JP6243871B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine using gaming media.

In a gaming machine such as a pachinko machine, various effects using an image display device including a liquid crystal screen, a sound output device (speaker), an electric accessory, etc. are performed, and a device for enhancing the interest of the player is made.
For example, an effect pattern is determined based on a lottery result of a symbol that is triggered by a game ball entering the start opening, and an effect image is displayed on the image display device according to the effect pattern, and voice output An effect is generally performed from the apparatus in which effect sounds such as music and sound effects flow (see Patent Document 1).

JP2015-062748A

  An object of the present invention is to provide a gaming machine capable of producing an effect that can enhance the interest of the game.

The present invention has been made to solve the above-described problems, and can be realized by the following modes.
The gaming machine according to the first aspect includes a determination unit that determines whether or not to execute a predetermined special game when the start condition is satisfied, and a variation that notifies the determination result based on the determination result by the determination unit. An effect control means for determining an effect and performing control to execute the variation effect, a storage means for storing audio information, and a control for outputting the effect sound from the audio output means as the variation effect based on the audio information. Audio control means for performing, when the production sound becomes the first production effect and the first production effect continuously output before becoming the specific production mode in the variation production Including a second variation effect sound indicating that the specific effect mode has been achieved and a third variation effect sound output during the specific effect mode, wherein the variation effect can be executed for one variation effect. Multiple different productions It comprises over de, the presentation control unit, with the establishment of a predetermined condition, selects one effect mode from the plurality of rendering modes on one variation effect, depending on the effect mode selected, a plurality of The first variation effect sound determining means for determining the first variation effect sound to be output from the first variation effect sound is further provided, and the sound control means until the first effect aspect is reached, the first variation effect sound. When the first variation effect sound determined by the sound determination means is continuously output and the specific effect mode is reached, any first variation effect sound is determined by the first variation effect sound determination means. The second variation effect sound is output at the same timing, the output of the first variation effect sound that has been output is limited, and the third variation effect sound is output after a predetermined period has elapsed after the second variation effect sound is output. Sound output That.

  Since it comprised as mentioned above, according to this invention, the game machine in which the production | presentation which can improve the interest of a game is realizable.

1 is a front view of a gaming machine according to an embodiment of the present invention. It is a schematic plan view which shows a part of embodiment of this invention. It is the perspective view which showed an example of the back side of the gaming machine which concerns on this embodiment. It is the block diagram which showed the structure of the game control apparatus with which the gaming machine which concerns on this embodiment is equipped. It is a block diagram of an image control board. It is the figure which showed an example of the jackpot determination table. It is the figure which showed an example of the symbol determination table which determines the stop symbol of a special symbol. It is the figure which showed an example of the hit normal symbol determination table. It is the figure which showed an example of the big hit end time setting data table. It is the figure which showed an example of the special electric accessory operation mode determination table which determines the opening / closing conditions of a special prize opening. It is the figure which showed the structure of the big winning opening open mode determination table for jackpots. It is the figure which showed the structure of the big winning opening open mode determination table for small hits. It is the figure which showed an example of the fluctuation pattern determination table of a normal gaming state (for low probability gaming states). It is the figure which showed an example of the fluctuation pattern determination table for high probability game states. It is the figure which showed an example of the fluctuation | variation pattern determination table for the specific game periods (for low probability game state) after a small hit. It is the figure which showed an example of the normal electric accessory operation mode determination table. It is a time chart which shows the energization timing of a start opening / closing solenoid for every table. It is the figure which showed an example of the prior determination table for determining in advance the result of the big hit lottery. It is a flowchart explaining the main process by the main control board. It is a flowchart explaining the timer interruption process by the main control board. It is a flowchart explaining the input control processing by a main control board. It is a flowchart explaining the 1st start port detection switch input process by a main control board. It is a flowchart explaining the prior determination process by a main control board. It is a flowchart explaining the gate detection switch input process by a main control board. It is a flowchart explaining the special figure special electricity control process by a main control board. It is a flowchart explaining the special symbol memory | storage determination processing by a main control board. It is a flowchart explaining the jackpot determination processing by the main control board. It is a flowchart explaining the special symbol fluctuation | variation process by a main control board. It is a flowchart explaining the special symbol stop process by a main control board. It is a flowchart explaining the jackpot game process by a main control board. It is a flowchart explaining the small hit game process by a main control board. It is a flowchart explaining the special game end process by a main control board. It is a flowchart explaining the common figure normal power control process by a main control board. It is a flowchart explaining the normal symbol variation process by a main control board. It is a flowchart explaining the normal electric accessory control process by a main control board. It is the figure which showed an example of the variation production pattern determination table based on the variation pattern of the special symbol in a 1st special symbol display apparatus. It is the figure which showed an example of the variation production pattern determination table based on the variation pattern of the special symbol in the 2nd special symbol display device. It is a flowchart explaining the main process by an effect control board. It is a flowchart explaining the timer interruption process by an effect control board. It is a flowchart explaining the command analysis process 1 by an effect control board. It is a flowchart explaining the command analysis process 2 by an effect control board. It is a flowchart explaining the change effect pattern determination process by an effect control board. It is a flowchart explaining the effect input control process by an effect control board. It is a flowchart explaining the main process by an image control board. It is a flowchart explaining the interruption process of an image control board. It is the figure which showed an example of the animation pattern for displaying the animation of a production pattern. It is the figure which showed an example of the display list comprised from a drawing control command group. It is a figure which shows the structure of the audio | voice control circuit which concerns on this embodiment. It is a flowchart explaining the audio | voice control process by an image control board. It is a flowchart explaining the master volume setting process by an image control board. It is a figure which shows an example of the audio | voice management table with which an image control board is provided (the 1). It is a figure which shows an example of the audio | voice management table with which an image control board is provided (the 2). It is a flowchart which shows the system sound setting process by an image control board. It is a flowchart which shows the effect sound setting process by an image control board. It is a flowchart explaining the process during audio | voice output by an image control board. It is a figure for demonstrating the audio | voice channel selection process by an image control board. It is a flowchart explaining the audio | voice channel selection process by the image control board concerning this embodiment. In the gaming machine of this embodiment, it is a figure explaining the confirmation sound emitted from an audio output device (speaker) when a cross key is operated while waiting for a customer (No. 1). In the gaming machine of this embodiment, it is a figure explaining the confirmation sound emitted from an audio | voice output apparatus (speaker) when a cross key is operated while waiting for a customer (the 2). In the gaming machine of this embodiment, it is a figure explaining the confirmation sound emitted from an audio | voice output apparatus (speaker) when a cross key is operated at the time of a fluctuation | variation. 61 is a flowchart for describing soft volume adjustment processing (using left and right keys) by the image control board described in FIGS. 58, 59, and 60. FIG. It is a flowchart explaining in detail the audio | voice output process by the audio | voice control circuit which concerns on this embodiment. It is FIG. (1) explaining the winning branch production performed with the game machine which concerns on this embodiment. It is a figure (the 2) explaining the winning branch production performed with the gaming machine concerning this embodiment. It is a timing diagram (the 1) which shows the audio | voice output aspect in the winning branch production of this embodiment. It is a timing diagram (the 2) which shows the audio | voice output aspect in the winning branch production of this embodiment. It is a timing diagram (the 3) which shows the audio | voice output aspect in the winning branch production of this embodiment. It is a timing diagram (the 4) which shows the voice output mode in the winning branch production of this embodiment. It is a figure explaining the output mode of the production sound in jackpot game in this embodiment. It is a figure which shows the timing of a background sound and sound effect when presentation mode switches. It is FIG. (1) which shows volume control in case a background sound and a sound effect overlap. It is FIG. (2) which shows volume control in case a background sound and a sound effect overlap. It is a figure which shows the notification effect determination table used when CPU of an effect control board selects a notification effect in this embodiment. FIG. 39 is a diagram (part 1) illustrating an example of effects selected / executed using the variable effect determination table illustrated in FIGS. 36 and 37 and the notice effect determination table illustrated in FIG. 48; FIG. 39 is a diagram (part 2) illustrating an example of an effect selected / executed using the variable effect determination table illustrated in FIGS. 36 and 37 and the notice effect determination table illustrated in FIG. 48; In the gaming machine according to the present embodiment, it is a diagram for explaining the winning sound that is emitted during the round game. It is a flowchart explaining the winning notification process in a round game by an image control board. It is a figure which shows the transition of the effect display accompanying the reach alerting | reporting effect in this embodiment. It is a timing diagram which shows the audio | voice output aspect in the specific production mode in the gaming machine of this embodiment. It is a figure which shows the stop mode of the production | presentation symbol in the gaming machine of this embodiment. It is a timing diagram which shows an example of the output aspect of the fluctuation | variation stop sound in case a some effect design temporarily stops fluctuation | variation simultaneously. In the gaming machine of the present embodiment, it is a timing diagram showing the output mode of the fluctuation stop sound when a plurality of effect symbols temporarily stop the fluctuation at the same time. It is a timing diagram which shows an example of the output aspect of a fluctuation | variation stop sound in case a production | presentation right and left temporarily stops a fluctuation | variation simultaneously at the time of reach production. In the gaming machine of the present embodiment, it is a timing diagram showing the output mode of the change stop sound when the left and right effect symbols temporarily stop changing at the time of reach effect. It is a figure which shows the aspect from the stop aspect of the production | presentation symbol in the gaming machine of this embodiment to immediately after a fluctuation | variation start. It is a timing diagram which shows an example of the output aspect of the fluctuation | variation start sound in the case where three effect symbols start to fluctuate simultaneously. In the gaming machine of this embodiment, it is a timing diagram showing an example of the output mode of the fluctuation start sound when three effect symbols start to fluctuate simultaneously.

Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings.
<Configuration of gaming machine>
FIG. 1 is a front view showing an example of a gaming machine according to the present embodiment, FIG. 2 is a schematic plan view showing a part of the pachinko gaming machine 1, and FIG. 3 is a back side of the gaming machine according to the present embodiment. FIG. 4 is a block diagram showing a configuration of a game control device provided in the gaming machine according to the present embodiment.

