the resistance value is adjusted by the secondary control 24V adjustment resistor 24SR, and the secondary control 5V monitor LED 5SL is also adjusted in resistance value by the secondary control 5V adjustment resistor 5SR. Lights up due to induced current.

The induced current that has flowed into the first sub-control board 400B this time flows through the harness PS1 into the power supply control board 252B and is supplied from the connector PC3 to the 24V power line. The power control 24V monitor LED 24PL is lit by an induced current due to the resistance value being adjusted by the power control 24V adjustment resistor 24PR.

In addition, the induced current that has flowed into the first sub-control board 400B also passes through the harness PS2, flows into the power supply control board 252B, and is supplied from the connector PC4 to the 5V power line. The power control 5V monitor LED 5PL is also lit by an induced current due to the resistance value being adjusted by the power control 5V adjustment resistor 5PR. Here, the LEDs of a plurality of substrates such as the LEDs (24SL, 5SL) of the first sub-control substrate 400B and the LEDs (24PL, 5PL) of the power control substrate 252B emit light.

The induced current that has flowed into the power control board 252B further flows through the harness PM into the main control board 300B, and is supplied from the connector MC5 to the 24V power line and the 5V power line. The power control 24V monitor LED 24PL has its resistance adjusted by the power control 24V adjustment resistor 24PR, so that it is lit by the induced current, and the power control 5V monitor LED 5PL has its resistance adjusted by the power control 5V adjustment resistor 5PR. Lights up due to induced current. Here, the LEDs of a plurality of boards such as the LEDs (24PL, 5PL) of the power control board 252B, the LEDs (24SL, 5SL) of the first sub-control board 400B, and the LEDs (24ML, 5ML) of the main control board 300B emit light. There will be

The above explanation is for the phenomena that occur when the harnesses SD, PS1, PS2, and PM are normally connected to the connectors and are not disconnected. On the other hand, if the harness SD is disconnected or is not properly connected to the connector DC1 and/or the connector SC3, none of the monitor LEDs shown in FIG. , the sub-control 24V monitor LED 24SL and the sub-control 5V monitor LED 5SL remain off.

As a result, even if the shutter 163 is manually opened and closed, if none of the monitor LEDs, the sub-control 24V monitor LED 24SL, and the sub-control 5V monitor LED 5SL shown in FIG. A bad connection can be suspected.

Also, if the harness PS1 is disconnected or is not properly connected to the connector SC1 and/or the connector PC3, when the shutter 163 is manually opened and closed, the secondary control 24V monitor LED24SL and the secondary control 5V monitor LED5SL Although it lights up, the power control 24V monitor LED 24PL and the main control 24V monitor LED 24ML do not light up.

As a result, when the shutter 163 is manually opened and closed, the sub-control 24V monitor LED 24SL and the sub-control 5V monitor LED 5SL are lit, but the power supply control 24V monitor LED 24PL and the main control 24V monitor LED 24ML are not lit. , an abnormality in the harness PS1 and a poor connection with the connectors SC1 and PC3 can be suspected.

Furthermore, if the harness PS2 is disconnected or not properly connected to the connector SC2 and/or the connector PC4, when the shutter 163 is manually opened and closed, the sub-control 24V monitor LED24SL and the sub-control 5V monitor LED5SL Although it lights up, the power supply control 5V monitor LED 5PL and the main control 5V monitor LED 5ML do not light up.

As a result, when the shutter 163 is manually opened and closed, the sub-control 24V monitor LED 24SL and the sub-control 5V monitor LED 5SL are lit, but the power supply control 5V monitor LED 5PL and the main control 5V monitor LED 5ML are not lit. , an abnormality in the harness PS2 or a poor connection with the connectors SC2 and PC4 can be suspected.

Even when the first sub-control board 400B is not connected to the power supply control board 252B during cleaning, maintenance, or manufacturing, the LEDs (24SL, 5SL) of the first sub-control board 400B can be controlled by manually opening and closing the shutter 163. ) can be lit.