In the gaming machine 1 shown in FIG. 1, an inner frame (open / close frame) 3 is attached to an outer frame 2 attached to an island structure of a game hall so that the glass frame 4 can be opened / closed. It is installed.
A window 4a is formed in the glass frame 4, and a transparent plate 4b is attached to the window 4a. A game board 10 having a board surface on which a game ball is launched is mounted on the inner frame 3, and a game area 10a in which the game ball can roll and flow down between the board surface of the game board 10 and the transparent plate 4b on the front side thereof. Is formed. The transparent plate 4b is, for example, a glass plate and is detachably fixed to the glass frame 4.

  The glass frame 4 is connected to the outer frame 2 via a hinge mechanism portion 5 on one end side in the left-right direction (for example, the left side facing the gaming machine), and the other end in the left-right direction using the hinge mechanism portion 5 as a fulcrum. The side (for example, the right side facing the gaming machine) can be rotated in a direction to release from the outer frame 2. The glass frame 4 covers the game board 10 together with the glass plate 4b, and can be opened like a door with the hinge mechanism portion 5 as a fulcrum to open the inner part of the outer frame 2 including the game board 10. On the other end side of the glass frame 4, a lock mechanism for fixing the other end side of the glass frame 4 to the outer frame 2 is provided. The fixing by the lock mechanism can be released by a dedicated key. Further, the glass frame 4 is provided with a door opening switch 136 (see FIG. 3) for detecting whether or not the glass frame 4 is opened from the outer frame 2.

At the lower part of the glass frame 4 (the lower part of the window 4a), a tray unit 7 having a storage tray 6 (upper tray 6a and lower tray 6b) for storing game balls is provided. The effect button 8 (FIG. 2) that can be pressed, the cross key 40 (FIG. 2) that allows the player to perform various selection operations, and the game balls stored in the lower plate 6b are discharged to the outside of the gaming machine. A discharge button 9 is provided.
The effect button 8 is effective only when, for example, a message for operating the effect button 8 is displayed on the image display device 31 described later. The effect button 8 is provided with an effect button detection switch 8a (see FIG. 4), and when the effect button detection switch 8a detects a player's operation, a further effect is executed according to this operation.
Further, the cross key 40 is provided with a cross key detection switch 40 (up key detection switch 40a, down key detection switch 40b, left key detection switch 40c, right key detection switch 40d) (see FIG. 4).

  An operation handle 11 is provided on the lower right side of the glass frame 4. When the player touches the operation handle 11, the operation handle 11 detects that a touch sensor 11a (see FIG. 4) in the operation handle 11 has touched the operation handle 11, and a launch control board described later. A touch signal is transmitted to 160. Upon receiving a touch signal from the touch sensor 11a (see FIG. 4), the firing control board 160 permits energization of the firing solenoid 12a. When the rotation angle of the operation handle 11 is changed, the gear directly connected to the operation handle 11 rotates and the knob of the firing volume 11b (see FIG. 4) connected to the gear rotates. A voltage corresponding to the detection angle of the firing volume 11b is applied to a launching solenoid 12a provided in the game ball launching mechanism. When a voltage is applied to the firing solenoid 12a (see FIG. 3), the firing solenoid 12a operates according to the applied voltage, and the game ball is played with a strength according to the rotation angle of the operation handle 11. It is fired to the game area 10a of the board 10.

  An outer rail R1 and an inner rail R2 are provided around the game area 10a in the game board 10. The outer rail R1 and the inner rail R2 guide the game ball launched from the game ball launching mechanism when the operation handle 11 is operated to the upper part of the game area 10a. The game ball guided to the upper part of the game area 10a falls in the game area 10a. At this time, the game ball falls unpredictably by a plurality of nails and windmills provided in the game area 10a.

  A center member 12 is disposed substantially at the center of the game board 10. The center member 12 is provided with an image display device 31 composed of a liquid crystal display device and the like, and an effect accessory device 32 imitating a “sword”.

The game area 10a on the lower center side of the center member 12 is provided with a first start port 13 into which a game ball can enter. A second start port 14 is provided below the first start port 13. The second start port 14 has an open / close door 14b, and is controlled to move to a first mode in which the open / close door 14b is maintained in a closed state and a second mode in which the open / close door 14b is in an open state. . Therefore, when the second start port 14 is in the first mode, there is no opportunity for winning a game ball, and when it is in the second mode, the chance for winning a game ball is increased.
In the present embodiment, when the second start port 14 is controlled to the first mode, the game ball is prevented from entering the second start port 14. However, if there is less opportunity for a game ball to enter when being controlled to the first mode than when being controlled to the second mode, the second is being controlled to the first mode. A game ball may enter the start port 14. That is, the first aspect includes a state where it is impossible or difficult to enter the game ball into the second start port 14.

  The first start port 13 and the second start port 14 are respectively provided with a first start port detection switch 13a (see FIG. 4) and a second start port detection switch 14a for detecting the entrance of a game ball. When these detection switches detect the entry of game balls, a lottery for acquiring a right to execute a jackpot game, which will be described later (hereinafter referred to as a “hit lottery”), is performed. Also, when the first start port detection switch 13a and the second start port detection switch 14a detect the entry of a game ball, a predetermined prize ball (for example, 3 game balls) is paid out.

  In the gaming machine 1 of the present embodiment, when game balls enter the first start port 13 and the second start port 14, for example, three game balls are paid out. It is not always necessary to pay out when entering the ball. Further, for example, the number of payouts for the first start port 13 may be three, and the number of payouts for the second start port 14 may be one.

  In the game area 10a on both sides of the center member 12, gates 15 through which game balls can pass are provided. The gate 15 is provided with a gate detection switch 15a (see FIG. 4) for detecting the passage of the game ball. When the gate detection switch 15a detects the passage of the game ball, a normal symbol lottery described later is performed. .

  Further, the game area 10a on the right side of the center member 12 is provided with a first grand prize winning port 16 and a second grand prize winning port 17 through which game balls can be entered. For this reason, the game ball is configured not to win the first big prize opening 16 and the second big prize opening 17 unless the operation handle 11 is rotated greatly and the game ball is hit with a strong force.

  The first grand prize winning opening 16 is normally kept closed by the open / close door 16b, making it impossible for a game ball to enter. On the other hand, when a jackpot game, which will be described later, is started, the open / close door 16b is opened, and the open / close door 16b functions as a receiving tray for guiding the game ball into the first big winning opening 16, and the game ball is It is possible to enter the 1st prize opening 16. The first big prize opening 16 is provided with a first big prize opening switch 16a. When the first big prize opening switch 16a detects the entry of a game ball, a predetermined prize ball (for example, 15 pieces) Game balls) are paid out.

  The second big winning opening 17 is normally kept closed by the movable piece 17b, and it is impossible to enter the game ball. On the other hand, when a jackpot game, which will be described later, is started, the movable piece 17b is actuated and opened, and the movable piece 17b functions as a guide path for guiding the game ball into the second big prize opening 17, A game ball can enter the second grand prize opening 17. The second big prize opening 17 is provided with a second big prize opening switch 17a. When the second big prize opening switch 17a detects the entry of a game ball, a predetermined prize ball (for example, 15 pieces) Game balls) are paid out.

Furthermore, the game area 10a is provided with a plurality of general winning awards 18. When a game ball wins each of these general winning ports 18, a predetermined prize ball (for example, 10 game balls) is paid out.
At the bottom of the game area 10 a, game balls that have not entered any of the general winning opening 18, the first starting opening 13, the second starting opening 14, the first large winning opening 16, and the second large winning opening 17 Is provided with an outlet 19.

The image display device 31 displays an image while the game is not being performed or displays an image according to the progress of the game. In particular, when a game ball enters the first start port 13 or the second start port 14, the effect symbol 35 for notifying the player of the lottery result is variably displayed.
The production symbol 35 is, for example, a scroll of three symbols (numbers) of a first symbol (left symbol), a second symbol (right symbol), and a third symbol (middle symbol). Scrolling is stopped and a specific symbol (number) is displayed in an array.
As a result, while the symbols are being scrolled, the player is given an impression that the lottery is currently being performed, and the player is notified of the lottery result by the symbols displayed when the scrolling is stopped. By displaying various images, characters, and the like during the variation display of the effect symbol 35, a high expectation that the player may win a big hit is given to the player.

Although not shown, a fourth symbol is displayed on the image display device 31 in addition to the effect symbol 35. The fourth symbol is a symbol showing a variation state of the effect symbol 35 used for notifying the lottery result by the jackpot lottery process.
Note that the 4th symbol does not necessarily have to be displayed on the image display device 31 and may be displayed by providing a 4th symbol display lamp separately.

  On the upper part of the glass frame 4, a pair of left and right effect lighting devices 33 are provided. The effect lighting device 33 includes a plurality of lights, and performs various effects while changing the light irradiation direction and emission color of each light.

In addition, the effect lighting device 33 includes a plurality of lights, and performs various effects while changing the light irradiation direction and emission color of each light.
Further, although not shown in FIG. 1, the gaming machine 1 is provided with an audio output device 34 (see FIG. 4) including a speaker. In addition to the above-described each production device, BGM (background music), SE (sound effect) etc. are output, and the production by sound is also performed.

  On the lower left side of the game area 10a, a first special symbol display device 20, a second special symbol display device 21, a normal symbol display device 22, a first special symbol hold indicator 23, a second special symbol hold indicator 24, which will be described later. A display area 27 such as a normal symbol hold indicator 25 and a round number indicator 26 is provided.

  The said 1st special symbol display apparatus 20 alert | reports the jackpot lottery result performed when the game ball entered into the 1st start port 13, and is comprised by several LED. That is, a plurality of special symbols corresponding to the jackpot lottery result are provided, and the lottery result is displayed by displaying a special symbol (lighting mode) corresponding to the jackpot lottery result on the first special symbol display device 20. The person is notified. The special symbols displayed in this way are not displayed immediately, but are displayed in a stopped state after being displayed for a predetermined time (flashing).

More specifically, when a game ball enters the first start port 13, a lottery lottery will be performed. However, the lottery lottery result is not immediately notified to the player, and a predetermined time is passed. The player is notified when it has passed. Then, when a predetermined time has elapsed, a special symbol corresponding to the jackpot lottery result is stopped and displayed so that the player is notified of the lottery result.
The second special symbol display device 21 is for notifying the jackpot lottery result performed when a game ball has entered the second starting port 14, and the display mode is the first special symbol. This is the same as the display mode of special symbols on the display device 20.

  The normal symbol display device 22 is for informing a lottery result of a normal symbol that is performed when a game ball passes through the gate 15. As will be described in detail later, when the predetermined symbol is won by the normal symbol lottery, the normal symbol display device 22 is turned on, and then the second start port 14 is controlled to the second mode for a predetermined time. Note that the normal symbol does not immediately notify the lottery result when the game ball passes through the gate 15, and the normal symbol fluctuates, for example, the normal symbol display device 22 blinks until a predetermined time elapses. It is trying to display.

Furthermore, if a game ball enters the first start port 13 or the second start port 14 during a special symbol change display or a special game, which will be described later, and if the big hit lottery cannot be performed immediately, a certain condition The right to win a jackpot is reserved. More specifically, the right to win a jackpot where a game ball enters and is retained at the first start port 13 is retained as a first hold, and a game ball is retained and retained at the second start port 14. The jackpot lottery right is reserved as a second hold.
For both of these holds, the upper limit reserve number is set to 4, and the reserve number is displayed on the first special symbol hold indicator 23 and the second special symbol hold indicator 24, respectively.

The upper limit reserved number of normal symbols is also set to four, and the reserved number of normal symbols is displayed in the same manner as the first special symbol hold indicator 23 and the second special symbol hold indicator 24. Displayed on the instrument 25.
The round number display 26 is for informing the number of rounds of a round game performed during a special game described later.

  As shown in FIG. 3, a main control board 110, an effect control board 120, a payout control board 130, a power supply board 170, a game information output terminal board 27 and the like are provided on the back surface of the gaming machine 1. The power supply board 170 is provided with a power plug 171 for supplying power to the gaming machine and a power switch (not shown).

Next, the effect button 8 will be described.
The production button 8 is incorporated in the central portion of the dish unit 7.
The effect button 8 is configured to be able to advance and retreat over a normal operation position (not shown), a pressed position that is retracted downward from the normal operation position, and a protruding operation position that protrudes upward from the normal operation position. . The effect button 8 is configured to be able to be pressed from any position including the normal operation position and the protruding operation position to the pressed position.
In the present specification, the detailed structure of the effect button 8 is disclosed in, for example, Japanese Unexamined Patent Application Publication No. 2013-116168, and the description thereof is omitted.

<Configuration of game control device>
Next, a game control device that controls the progress of the game in the gaming machine 1 of the present embodiment will be described with reference to FIG.
In FIG. 4, the main control board 110 controls the basic operation of the game. The main control board 110 includes at least a one-chip microcomputer 114 including a main CPU 111, a main ROM 112, and a main RAM 113, and an input port and an output port (not shown) for main control.
The main CPU 111 reads out a program stored in the main ROM 112 based on an input signal from each detection switch and performs arithmetic processing, directly controls each device and display, or according to the result of the arithmetic processing. Send commands to other boards. The main RAM 113 functions as a data work area when the main CPU 111 performs arithmetic processing.

  On the input side of the main control board 110, there are a first start port detection switch 13a, a second start port detection switch 14a, a gate detection switch 15a, a first large winning port detection switch 16a, a second large winning port detection switch 17a, A general winning opening detection switch 18 a is connected to input a detection signal of a game ball to the main control board 110.

Further, on the output side of the main control board 110, a start opening / closing solenoid 14c for opening / closing the opening / closing door 14b of the second start opening 14 and a first large winning opening for opening / closing the opening / closing door 16b of the first large winning opening 16 are provided. An open / close solenoid 16c and a second large prize opening opening / closing solenoid 17c for opening / closing the movable piece 17b of the second big prize opening 17 are connected.
Further, on the output side of the main control board 110, a first special symbol display device 20, a second special symbol display device 21, a normal symbol display device 22, a first special symbol hold indicator 23, a second special symbol hold indicator. 24, a normal symbol hold display unit 25, and a round number display unit 26 are connected to output various signals via the output port.
Further, the main control board 110 outputs an external information signal necessary for managing the gaming machine in the hall computer or the like of the gaming store to the gaming information output terminal board 27.

The main ROM 112 of the main control board 110 stores a game control program to be described later, data and tables necessary for various games.
The main RAM 113 of the main control board 110 has a plurality of storage areas.
For example, the main RAM 113 includes a normal symbol hold count (G) storage area, a normal symbol hold storage area, a first special symbol hold count (U1) storage area, a second special symbol hold count (U2) storage area, and a determination storage area. , First special symbol storage area, second special symbol storage area, high probability game count (X) storage area, time-short game count (J) storage area, round game count (R) storage area, release count (K) storage area , First grand prize opening number (C1) storage area, second big prize opening number (C2) storage area, gaming state storage area, gaming state buffer, stop symbol data storage area, effect transmission data storage area Etc. are provided. The game state storage area includes a short-time game flag storage area, a high-probability game flag storage area, a special-purpose special electric processing data storage area, and a general-purpose normal electric processing data storage area. Note that the storage area described above is merely an example, and many other storage areas are provided.

  The game information output terminal board 27 is a board for outputting an external information signal generated in the main control board 110 to a hall computer or the like of the game shop. The game information output terminal board 27 is connected to the main control board 110 by wiring and is provided with a connector for connecting to a hall computer or the like of a game store.

The power board 170 converts the power supply voltage supplied from the power plug 171 into a predetermined voltage and supplies it to each control board. The power supply board 170 is provided with a backup power supply composed of a capacitor, monitors the power supply voltage supplied to the gaming machine, and outputs a power interruption detection signal to the main control board 110 when the power supply voltage falls below a predetermined value. To do. More specifically, when the power interruption detection signal becomes high level, the main CPU 111 enters an operable state, and when the power interruption detection signal becomes low level, the main CPU 111 enters an operation stop state. The backup power source is not limited to a capacitor, and for example, a battery may be used, and a capacitor and a battery may be used in combination.
The main control board 110 is connected with a magnetic sensor 50 for detecting unauthorized radio waves.

The effect control board 120 mainly controls each effect such as during a game or standby. The effect control board 120 includes a sub CPU 121, a sub ROM 122, and a sub RAM 123, and is connected to the main control board 110 so as to be able to communicate in one direction from the main control board 110 to the effect control board 120. .
The sub CPU 121 reads and calculates a program stored in the sub ROM 122 based on a command transmitted from the main control board 110 or an input signal from the effect button detection switch 8a input via the lamp control board 140. A process is performed, and corresponding data is transmitted to the lamp control board 140 or the image control board 150 based on the process. The sub RAM 123 functions as a data work area when the sub CPU 121 performs arithmetic processing.

The sub ROM 122 of the effect control board 120 stores an effect control program, data necessary for various games, and a table.
For example, a variation effect pattern determination table (not shown) for determining an effect pattern based on a variation pattern designation command received from the main control board 110, and an effect symbol pattern determination for determining a combination of effect symbols 35 to be stopped and displayed. A table (not shown) or the like is stored in the sub ROM 122. Note that the above-described table is merely an example of characteristic tables among the tables in the present embodiment, and a number of other tables and programs (not shown) are provided for the progress of the game. ing.

The sub RAM 123 of the effect control board 120 has a plurality of storage areas.
The sub-RAM 123 includes a command reception buffer, a gaming state storage area, an effect mode storage area, an effect pattern storage area, an effect symbol storage area, a determination storage area (0th storage area), a first reservation storage area, and a second reservation storage area. Etc. are provided. The storage area described above is merely an example, and a large number of other storage areas are provided.

The effect control board 120 is equipped with an RTC (real time clock) 124 for outputting the current time. The sub CPU 121 receives a date signal indicating the current date and a time signal indicating the current time from the RTC 124, and executes various processes based on the current date and time.
The RTC 124 normally operates with power from the gaming machine when power is supplied to the gaming machine, and with power supplied from a backup power source mounted on the power supply board 170 when the gaming machine is powered off. Operate. Therefore, the RTC 124 can count the current date and time even when the gaming machine is turned off. Note that the RTC 124 may be operated by providing a battery on the effect control board 120.

  The payout control board 130 performs game ball launch control and prize ball payout control. The payout control board 130 includes a payout CPU 131, a payout ROM 132, and a payout RAM 133, and is connected to the main control board 110 so as to be capable of bidirectional communication. The payout CPU 131 reads out the program stored in the payout ROM 132 based on the input signals from the payout ball counting switch 135 and the door opening switch 136 for detecting whether or not the game ball has been paid out, and performs arithmetic processing. Based on this processing, corresponding data is transmitted to the main control board 110.

The payout control board 130 is connected to a payout motor 134 of a prize ball payout device for paying out a predetermined number of prize balls from the game ball storage unit to the player. The payout CPU 131 reads out a predetermined program from the payout ROM 132 based on the payout number designation command transmitted from the main control board 110, performs arithmetic processing, and controls the payout motor 134 of the prize ball payout device to execute a predetermined prize. Pay the ball to the player. At this time, the payout RAM 133 functions as a data work area during the calculation process of the payout CPU 131.
Also, it is confirmed whether or not a game ball lending device (card unit) (not shown) is connected to the payout control board 130, and if the game ball lending device (card unit) is connected, the game control ball 160 is caused to fire a game ball. Send launch control data to allow that.
In addition, a dish full tank detection switch 51 and a ball clogging detection switch 52 are connected to the payout control board 130.
The dish full tank detection switch 51 is a switch for detecting that the storage tray (lower dish) of the game balls is full.
The ball clogging detection switch 52 is a switch for detecting clogging of game balls in a passage for paying out game balls from a game ball storage unit, for example.

  When the launch control board 160 receives the launch control data from the payout control board 130, the launch control board 160 permits the launch. Then, the touch signal from the touch sensor 11a and the input signal from the launch volume 11b are read out, the energization control is performed on the launch solenoid 12a and the ball feed solenoid 12b, and the game ball is fired.