Also, if the harness PM is disconnected or is not properly connected to the connector PC2 and/or the connector MC5, when the shutter 163 is manually opened and closed, the main control 24V monitor of the monitor LEDs shown in FIG. Only LED24ML and main control 5V monitor LED5ML do not light up.

As a result, if only the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML out of the monitor LEDs shown in FIG. connection failure can be suspected.

FIG. 41 is a diagram showing an example in which a relay board is provided between the main control board 300B shown in FIG. 39 and the hopper unit 180 and reel unit 700 also shown in FIG. In the following, differences from the connection example described with reference to FIG. 39 will be mainly described, and redundant description may be omitted.

In FIG. 41, the connector MC5 and the connector MC6 provided on the main control board 300B are omitted. A hopper relay board 901B is shown between the main control board 300B and the hopper unit 180 shown in FIG. 41, and a reel relay board 902B is shown between the main control board 300B and the reel unit 700. It is

The hopper relay board 901B is provided with a connector HRM to which the harness MH1 connected to the connector MC1 of the main control board 300B is connected, and a connector HRH to which the harness MH2 connected to the connector HC1 of the hopper unit 180 is connected.

The reel relay board 902B is provided with a connector RRM1 to which the harness MR11 connected to the connector MC2 of the main control board 300B is connected, and a connector RRR1 to which the harness MR12 connected to the connector RC1 of the reel unit 700 is connected.

Also provided are a connector RRM2 to which the harness MR21 connected to the connector MC3 of the main control board 300B is connected, and a connector RRR2 to which the harness MR22 connected to the connector RC2 of the reel unit 700 is connected. Further, a connector RRM3 to which the harness MR31 connected to the connector MC4 of the main control board 300B is connected, and a connector RRR3 to which the harness MR32 connected to the connector RC3 of the reel unit 700 is connected are also provided.

Even in the connection example in FIG. 41, when the reels 110 to 112 are manually rotated in the power failure state, the monitor LEDs such as the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML light up if normal. However, if the plurality of harnesses MR11, MR12, MR21, MR22, MR21, and MR32 between the main control board 300B and the reel unit 700 are broken or not properly connected, the main control 24V monitor LED 24ML and Monitor LEDs such as the main control 5V monitor LED 5ML do not light up.

Also, even if the hopper disk 182 is manually rotated in the power failure state, the monitor LEDs such as the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML light up if normal. However, if the plurality of harnesses MH1 and MH2 between the main control board 300B and the hopper unit 180 are disconnected or not connected properly, the main control 24V monitor LED 24ML and the main control 5V monitor LED 5ML, etc. LED does not light up.

In the example of connection shown in FIG. 41, the number of harnesses and the number of connectors are increased compared to the example of connection shown in FIG. It is more likely that a poor physical connection will occur. However, an induced current can be generated by manual operation in a power-off state, and poor electrical connection can be easily confirmed from the lighting state of the monitor LED.

The hopper relay board 901B and the reel relay board 902B may also be provided with a 24V monitor LED and an adjustment resistor on the 24V power line, and a 5V monitor LED and an adjustment resistor on the 5V power line. An induced current is generated by manual operation in the power-off state, and if the monitor LED is normal, these monitor LEDs are also turned on, so that it is possible to confirm the electrical connection failure.

In the description here, the left reel 110, the middle reel 111, the right reel 112, the hopper disk 182 and the shutter 163 are used as the movable bodies, but the movable bodies are not limited to these, and any movable body driven by a motor can be used. good.

<Other embodiments>
In the above-described embodiment, it is configured to execute a pseudo-game without interposing this game after confirming that it will shift to the AT state, for example, after confirming that it shifts to the AT state It may be configured to notify that a pseudo game is executed after the game has been played several times (for example, three times) and the state is shifted to the AT state.

In the present embodiment, the slot machine 100 using medals (coins) as a game medium is shown as an example of a game table, but the present invention is not limited to this, and game balls (for example, pachinko balls) are used as games. It can be applied to slot machines, pachinko machines, arranged ball game machines, rock-paper game machines, smart balls, etc., which are used as media.