The firing solenoid 12a is composed of a rotary solenoid. A launching member (not shown) is directly connected to the firing solenoid 12a, and the launching member is rotated by the rotation of the firing solenoid 12a.
Here, the rotational speed of the firing solenoid 12a is set to about 99.9 (times / minute) based on the frequency based on the output period of the crystal oscillator provided on the firing control board 160. Accordingly, the number of game balls to be fired in one minute is about 99.9 (pieces / minute) because one ball is fired every time the firing solenoid rotates. That is, the game ball is fired about every 0.6 seconds.
The ball feed solenoid 12b is composed of a linear solenoid, and sends out the game balls on the upper plate 6a (see FIG. 1) one by one toward the launching member directly connected to the firing solenoid 12a.

The lamp control board 140 is connected to the effect control board 120 so as to be capable of bidirectional communication, and an effect button detection switch 8a provided on the effect button 8 is connected to the input side of the lamp control board 140. When a detection signal is input from 8a, it is output to the effect control board 120.
The lamp control board 140 is connected to the effect accessory device 32 and the effect lighting device 33 provided on the game board 10, and the lamp control board 140 is connected to the data transmitted from the effect control board 120. Based on this, lighting control of the lighting device for effect 33 is performed, or drive control for the motor for changing the light irradiation direction is performed. In addition, energization control is performed on a drive source such as a solenoid or a motor that operates the effect accessory device 32. In the present embodiment, the production effect device 32 includes the production buttons 8 because the production buttons 8 are configured to protrude.

  The image control board 150 is connected to the effect control board 120 so as to be capable of bidirectional communication, and the image display device 31 and the audio output device 34 are connected to the output side thereof.

<Image control board configuration>
Here, the configuration of the image control board 150 will be described with reference to FIG.
FIG. 5 is a block diagram showing the configuration of the image control board.
The image control board 150 includes a host CPU 151, a host RAM 152, a host ROM 153, a CGROM 154, a crystal oscillator 155, a VRAM 156, and a VDP (Video Display Processor) 200 for performing image display control of the image display device 31.
As will be described later, the VDP 200 includes a voice control circuit 300 for controlling voice output in the gaming machine.

The host CPU 151 instructs the image display device 31 to display the image data stored in the CGROM 154 on the VDP 200 based on the later-described effect pattern designation command received from the effect control board 120. Such an instruction is performed by setting data in the control register 201 of the VDP 200 and outputting a display list including drawing control command groups.
In addition, when receiving a V blank interrupt signal or a drawing end signal from the VDP 200, the host CPU 151 appropriately performs an interrupt process.

Further, the host CPU 151 also instructs the audio control circuit 300 included in the VDP 200 to output predetermined audio data to the audio output device 34 based on the effect pattern designation command received from the effect control board 120.
The host RAM 152 is built in the host CPU 151, functions as a data work area when the host CPU 151 performs arithmetic processing, and temporarily stores data read from the host ROM 153.

The host ROM 153 is composed of a mask ROM, and displays a program for controlling the host CPU 151, symbol arrangement information in which the symbol number of the effect symbol is associated with the type of the effect symbol 35, and a display for generating a display list. A list generation program, an animation pattern for displaying an animation of a production pattern, animation scene information, and the like are stored.
This animation pattern is referred to when displaying the animation of the production pattern, and stores the combination of animation scene information included in the production pattern, the display order of each animation scene information, and the like. The animation scene information stores information such as weight frame (display time), target data (sprite identification number, transfer source address, etc.), parameters (sprite display position, transfer destination address, etc.), drawing method, etc. doing.

The CGROM 154 includes a flash memory, an EEPROM, an EPROM, a mask ROM, and the like. The CGROM 154 compresses and stores image data (sprite, movie) or the like including a collection of pixel information in a predetermined range of pixels (for example, 32 × 32 pixels). ing. The pixel information is composed of color number information for designating a color number for each pixel and an α value indicating the transparency of the image.
Furthermore, the CGROM 154 stores palette data in which color number information for designating color numbers and display color information for actually displaying colors are associated with each other without being compressed.
Note that the CGROM 154 may have a configuration in which only a part of the image data is compressed without being compressed. As a movie compression method, various known compression methods such as MPEG4 can be used.
The CGROM 154 also stores a lot of audio data as will be described later.

  The crystal oscillator 155 outputs a pulse signal to the clock generation circuit 205 of the VDP 200, and divides the pulse signal to synchronize with the system clock for the VDP 200 to control by the clock generation circuit 205 and the image display device 31. A synchronization signal or the like is generated for the purpose.

The VRAM 156 is configured by an SRAM that can write or read image data at high speed.
The VRAM 156 also draws or displays an image, a display list storage area 156a that temporarily stores the display list output from the host CPU 151, a development storage area 156b that stores image data decompressed by the decompression circuit 206, and the like. A first frame buffer 156c and a second frame buffer 156d. The VRAM 156 also stores palette data.
The two frame buffers 156c and 156d are alternately switched between a “drawing frame buffer” and a “display frame buffer” each time drawing is started.

The VDP 200 is a so-called image processor, reads image data from one of the frame buffers (display frame buffer) based on an instruction from the host CPU 151, and a video signal (RGB signal or the like) based on the read image data. Is generated and output to the image display device.
However, in the gaming machine of the present embodiment, the VDP 200 is not only an image processor, but has an audio output function.
The VDP 200 includes a control register 201, a CG bus I / F 202, a CPU I / F 203, a clock generation circuit 205, a decompression circuit 206, a drawing circuit 207, a display circuit 208, a memory controller 209, and audio control. And a circuit 300.

The control register 201 is a register for the VDP 200 to control drawing and display, and drawing control and display control are performed by writing and reading data to and from the control register 201. The host CPU 151 can write and read data to and from the control register 201 via the CPU I / F 203.
The control register 201 is a system control register that performs basic settings necessary for the operation of the VDP 200, a data transfer register that performs settings necessary for data transfer, and a drawing that performs settings for controlling drawing. A register, a bus interface register for making settings necessary for bus access, a decompression register for making settings necessary for decompressing a compressed image, a display register for making settings for controlling display, and six types It has a register.

The CG bus I / F 202 is an interface circuit for communication with the CGROM 154, and image data from the CGROM 154 is input to the VDP 200 via the CG bus I / F 202.
The CPU I / F 203 is an interface circuit for communication with the host CPU 151, and the host CPU 151 outputs a display list to the VDP 200, accesses a control register, and various types of information from the VDP 200 via the CPU I / F 203. The host CPU 151 inputs an interrupt signal.

The data transfer circuit 204 performs data transfer between various devices.
Specifically, data transfer between the host CPU 151 and the VRAM 156, data transfer between the CGROM 154 and the VRAM 156, and data transfer between various storage areas (including the frame buffer) of the VRAM 156 are performed.
The clock generation circuit 205 receives a pulse signal from the crystal oscillator 155 and generates a system clock that determines the operation processing speed of the VDP 200. Also, a synchronization signal generation clock is generated, and the synchronization signal is output to the image display device via the display circuit.

The decompression circuit 206 is a circuit for decompressing the image data compressed in the CGROM 154, and stores the decompressed image data in the expanded storage area 153b.
The drawing circuit 207 is a circuit that performs sequence control based on a display list including drawing control commands.

The display circuit 208 generates an RGB signal (analog signal) indicating image color data as a video signal from the image data (digital signal) stored in the “display frame buffer” in the VRAM 156, and generates the generated video signal ( (RGB signal) to the image display device 31. Further, the display circuit 208 also outputs a synchronization signal (vertical synchronization signal, horizontal synchronization signal, etc.) for synchronizing with the image display device 31 to the image display device 31.
In the present embodiment, an RGB signal obtained by converting a digital signal into an analog signal is output to the image display device 31 as the video signal. However, the video signal may be output as the digital signal.

The memory controller 209 performs control to switch between the “drawing frame buffer” and the “display frame buffer” when the host CPU 151 instructs to switch the frame buffer.
The sound control circuit 300 reads a predetermined program based on the command transmitted from the effect control board 120 and controls sound output in the sound output device 34.
The voice control circuit 300 outputs voice using the voice data stored in the CGROM 154. In this case, the CGROM 154 includes an audio ROM 400 for storing audio data.

Note that the audio data is not stored in the CGROM 154, but the sound source ROM 400 may be provided separately in the VDP 154.
In this case, audio data is not stored in the CGROM 154 having a fixed capacity, and more image data can be stored. Therefore, the production using video can be made more colorful and impressive.

  Further, the audio control circuit 300 may not be included in the VDP 200 but may be provided independently within the image control board 150. In that case, the sound source ROM 400 may be included in the sound control circuit 300.

  Next, details of various tables stored in the main ROM 112 will be described with reference to FIGS.

<Big hit judgment table>
FIGS. 6 (a) and 6 (b) are diagrams showing an example of a jackpot determination table that is referred to when determining whether or not the special symbol variation stop result is a jackpot. FIG. FIG. 6B is a jackpot determination table referred to in the second special symbol display device 21. FIG. 6B is a jackpot determination table referred to in the first special symbol display device. In the tables of FIG. 6 (a) and FIG. 6 (b), the big hit probability is the same although the winning probability for the small hit is different.

  The jackpot determination table shown in FIGS. 6 (a) and 6 (b) is composed of a low probability random number determination table and a high probability random number determination table. A random number determination table is selected, and one of “big hit”, “small hit”, and “lack” is determined based on the selected table and the extracted random numbers for special symbol determination.

  For example, according to the low probability random number determination table of the first special symbol display device 20 shown in FIG. 6A, two special symbol determination random numbers “7” and “317” are determined to be big hits. . On the other hand, according to the high probability random number determination table, “7”, “37”, “67”, “97”, “127”, “157”, “187”, “217”, “247”, “277” , “317”, “337”, “367”, “397”, “427”, “457”, “487”, “517”, “547”, “577” 20 special symbol determination random numbers Is determined to be a big hit.

Further, regardless of whether the low probability random number determination table or the high probability random number determination table is used, the special symbol determination random number values are “50”, “100”, “150”, and “200”. If it is a random number value for symbol determination, it is determined as “small hit”. If the random number is other than the above, it is determined as “lost”.
Accordingly, since the random number range of the special symbol determination random number value is 0 to 598, in the jackpot determination table of the first special symbol display device 20, the probability of being determined to be a jackpot at a low probability is 1 / 299.5, The probability of being determined to be a big hit at a high probability is 10 times, which is 1 / 29.95. In addition, the probability determined to be a small hit is 1 / 149.75 for both low and high probabilities.

On the other hand, in the jackpot determination table of the second special symbol display device 21 shown in FIG. 6B, the special symbol determination random number value determined to be a jackpot at the low probability and the high probability is the first special symbol display device 20. Although it is the same, the special symbol determination random number value determined to be small hit is different from the big hit determination table in the first special symbol display device 20. For example, in the determination table in the second special symbol display device 21, “small hit” is determined only when the special symbol determination random number is “50”. If it is a random number other than the above, it is determined as “lost”.
Therefore, in the low probability random number determination table in the second special symbol display device 21, the probability of being determined to be a big hit at the low probability is 1 / 299.5, similarly to the low probability random number determination table in the first special symbol display device 20. The probability of being determined to be a big hit at a high probability is 10 times, which is 1 / 29.95. On the other hand, the probability determined to be a small hit is 1/599 for both low and high probabilities.

<Hit determination table>
Next, FIG. 6C is a diagram showing a hit determination table that is referred to when determining whether or not the stop result of the normal symbol variation is determined to be win.
The hit determination table shown in FIG. 6 (c) is composed of a random time determination table for non-short game state and a random number determination table for short time game state, and refers to the game state to determine a random number determination table for non-short game state or short time game. A state random number determination table is selected, and based on the selected table and the extracted random number value for winning determination, it is determined whether it is “winning” or “lost”.

For example, according to the non-short-time gaming state random number determination table shown in FIG. 6C, among the random numbers for normal symbol determination of “0” to “19”, one random number value of “0” Determined. On the other hand, according to the short-time gaming state random number determination table, 19 random numbers “0” to “18” among the normal symbol determination random values “0” to “19” are determined to be winning. If the random number is other than the above, it is determined as “lost”.
Therefore, the probability that the normal symbol is determined to be hit in the non-time-short gaming state is 1/20, and the probability that the normal symbol is determined to be winning in the time-short gaming state is 19/20.

<Design determination table>
FIG. 7 is a diagram showing a symbol determination table for determining a special symbol stop symbol.
FIG. 7A is a jackpot symbol determination table for determining a stop symbol at the time of jackpot, and FIG. 7B is a jackpot symbol determination table for determining a stop symbol at the time of jackpot. (C) is a lost symbol determination table for determining a stop symbol at the time of a loss. More specifically, each symbol determination table is configured for each special symbol display device, and includes a symbol determination table for the first special symbol display device and a symbol determination table for the second special symbol display device.

In the jackpot symbol determination table shown in FIG. 7A, the jackpot symbol random number value is referred to. If the first special symbol display device 20 determines that the jackpot is a random number for the jackpot symbol from “0” to “29”, “01” (first special symbol 1) is determined as stop symbol data. To do. Further, at the time of starting the change of the special symbol, based on the determined special symbol type (stop symbol data), the production symbol designation commands “E0H” and “01H” as special symbol information are generated.
Here, the effect designating command is composed of 1-byte data, and 1-byte MODE for identifying the control command classification and 1-byte indicating the content (function) of the executed control command. DATA. The same applies to a variation pattern designation command and a start winning designation command described later.

Further, when the first special symbol display device 20 determines that the jackpot is a jackpot symbol random number “30” to “39”, “02” (first special symbol 2) is determined as the stop symbol data. At the start of the variation of the special symbol, the production symbol designation commands “E0H” and “02H” are generated.
Similarly, if the jackpot symbol random number value is “40” to “49”, “03” (first special symbol 3) is determined as stop symbol data, and the design symbol designation commands “E0H” “03H” are determined. If the jackpot symbol random number value is “50” to “59”, “04” (first special symbol 4) is determined as stop symbol data, and the production symbol designation commands “E0H” and “04H” are If the random number for the jackpot symbol is “60” to “69”, “05” (first special symbol 5) is determined as the stop symbol data, and the production symbol designation commands “E0H” and “05H” are generated. If the random numbers for winning symbols are “70” to “99”, “06” (first special symbol 6) is determined as stop symbol data, and production symbol designation commands “E0H” and “06H” are generated. .

If the second special symbol display device 21 determines that the jackpot is a jackpot symbol random number between “0” and “49”, “07” (second special symbol 1) is determined as stop symbol data. At the start of the variation of the special symbol, the production symbol designation commands “E1H” and “01H” are generated.
Similarly, if the random number for the jackpot symbol is “50” to “59”, “08” (second special symbol 2) is determined as the stop symbol data, and an effect symbol designating command at the start of the variation of the special symbol If “E1H” and “02H” are generated and the random number value for the jackpot symbol is “60” to “69”, “09” (second special symbol 3) is determined as the stop symbol data, and the production symbol designation command “ E1H ”“ 03H ”is generated, and if the jackpot symbol random number value is“ 70 ”to“ 99 ”,“ 10 ”(second special symbol 4) is determined as the stop symbol data, and the production symbol designation command“ E1H ”is determined. "04H" is generated.

  Next, in the small hit symbol determination table shown in FIG. When the first special symbol display device 20 determines that a small hit is made, if the random number value for the small hit symbol is “0” to “49”, the stop symbol data is “11” (special symbol A for small hit) ). Then, at the time of starting the variation of the special symbol, the production symbol designation commands “E0H” and “0AH” are generated based on the determined special symbol type (stop symbol data). If the random number value for the small hit symbol is “50” to “99”, “12” (special symbol B for small hit) is determined as the stop symbol data, and when the variation of the special symbol is started, the directing symbol designation command “E0H” and “0BH” are generated.

  When the second special symbol display device 21 is small hit, if the random number value for the small hit symbol is “0” to “49”, “13” (special symbol A for small hit) is determined as stop symbol data, If the production symbol designation commands “E1H” and “0AH” are generated and the random number value for the small hit symbol is “50” to “99”, “14” (special symbol B for small bonus) is determined as the stop symbol data. The production symbol designation commands “E1H” and “0BH” are generated.

  Next, in the lose symbol determination table shown in FIG. 7C, when it is determined that the first special symbol display device 20 has lost, “00” (special symbol 0 (lost)) is determined as the stop symbol data, At the start of symbol variation, the production symbol designation commands “E0H” and “00H” are generated, and when it is determined that the second special symbol display device 21 has lost, “00” (special symbol 0 ( When the change of the special symbol is started, the production symbol designation commands “E1H” and “00H” are generated.

  As will be described later, the game state after the jackpot (see FIG. 9) and the jackpot mode (see FIG. 10) are determined by the type of special symbol (stop symbol data), so the type of special symbol is a jackpot It can be said that the game state after the game ends and the jackpot mode are determined.

FIG. 8 is a diagram showing a hit normal symbol determination table that is referred to when a normal symbol is determined based on the stop result of the normal symbol fluctuation, and FIG. FIG. 8B is a normal symbol determination table that is referred to when the game is determined to be lost by the determination of the random number for determination.
In the normal symbol determination table shown in FIGS. 8A and 8B, the normal symbol random numbers (0 to 10) are referred to.
If the normal symbol random number value of the normal symbol display device 22 is determined to be a hit in the hit determination table, the normal symbol random number values are “0” and “1” as shown in FIG. If there is, the long open symbol is determined, and if the normal symbol random number is “2” to “10”, the short open symbol is determined.
In the case of the long open symbol, “01” is determined as the stop symbol data, and when the variation of the normal symbol starts, the production symbol designation commands “E8H” and “01H” are generated. When the short open symbol is determined, “02” is determined as the stop symbol data, and when the variation of the normal symbol starts, the production symbol designation commands “E8H” and “02H” are generated.

On the other hand, if the normal symbol random number value of the normal symbol display device 22 is determined to be lost in the hit determination table, the normal symbol random number value is “0” to “10” as shown in FIG. Whatever value is used, the lost symbol is determined.
In the case of the lost symbol, “00” is determined as the stop symbol data, and when the variation of the normal symbol is started, the production symbol designation commands “E8H” and “00H” are generated. The long open symbol and the short open symbol will be described in detail later.

<Big jackpot setting data table>
FIG. 9 is a jackpot end setting data table for determining the gaming state after the jackpot ends.
According to the jackpot end setting data table shown in FIG. 9, based on the type of special symbol (stop symbol data) and the game state at the time of jackpot winning stored in the game state buffer, the high probability game flag setting, the number of high probability games Setting of (X), setting of a short time game flag, and setting of the number of short time games (J) are performed.
It should be noted that “00H” in the gaming state buffer indicating the gaming state at the time of winning the big win indicates gaming state information in which neither the short-time gaming flag nor the high probability gaming flag is set, and “01H” indicates that the short-time gaming flag is set. Although the high probability game flag is not set, the game state information is set. “02H” is the game state information in which the short-time game flag is set but the high probability game flag is not set. "" Indicates game state information in which both the short-time game flag and the high probability game flag are set.

  In the present embodiment, when the stop symbol data of the first special symbol display device 20 is “01” to “04”, that is, when the first special symbols 1 to 4 are won, the gaming state after the end of the jackpot is displayed. A short-time gaming state and a high-probability gaming state (so-called probabilistic gaming state) are set. At this time, 10,000 times are set for the number of short-time games (J) and the number of high-probability games (X), respectively.

  Further, when the stop symbol data of the first special symbol display device 20 is “05”, that is, when the first special symbol 5 is won, the gaming state after the jackpot is the non-short-time gaming state and the high probability game. The state (so-called latent probability changing game state) is set. At this time, 0 is set to the number of short-time games (J), and 10000 is set to the high probability game number (X).

  Further, when the stop symbol data of the first special symbol display device 20 is “06”, that is, when the first special symbol 6 is won, the gaming state after the jackpot is the short-time gaming state and the non-high probability game. The state (so-called short-time gaming state) is set. At this time, 100 times is set as the number of short-time games (J), and 0 is set as the high probability game number (X).