In addition, the slot machine is a slot machine that only exchanges electronic data without using medals, such as running on mobile terminals (smartphones, game machines) and personal computers by a program that simulates the operation based on the above configuration. In this case, the game medium contains digitized data corresponding to medals, and the game medium is inserted by inputting the digitized data from a predetermined external device (electronic storage device). Payout of game media includes outputting digitized data to a predetermined external device (electronic storage device).

<Summary of embodiment>
The above embodiments disclose at least the following gaming machines.

A1. The gaming machine (for example, 100) of the above embodiment is
production means (eg 157);
a first operating means (eg 137-139);
a second operating means (eg 165);
A game machine comprising
The effect means is a means capable of executing a first operation instruction effect (for example, a BAR effect image),
The effect means is a means capable of executing a second operation instruction effect (for example, a seven effect image),
the first operation instruction rendering is a rendering related to the operation of the first operating means;
the second operation instruction rendering is a rendering relating to the operation of the first operating means;
The rendering means is capable of ending the first operation instruction rendering and executing the second operation instruction rendering when the second operating means is operated while the first operation instruction rendering is being executed. means (for example, FIG. 30(a)),
It is characterized by
According to this embodiment, the amusement of the game can be enhanced in the game machine which can execute the effect when the operating means is operated. An advanced player who knows that the operation instruction presentation is updated can be made to positively operate the second operating means, and a beginner who is poor in game knowledge accidentally operates the second operating means. Sometimes you can give a surprise.

A2. In the above embodiment,
The effect means is a means that does not execute the effect (for example, FIG. 28(a)) prompting the operation of the second operation means while the first operation instruction effect is being executed.
It is characterized by
According to this embodiment, an advanced gamer who knows that the operation instruction effect will be updated can be made to actively operate the second operation means, and a game beginner who is poor in game knowledge can accidentally operate the second operation means. In some cases, a surprise can be given when the second operating means is operated.

A3. In the above embodiment,
Even if the first operation means is operated while the first operation instruction effect is being executed, and the second operation means is operated after the first operation means is operated, the first operation means is operated. It is a means for continuously executing the operation instruction effect (for example, FIG. 30 (b)),
It is characterized by
According to this embodiment, by restricting the section in which the operation of the second operation means is activated, it is possible for advanced gamers to actively operate the second operation means, and for beginners, It may be possible to give a surprise when the second operation means is accidentally operated in the valid section.

A4. In the above embodiment,
Even if the first operation means is operated while the first operation instruction effect is being executed, and the second operation means is operated after the first operation means is operated, the second operation means is operated. It is a means that does not execute the operation instruction effect (for example, FIG. 30 (b)),
It is characterized by
According to this embodiment, by restricting the section in which the operation of the second operation means is activated, it is possible for advanced gamers to actively operate the second operation means, and for beginners, It may be possible to give a surprise when the second operation means is accidentally operated in the valid section.

A5. In the above embodiment,
Equipped with display means (eg 110-112),
If the first operation means is not operated for a first period of time while the first operation instruction effect is being executed, the display means displays a display related to the second operation instruction effect (for example, FIG. 30 ( (a) in the case of FIG. 24(b)) can be displayed.
According to this embodiment, the game can proceed smoothly.

A6. In the above embodiment,
When the power is restored while the first operation instruction effect is being executed, the first operation instruction effect is not executed (for example, FIG. 29(b)),
It is characterized by
According to this embodiment, it may be possible to prevent the execution of an unnatural effect at the time of power failure and power recovery.