Further, when the stop symbol data of the first special symbol display device 20 is “11” “12”, that is, when the special symbols A and B for small hits are won, the gaming state after the small hit ends is the small hit The game state is the same as that at the time of winning, that is, the game state at the time of winning the small hit is continued.
However, when the game state buffer at the time of winning the small hit is 00H, that is, in the low probability gaming state and the non-short-time gaming state, in the specific game period after the end of the small hit, in order to perform a specific effect, In order to determine the fluctuation pattern determination table (see FIG. 15), the number of specific periods is set.

  Specifically, the number of specific periods (T) is set to 50 times until the special symbol variation display is performed 50 times after the end of the small hit. During this specific game period (when the number of specific periods (T)> 0), as will be described later, the variation pattern determination table for the specific game period (low probability gaming state) after the small hit shown in FIG. 15 is determined. In other than the specific game period (when the number of specific periods (T) = 0), the variation pattern determination table of the normal game state (for low probability game state) shown in FIG. 13 or the high probability game state shown in FIG. The variation pattern determination table is determined.

  In addition, when the stop symbol data of the second special symbol display device 21 is “07” to “09”, that is, when the second special symbol 1 to 3 is won, the gaming state after the jackpot is ended in the short-time gaming state. In addition, a high probability gaming state (so-called probability variation gaming state) is set. At this time, 10,000 times are set for the number of short-time games (J) and the number of high-probability games (X), respectively.

  Further, when the stop symbol data of the second special symbol display device 21 is “10”, that is, when the second special symbol 4 is won, the gaming state after the jackpot is the short-time gaming state and the non-high probability game. The state (so-called short-time gaming state) is set. At this time, 100 times is set as the number of short-time games (J), and 0 is set as the high probability game number (X).

In addition, when the stop symbol data of the second special symbol display device 21 is “13” “14”, that is, when the special symbols A and B for small hits are won, the gaming state after the small hit ends is the small hit The game state is the same as that at the time of winning, that is, the game state at the time of winning the small hit is continued.
However, when the game state buffer at the time of winning the small hit is 00H, that is, in the low probability gaming state and the non-short-time gaming state, as in the case of the first special symbol display device 20, the special symbol is displayed after the end of the small hit. The number of specific periods (T) is set to 50 times so that the specific game period is reached until the variable display is performed 50 times.

<Special electric accessory operation mode determination table>
FIG. 10 is a diagram showing an example of the special electric accessory operating mode determination table for determining the opening / closing conditions of the special winning opening.
With reference to the special electric accessory operating mode determination table shown in FIG. 10, based on the type of special symbol (stopped symbol data), the operating mode of the special winning opening, that is, the number of round games (R) and the opening of the special winning opening The big prize opening opening mode determination table for determining the mode is determined. In the present embodiment, “table” is appropriately omitted and described as “TBL”.

Specifically, when the stop symbol data is “01”, the round game number R is determined to be “16”, and the release mode table is determined to be “1 TBL per long” to be described later.
Further, when the stop symbol data is “02”, the round game number R is determined to be “16” and the release mode table is “1 TBL per development” to be described later, and when the stop symbol data is “03”, the round game The number of times R is determined to be “16”, and the release mode table is determined to be “2 TBL per development” to be described later.
When the stop symbol data is “04” or “05”, the round game number R is determined to be “4”, and the release mode table is set to “short hit TBL” described later. When the stop symbol data is “06” The round game number R is determined to be “16”, and the release mode table is determined to be “2 TBL per long” which will be described later.

  Further, when the stop symbol data is “07”, the round game number R is determined to be “16” and the release mode table is determined to be “1 TBL per long”, and when the stop symbol data is “08”, the round game number R is determined. Is set to “16”, the release mode table is set to “1 TBL per development”, and when the stop symbol data is “09”, the round game number R is set to “16”, and the release mode table is set to “2 TBL per development”. When the stop symbol data is “10”, the round game number R is determined to be “16”, and the release mode table is determined to be “1 TBL per long”.

<Large winning opening open mode determination table>
FIG. 11 is a diagram showing the configuration of the big prize opening opening manner determination table determined in FIG. 10, and the open / close door 16b of the first big winning opening 16 or the like according to the big prize opening opening manner determination table shown in FIG. The opening / closing conditions of the movable piece 17b of the second grand prize winning port 17 are determined.
11 is a table that is referred to in the case of a jackpot game, and is composed of 1 TBL per long, 2 TBL per long, TBL per short, 1 TBL per development, and 2 TBL per development. .
Then, a game per long is executed based on the TBL per long, a game per short is executed based on the TBL per short, and a game per development is executed based on the TBL per development.

  In the jackpot opening mode determination table for jackpot shown in FIG. 11, the type of jackpot to be opened (the first jackpot 16 or the second jackpot 17) and the maximum round game in one jackpot game The number of times (R), the specified number indicating the maximum number of winnings in a single winning round in one round, the start interval time from the start of the big win game to the execution of the first round game, and the big winning opening in each round game Maximum number of times of opening (K), opening time of the big prize opening for one opening of each round game, closing time of the big winning opening for one opening of each round game, The closing interval time of the big prize opening from the end of one round game to the execution of the next round game and the end interval time from the end of the last round game to the end of the jackpot game are stored It has been.

  Here, at 1 TBL per length shown in FIG. 11, the open / close door 16b of the first grand prize opening 16 can be operated to open the first big prize opening 16 for a maximum of 29 seconds per round. However, when a specified number (9) of game balls wins the first grand prize opening 16 before the opening time of 29 seconds elapses, the operation of the open / close door 16b is finished and one round of the game is finished. It will be. In this case, the maximum round game count R is set to 16 rounds.

In addition, at 2 TBL per length shown in FIG. 11, as with 1 TBL per length, the first grand prize opening 16 can be opened up to 29 seconds per round by operating the door 16b of the first big prize opening 16. it can. When a prescribed number (9) of game balls wins the first grand prize opening 16 in one round, the operation of the open / close door 16b is finished, and one round of game is finished. Also in this case, the maximum number of round games R is set to 16 rounds.
However, the opening mode of the first grand prize opening 16 at 2 TBL per length is the same as 1 TBL per length from the first round to the fourth round, but the opening mode after the fifth round is different from 1 TBL per length. ing. In other words, at 2 TBL per long, after the fifth round, the maximum opening time of the first grand prize opening 16 is set to an extremely short time of 0.052 seconds, and it is difficult for the game ball to win the first big prize opening 16. It is trying to be in a state.
As described above, in this embodiment, by providing 1 TBL per length and 2 TBL per length, a jackpot game in which the number of balls that can be obtained by the player is different while the type of the big prize opening and the maximum number of round games are the same. Can be realized.

  Further, in the short hit TBL shown in FIG. 11, the movable piece 17b of the second big prize opening 17 is operated to open the second big prize opening 17 for a maximum of 0.052 seconds per round. However, also in this case, when a prescribed number (9) of game balls have won the second grand prize opening 17 in one round, the operation of the movable piece 17b is finished, and one game is finished. become. In this case, the maximum round game count R is set to 4 rounds.

  In addition, at 1 TBL per development and 2 TBL per development shown in FIG. 11, the movable piece 17 b of the second big prize opening 17 can be operated to open the second big prize opening 17 a plurality of times in one round. However, also in this case, when a prescribed number (9) of game balls wins the second big prize opening 17 for one round, the operation of the movable piece 17b of the second big prize opening 17 ends, and one The round game will end. That is, it is not always opened three times (K = 3) for one round.

Further, in this embodiment, 1TBL per development and 2TBL per development have the same opening mode up to the second round, but the opening mode is different after the third round. That is, according to 1 TBL per development, after the third round, the opening time of the second grand prize opening 17 is set to a short time of 0.052 seconds, and the game ball wins the second big prize opening 17 Although it becomes difficult, according to 2TBL per development, the opening time of the second grand prize opening 17 is set to the maximum of 29 seconds, which is the same as the first round and the second round, in the third and fourth rounds. Therefore, it becomes easy for the game ball to win the second big winning opening 17.
With this configuration, it is possible to make it difficult to determine which of the plurality of games per development is being played up to a predetermined round (second round). However, a more advantageous game per development (2 TBL per development) can be expected to be controlled.

In the present embodiment, the second half of the game per development (2nd round or after the fourth round) is in a state where it is difficult for the game ball to enter the second big prize opening 17, but the most advantageous game per development The game ball may not be in a state where it is difficult to win a prize.
In this embodiment, the opening time and closing time of 1 TBL per development and 2 TBL per development are set to exactly the same time. However, the time difference may be set so that it is difficult to determine which of the plurality of games per development is not set at exactly the same time.

As described above, in the present embodiment, the “long winning game” that opens the first big winning opening 16 with a long opening time, and the “short winning game” that opens the second big winning opening 17 with a short opening time, Three types of “big hit games” are provided, which are “games per development” that open the plurality of second big prize winning openings 17 in one round.
In the present embodiment, “big hit game” is referred to as “special game”.

  Further, as a feature of the special electric accessory actuating mode determination table shown in FIG. 10, in the second special symbol display device 21 that is actuated when a game ball enters the second start port 17, “short hit TBL "Is not determined. This is because, in the non-short-time gaming state, almost no game ball enters the second start port 17, but if a short hit is determined when a game ball enters the second start port 17, This is because even if the short-time gaming state is provided, the player's willingness to play may be reduced.

  In the present embodiment, the second special symbol display device 21 is configured not to determine “short hit TBL”, but the second special symbol display device 21 also determines “short hit TBL”. You may comprise. However, in the case of determining “short hit TBL” in the second special symbol display device 21, compared to the first special symbol display device 20 that is activated when a game ball enters the first start port 14, It is desirable that the “short TBL” is not easily determined.

  Furthermore, the gaming machine 1 according to the present embodiment has a variation pattern for the probability variation gaming state (for high probability gaming state) shown in FIG. 14 based on the variation pattern determination table for the normal gaming state (for low probability gaming state) shown in FIG. In the decision table, the ratio of winning the jackpot that is advantageous to the player is higher, that is, the first special symbol 11 makes it easier to win the jackpot that is advantageous to the player than during the normal game because of the first special symbol 11. It has become.

FIG. 12 is a diagram showing the structure of the opening mode table for the big winning opening at the time of a small hit determined in FIG. 10, and the second big at the time of small hitting is determined by the table for determining the opening of a big winning opening shown in FIG. The opening / closing conditions of the movable piece 17b of the winning opening 17 are set.
When the small-hit opening mode determination table shown in FIG. 12 is determined, a small-hit game in which the movable piece 17b of the second big winning opening 17 repeats opening for 0.052 seconds and closing for 2.000 seconds is executed. Is done. This small hit game is regarded as one game in which the movable piece 17b of the second big prize opening 17 repeats opening and closing four times continuously, so the concept of “round game” in the long hit game and the short hit game described above. However, the opening / closing mode of the second grand prize winning port 17 is substantially the same as that of the short hit game. Thereby, the pleasure which makes a player guess whether it is a small hit or a short win can be provided. However, if the opening / closing mode is approximated to the extent that it is impossible or difficult to discriminate whether the player is a small hit or short hit even if the opening time and closing time are not set exactly the same, the same as above The fun of gaming can be improved.

  Note that the “short hit” or “small hit” release time (0.052 seconds) is shorter than the time (about 0.6 seconds) at which one game ball is fired as described above. Even if the movable piece 17b of the winning opening 17 is opened, it is difficult to win the big winning opening 25, and the opening mode of “short win” or “small hit” can be said to be “unfavorable opening mode”. On the other hand, since the “long hit” release time (29.5 seconds) is longer than the time (about 0.6 seconds) at which one game ball is fired, it can be said to be an “advantageous release mode”.

<Variation pattern determination table>
FIGS. 13 to 15 are diagrams showing a variation pattern determination table for determining a variation pattern of a special symbol. FIG. 13 shows a normal gaming state (low level) that is referred to for a normal gaming state (for a low probability gaming state). 14 is an example of a variation pattern determination table for a high probability gaming state. FIG. 14 is an example of a variation pattern determination table for a high probability gaming state referred to in the high probability gaming state, and FIG. It is an example of the variation pattern determination table for the specific game period (for low probability gaming state) after the small hit referred to during the specific game period.
The specific game period after the end of the jackpot is determined only in the low-probability gaming state and the non-short-time gaming state at the time of winning the jackpot as described in the explanation of the jackpot end time setting data table shown in FIG. Is not.

Specifically, according to the variation pattern determination table, the type of special symbol display device, special symbol judgment random number value (winning winning or defeating), jackpot symbol random number value (jackpot symbol), presence or absence of short-time gaming state, special symbol The variation pattern is determined based on the number of holds, the reach determination random value, and the variation pattern random value.
The variation pattern is determined at the start of variation of the special symbol, and a variation pattern designation command is generated based on the determined variation pattern. This variation pattern designation command is transmitted from the main control board 110 to the effect control board 120 in the output control process.

Note that the gaming machine 1 according to the present embodiment is configured such that the reach is always performed in the case of a big hit or a small win, so that the reach determination random number value is not referred to in the case of a big win or a small win.
The “reach” in the present embodiment means that after a part of the combination of the production symbols 35 for notifying the transition to the special game is stopped and displayed, the remaining some of the production symbols 35 continue to be displayed in a variable manner. Say. For example, when the combination of the three-digit effect symbol 35 of “777” is set as the combination of the effect symbols 35 for informing that the game will shift to the jackpot game, the two effect symbols 35 are stopped and displayed at “7”. The state where the remaining effect symbols 35 are displayed in a variable manner.

  In addition, when the variation pattern designation command is “E6H” as the MODE, the variation pattern determined when the game ball enters the first start port 13 and the variation of the special symbol of the first special symbol display device 20 is started. When the MODE is “E7H”, a game ball enters the second starting port 14 and the second special symbol display device 21 starts to change the special symbol. Indicates that the command is a variation pattern designation command corresponding to the determined variation pattern. Then, DATA of the variation pattern designation command indicates a specific variation pattern number. That is, the variation pattern designation command is also information indicating the variation pattern.

<Variation pattern determination table for normal gaming state>
The configuration of the variation pattern determination table for the normal gaming state shown in FIG. 13 will be described.
In the variation pattern determination table, since the variation pattern of the special symbol of the first special symbol display device 20 and the variation pattern of the special symbol of the second special symbol display device 21 are provided, first, the first special symbol display device 20. The variation pattern of the special symbol will be described.

  In the variation pattern determination table for the normal gaming state shown in FIG. 13, it is determined that the special symbol determination random number value in the first special symbol display device 20 is “7” or “317” and that the jackpot is won. Is the first special symbol 1 (the special symbol stop symbol data “01”), and if the special symbol variation random value is “0” to “29”, the variation time of the special symbol is 60000 ms. Change pattern 1 is selected. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “01H” corresponding to the variation pattern 1 are generated as the special symbol information. The variation content of the variation pattern 1 is, for example, a hit effect with reach A.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot, and the special symbol type is determined to be the first special symbol 1, the special symbol variation random value is “ If “30” to “99”, the variation pattern 2 having a variation time of 90000 ms is selected as the variation pattern of the special symbol. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “02H” corresponding to the variation pattern 2 are generated. The variation content of the variation pattern 2 is, for example, a hit effect with reach B.

  Also, it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won, and the type of the special symbol is the first special symbol 2, 3 (the special symbol stop symbol data “02” “03”). ), The variation pattern 3 having a variation time of 75000 ms is selected as the variation pattern of the special symbol regardless of the random numbers for special figure variation “0” to “99”. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “03H” corresponding to the variation pattern 3 are generated. The variation content of the variation pattern 3 is, for example, a symbol squeak effect that makes the expectation that the effect symbol 35 reaches a reach state with a specific symbol (for example, “7”).

  Also, it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won, and the special symbol type is the first special symbol 4 or the first special symbol 5 (the special symbol stop symbol data “04 "05"), the fluctuation pattern 4 or the fluctuation pattern 5 having a fluctuation time of 60000 ms is selected as the special symbol fluctuation pattern regardless of the special figure fluctuation random values "0" to "99". At the start of the variation of the special symbol, the variation pattern designation commands “E6H”, “04H”, “E6H” and “05H” corresponding to the variation pattern 4 or the variation pattern 5 are generated. The fluctuation content of the fluctuation pattern 4 or the fluctuation pattern 5 is, for example, a chance effect that expects a big hit.

  In addition, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won, and the type of the special symbol is the first special symbol 6 (the special symbol stop symbol data “06”), Similar to the first special symbol 1, if the special figure variation random value is “0” to “29”, the above-described variation pattern 1 is selected, and the special figure variation random value is “30” to “99”. If so, the above-described variation pattern 2 is selected. The change pattern designation commands and change contents of the change patterns 1 and 2 are as described above.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won by a small hit, that is, when the special symbol stop symbol data “11” “12”, Regardless of the numerical values “0” to “99”, the variation pattern 6 having a variation time of 60000 ms is selected as the variation pattern of the special symbol. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “06H” corresponding to the variation pattern 6 are generated. The variation content of the variation pattern 6 is, for example, the same chance effect as the variation patterns 4 and 5.

Next, a case where the special symbol determination random number value in the first special symbol display device 20 is a loss other than the big hit or the small hit will be described.
If the special symbol determination random number value is lost, the variation pattern of the special symbol is determined based on the gaming state, the number of reserved balls in the first special symbol, the reach determination random number value, and the special symbol variation random value.
Specifically, when the special symbol determination random number value in the first special symbol display device 20 is lost (the special symbol stop symbol data “00”) and the gaming state is the non-short game state, the first special symbol. If the number of reserved balls is “0” to “2” and the reach determination random number value is “0” to “79”, regardless of the special figure variation random value “0” to “99”, A variation pattern 7 having a variation time of 10,000 ms is selected. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “07H” corresponding to the variation pattern 7 are generated. The variation content of the variation pattern 7 is, for example, normal variation.

On the other hand, the number of reserved balls of the first special symbol is “0” to “2”, the reach determination random number value is “80” to “99”, and the special figure variation random number value is “0” to “69”. If so, the variation pattern 8 having a variation time of 60000 ms is selected, and when the variation of the special symbol starts, variation pattern designation commands “E6H” and “08H” corresponding to the variation pattern 8 are generated. The variation content of the variation pattern 8 is, for example, a loss effect with reach A.
Similarly, the number of reserved balls of the first special symbol is “0” to “2”, the reach determination random number value is “80” to “99”, and the special figure variation random number value is “70” to “99”. ”Is selected, the variation pattern 9 having a variation time of 90000 ms is selected, and when the variation of the special symbol starts, variation pattern designation commands“ E6H ”and“ 09H ”corresponding to the variation pattern 9 are generated. The variation content of the variation pattern 9 is, for example, a loss effect with reach B.

Next, if the number of reserved balls of the first special symbol is “3” and the reach determination random number value is “0” to “89”, the special figure change random number value is “0” to “99”. Regardless, the variation pattern 10 is selected. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “0AH” corresponding to the variation pattern 10 are generated. The variation content of the variation pattern 10 is, for example, a shortened variation A.
On the other hand, if the number of reserved balls of the first special symbol is “3”, the reach determination random number value is “90” to “99”, and the special figure variation random number value is “0” to “69”, If the variation pattern 8 described above is selected and the random number value for special figure variation is “70” to “99”, the variation pattern 9 described above is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 8 and 9 are as described above.

Next, when the special symbol determination random number value in the first special symbol display device 20 is lost (the special symbol stop symbol data “00”) and the gaming state is the short-time gaming state, the holding ball of the first special symbol If the number is “0” “1” and the reach determination random number value is “0” to “84”, the above variation pattern 7 is selected regardless of the special figure variation random value “0” to “99”. To do. The variation pattern designation command and variation contents corresponding to the variation pattern 7 are as described above.
On the other hand, the number of reserved balls of the first special symbol is “0” “1”, the reach determination random number value is “85” to “99”, and the special figure variation random number value is “0” to “69”. If there is, the above-described variation pattern 8 is selected, and if the special figure variation random value is “70” to “99”, the above-described variation pattern 9 is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 8 and 9 are as described above.