B1. The gaming machine (for example, 100) of the above embodiment is
production means (eg 157);
a first operating means (eg 137-139);
a second operating means (eg 165);
a display means (eg 110-111);
A game machine comprising
The effect means is a means capable of executing a first operation instruction effect (for example, a BAR effect image),
The effect means is a means capable of executing a second operation instruction effect (for example, a seven effect image),
the first operation instruction rendering is a rendering related to the operation of the first operating means;
the second operation instruction rendering is a rendering relating to the operation of the first operating means;
The rendering means is capable of ending the first operation instruction rendering and executing the second operation instruction rendering when the second operating means is operated while the first operation instruction rendering is being executed. means (e.g. Figure 35),
The display means, when the first operation means is operated while the first operation instruction effect is being executed, displays a display related to the first operation instruction effect (for example, a pseudo-stop of the BAR pattern). After that, means capable of displaying a display (for example, pseudo-stop of seven symbols) related to the second operation instruction effect (for example, FIG. 36),
It is characterized by
According to this embodiment, the amusement of the game can be enhanced in the game machine which can execute the effect when the operating means is operated. An advanced player who knows that the operation instruction presentation is updated can be made to positively operate the second operating means, and a beginner who is poor in game knowledge accidentally operates the second operating means. Sometimes you can give a surprise. Also, even if the second operation means is not operated, there are cases where the display related to the second operation instruction effect can be displayed to make the player aware of it.

B2. In the above embodiment,
The effect means is a means that does not execute the effect (for example, FIG. 28(a)) prompting the operation of the second operation means while the first operation instruction effect is being executed.
It is characterized by
According to this embodiment, an advanced gamer who knows that the operation instruction effect will be updated can be made to actively operate the second operation means, and a game beginner who is poor in game knowledge can accidentally operate the second operation means. In some cases, a surprise can be given when the second operating means is operated.

B3. In the above embodiment,
Even if the first operation means is operated while the first operation instruction effect is being executed, and the second operation means is operated after the first operation means is operated, the first operation means is operated. It is a means for continuously executing the operation instruction effect (for example, FIG. 30 (b)),
It is characterized by
According to this embodiment, by restricting the section in which the operation of the second operation means is activated, it is possible for advanced gamers to actively operate the second operation means, and for beginners, It may be possible to give a surprise when the second operation means is accidentally operated in the valid section.

B4. In the above embodiment,
Even if the first operation means is operated while the first operation instruction effect is being executed, and the second operation means is operated after the first operation means is operated, the second operation means is operated. It is a means that does not execute the operation instruction effect (for example, FIG. 30 (b)),
It is characterized by
According to this embodiment, by restricting the section in which the operation of the second operation means is activated, it is possible for advanced gamers to actively operate the second operation means, and for beginners, It may be possible to give a surprise when the second operation means is accidentally operated in the valid section.

B5. In the above embodiment,
If the first operation means is not operated for a first period of time while the first operation instruction effect is being executed, the display means displays a display related to the second operation instruction effect (for example, FIG. 30 ( 24(b) in a) or FIG. 24(c) in FIG. 34).
According to this embodiment, the game can proceed smoothly.

B6. In the above embodiment,
When the power is restored while the first operation instruction effect is being executed, the first operation instruction effect is not executed (for example, FIG. 29(b)),
It is characterized by
According to this embodiment, it may be possible to prevent the execution of an unnatural effect at the time of power failure and power recovery.

C1. The gaming machine (for example, 100) of the above embodiment is
production means (eg 157);
a first operating means (eg 137-139);
a second operating means (eg 165);
a display means (eg 110-111);
A game machine comprising
The effect means is a means capable of executing a first operation instruction effect (for example, a BAR effect image),
The effect means is a means capable of executing a second operation instruction effect (for example, a seven effect image),
the first operation instruction rendering is a rendering related to the operation of the first operating means;
the second operation instruction rendering is a rendering relating to the operation of the first operating means;
The rendering means is capable of ending the first operation instruction rendering and executing the second operation instruction rendering when the second operating means is operated while the first operation instruction rendering is being executed. is a means (for example, FIG. 30(a)),
The display means is capable of displaying a display related to the second operation instruction effect (for example, pseudo-stop of seven symbols) when the first operation means is operated while the first operation instruction effect is being executed. is a means (for example, FIG. 30(b), FIG. 31(a)),
It is characterized by
According to this embodiment, the amusement of the game can be enhanced in the game machine which can execute the effect when the operating means is operated. An advanced player who knows that the operation instruction presentation is updated can be made to positively operate the second operating means, and a beginner who is poor in game knowledge accidentally operates the second operating means. Sometimes you can give a surprise. Also, even if the second operation means is not operated, there are cases where the display related to the second operation instruction effect can be displayed to make the player aware of it.

C2. In the above embodiment,
The effect means is a means that does not execute the effect (for example, FIG. 28(a)) prompting the operation of the second operation means while the first operation instruction effect is being executed.
It is characterized by
According to this embodiment, an advanced gamer who knows that the operation instruction effect will be updated can be made to actively operate the second operation means, and a game beginner who is poor in game knowledge can accidentally operate the second operation means. In some cases, a surprise can be given when the second operating means is operated.

C3. In the above embodiment,
Even if the first operation means is operated while the first operation instruction effect is being executed, and the second operation means is operated after the first operation means is operated, the first operation means is operated. It is a means for continuously executing the operation instruction effect (for example, FIG. 30 (b)),
It is characterized by
According to this embodiment, by restricting the section in which the operation of the second operation means is activated, it is possible for advanced gamers to actively operate the second operation means, and for beginners, It may be possible to give a surprise when the second operation means is accidentally operated in the valid section.

C4. In the above embodiment,
Even if the first operation means is operated while the first operation instruction effect is being executed, and the second operation means is operated after the first operation means is operated, the second operation means is operated. It is a means that does not execute the operation instruction effect (for example, FIG. 30 (b)),
It is characterized by
According to this embodiment, by restricting the section in which the operation of the second operation means is activated, it is possible for advanced gamers to actively operate the second operation means, and for beginners, It may be possible to give a surprise when the second operation means is accidentally operated in the valid section.

C5. In the above embodiment,
If the first operation means is not operated for a first period of time while the first operation instruction effect is being executed, the display means displays a display related to the second operation instruction effect (for example, FIG. 30 ( (a) in the case of FIG. 24(b)) can be displayed.
According to this embodiment, the game can proceed smoothly.

C6. In the above embodiment,
When the power is restored while the first operation instruction effect is being executed, the first operation instruction effect is not executed (for example, FIG. 29(b)),
It is characterized by
According to this embodiment, it may be possible to prevent the execution of an unnatural effect at the time of power failure and power recovery.
D1. The amusement machine of the above embodiment is
light emitting means;
a movable body unit having a first movable body operable by being driven by a first motor;
a main control board that controls the progress of the game;
A game machine comprising
The movable body unit has a third movable body operable by being driven by a third motor,
The first motor is electrically connected to the light emitting means via a first harness,
The third motor is electrically connected to the light emitting means via a third harness,
When the first motor is driven by manually operating the first movable body in a power-off state, a current generated by the back electromotive force generated by the first motor flows into the light-emitting means. may emit light,
When the third motor is driven by manually operating the third movable body in a power-off state, a current due to a back electromotive force generated by the third motor flows into the light emitting means. may emit light,
The light emitting means does not move even when the first motor is driven, and does not move when the third motor is driven,
The light emitting means is provided above the movable unit,
The light emitting means is provided on the main control board,
It is characterized by

Although the present embodiment has been described above, it is not limited to the above-described embodiment, and various modifications and changes can be made to the embodiment of the present invention without departing from the gist of the present invention. , those involving such modifications and changes are also included in the technical scope of the present invention. In addition, the actions and effects described in the embodiments of the invention are merely examples of the actions and effects resulting from the present invention, and the actions and effects of the present invention are those described in the embodiments of the present invention. is not limited to

100 slot machines

Claims (1)

light emitting means;
a movable body unit having a first movable body operable by being driven by a first motor;
a main control board that controls the progress of the game;
A game machine comprising
The movable body unit has a third movable body operable by being driven by a third motor,
The first motor is electrically connected to the light emitting means via a first harness,
The third motor is electrically connected to the light emitting means via a third harness,
When the first motor is driven by manually operating the first movable body in a power-off state, a current generated by the back electromotive force generated by the first motor flows into the light-emitting means. may emit light,
When the third motor is driven by manually operating the third movable body in a power-off state, a current due to a back electromotive force generated by the third motor flows into the light emitting means. may emit light,
The light emitting means does not move even when the first motor is driven, and does not move when the third motor is driven,
The light emitting means is provided above the movable unit,
The light emitting means is provided on the main control board,
A playground characterized by:

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