Next, if the number of reserved balls of the first special symbol is “2” “3” and the reach determination random number value is “0” to “94”, the special figure variation random value “0” to “ Regardless of “99”, the variation pattern 11 having a variation time of 3000 ms is selected. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “0BH” corresponding to the variation pattern 11 are generated. The variation content of the variation pattern 11 is, for example, a shortened variation B.
On the other hand, if the number of reserved balls of the first special symbol is “3”, the reach determination random number value is “95” to “99”, and the special figure variation random number value is “0” to “69”, If the variation pattern 8 described above is selected and the random number value for special figure variation is “70” to “99”, the variation pattern 9 described above is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 8 and 9 are as described above.

Next, the special symbol variation pattern of the second special symbol display device 21 will be described.
In the variation pattern determination table for the normal gaming state shown in FIG. 13, it is determined that the special symbol determination random number value in the second special symbol display device 21 is “7” or “317” and that the jackpot is won, and the type of the special symbol Is the second special symbol 1 (the special symbol stop symbol data “07”), if the random number value for special diagram variation is “0” to “29”, the variation pattern 1 described above is selected and the special diagram is selected. If the random number for variation is “30” to “99”, the variation pattern 2 described above is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 1 and 2 are the same as the variation patterns 1 and 2 of the first special symbol display device 20 described above except that the MODE of the variation pattern designation command is “E7H”. It is the same as the corresponding variation pattern designation command and variation content.

  Further, when it is determined that the special symbol determination random number value in the second special symbol display device 21 has won the jackpot, and the type of the special symbol is the second special symbol 2 (the special symbol stop symbol data “08”), Regardless of the special figure variation random values “0” to “99”, the variation pattern 3 described above is selected. The fluctuation pattern designation command and fluctuation contents corresponding to the fluctuation pattern 3 are fluctuations corresponding to the fluctuation pattern 3 of the first special symbol display device 20 described above except that the MODE of the fluctuation pattern designation command is “E7H”. It is the same as the pattern specification command and the variation contents.

  Further, when it is determined that the special symbol determination random number value in the second special symbol display device 21 has won the jackpot and the type of the special symbol is the second special symbol 3 (the special symbol stop symbol data “09”), Similar to the second special symbol 1, if the random number value for special figure fluctuation is “0” to “29”, the above-mentioned fluctuation pattern 1 is selected and the random number value for special figure fluctuation is “30” to “99”. If so, the above-described variation pattern 2 is selected.

  Further, when it is determined that the special symbol determination random number value in the second special symbol display device 21 is won by a small hit, that is, when the special symbol stop symbol data “13” “14”, the special symbol variation Regardless of the random numbers “0” to “99”, the above-described variation pattern 6 is selected. The variation pattern designation command and variation contents corresponding to the variation pattern 6 are the variation pattern designation of the variation pattern 6 of the first special symbol display device 20 described above except that the MODE of the variation pattern designation command is “E7H”. Same as command and variable contents.

  When the special symbol determination random number value in the second special symbol display device 21 is lost (special symbol stop symbol data “00”), the variable pattern designation command MODE is “E7H”, except that Since the special symbol determination random number value in the 1 special symbol display device 20 is the same as the case of losing, the description is omitted.

<Variation pattern determination table for probability variation gaming state>
Next, the configuration of the variation pattern determination table for the probability variation gaming state shown in FIG. 14 will be described.
As described above, in the variation pattern determination table, the variation pattern of the special symbol of the first special symbol display device 20 and the variation pattern of the special symbol of the second special symbol display device 21 are provided. The special symbol variation pattern of the special symbol display device 20 will be described.

  In the variation pattern determination table for the probability variation gaming state shown in FIG. 14, the special symbol determination random numbers in the first special symbol display device 20 are “7” “37” “67” “97” “127” “157” “187”. "217" "247" "277" "317" "337" "367" "397" "427" "457" "487" "517" "547" "577" If the symbol type is the first special symbol 1 (stop symbol data “01”) and the random number value for special symbol variation is “0” to “29”, the variation pattern 21 having a variation time of 40000 ms is selected. . At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “21H” corresponding to the variation pattern 21 are generated as the special symbol information. The variation content of the variation pattern 21 is a hit effect with reach C, for example.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot and the type of the special symbol is the first special symbol 1 (stop symbol data “01”), the special symbol variation If the random number for use is “30” to “99”, the variation pattern 22 having a variation time of 80000 ms is selected. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “22H” corresponding to the variation pattern 22 are generated. The variation content of the variation pattern 22 is, for example, a hit effect with reach D.

  In addition, it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won, and the type of the special symbol is the first special symbol 2 or 3 (stop symbol data “02” “03”). For example, the fluctuation pattern 23 having a fluctuation time of 75000 ms is selected regardless of the random numbers for special figure fluctuation “0” to “99”. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “23H” corresponding to the variation pattern 23 are generated. The variation content of the variation pattern 23 is, for example, the above-described symbol curling effect.

  In addition, it is determined that the special symbol determination random number in the first special symbol display device 20 has been won, and the special symbol type is the first special symbol 4 or the first special symbol 5 (stop symbol data “04” “05” ”), The fluctuation pattern 24 or the fluctuation pattern 25 having a fluctuation time of 60000 ms is selected regardless of the special figure fluctuation random values“ 0 ”to“ 99 ”. At the start of the variation of the special symbol, the variation pattern designation commands “E6H”, “24H”, “E6H” and “25H” corresponding to the variation pattern 24 or the variation pattern 25 are generated. The variation content of the variation pattern 24 or 25 is, for example, the chance effect described above.

  In addition, when it is determined that the special symbol determination random value in the first special symbol display device 20 has won the jackpot, and the type of the special symbol is the first special symbol 6 (stop symbol data “06”), the first Similarly to the special symbol 1, if the random number value for special figure fluctuation is “0” to “29”, the above-described fluctuation pattern 21 is selected, and if the random number value for special figure fluctuation is “30” to “99”. The variation pattern 22 described above is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 21 and 22 are as described above.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won by a small hit, that is, when the special symbol stop symbol data “11” “12”, Regardless of the numerical values “0” to “99”, the fluctuation pattern 26 having a fluctuation time of 60000 ms is selected. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “26H” corresponding to the variation pattern 26 are generated. The variation content of the variation pattern 26 is the same chance effect as the variation patterns 24 and 25 described above, for example.

Next, a case where the special symbol determination random number value in the first special symbol display device 20 is a loss other than the big hit or the small hit will be described.
When the special symbol determination random number value is lost, the variation pattern of the special symbol is determined based on the gaming state, the number of reserved balls of the first special symbol, the reach determination random number value, and the special symbol variation random value.
Specifically, when the special symbol determination random number value in the first special symbol display device 20 is lost (stop symbol data “00”) and the gaming state is the non-short game state, the first special symbol is suspended. A special symbol variation pattern is determined based on the number of balls, the reach determination random number value, and the special diagram variation random value.
Specifically, if the number of reserved balls of the first special symbol is “0” to “2” and the reach determination random number value is “0” to “79”, the random number value for special figure variation “0” The variation pattern 27 having a variation time of 10000 ms is selected regardless of "-" 99. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “27H” corresponding to the variation pattern 27 are generated. The variation content of the variation pattern 27 is, for example, normal variation.

On the other hand, the number of reserved balls of the first special symbol is “0” to “2”, the reach determination random number value is “80” to “99”, and the special figure variation random number value is “0” to “69”. If so, the variation pattern 28 having a variation time of 60000 ms is selected, and if the random number value for special figure variation is “70” to “99”, the variation pattern 29 having a variation time of 90000 ms is selected. At the start of the variation of the special symbol, the variation pattern designation command “E6H” “28H” or “E6H” “29H” corresponding to the variation pattern 28 or the variation pattern 29 is generated.
The variation content of the variation pattern 28 is, for example, a loss effect with reach C, and the variation content of the variation pattern 29 is, for example, a loss effect with reach D.

Next, when the number of reserved balls of the first special symbol is “3” and the reach determination random number value is “0” to “89”, the special figure change random number value is “0” to “99”. Regardless, the variation pattern 30 having a variation time of 5000 ms is selected. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “30H” corresponding to the variation pattern 30 are generated. The variation content of the variation pattern 30 is a shortened variation A, for example.
On the other hand, if the number of reserved balls of the first special symbol is “3”, the reach determination random number value is “90” to “99”, and the special figure variation random number value is “0” to “69”, If the variation pattern 28 described above is selected and the random number value for special figure variation is “70” to “99”, the variation pattern 29 described above is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 28 and 29 are as described above.

Next, when the random number value for special symbol determination in the first special symbol is lost (stop symbol data “00”) and the gaming state is the short-time gaming state, the number of reserved balls in the first special symbol is “0” “ If the random number value for reach determination is “0” to “84”, the variation pattern 27 described above is selected regardless of the random number values for special figure variation “0” to “99”. The variation pattern designation command and variation contents corresponding to the variation pattern 27 are as described above.
On the other hand, the number of reserved balls of the first special symbol is “0” “1”, the reach determination random number value is “85” to “99”, and the special figure variation random number value is “0” to “69”. If there is, the above-described variation pattern 28 is selected, and if the special figure variation random value is “70” to “99”, the above-described variation pattern 29 is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 28 and 29 are as described above.

Next, if the number of reserved balls of the first special symbol is “2” “3” and the reach determination random number value is “0” to “94”, the special figure variation random value “0” to “ Regardless of “99”, the variation pattern 31 having a variation time of 3000 ms is selected. Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “31H” corresponding to the variation pattern 31 are generated. The variation content of the variation pattern 31 is, for example, a shortened variation B.
On the other hand, if the number of reserved balls of the first special symbol is “3”, the reach determination random number value is “95” to “99”, and the special figure change random number value is “0” to “69”, If the variation pattern 28 described above is selected and the random number value for special figure variation is “70” to “99”, the variation pattern 29 described above is selected. The variation pattern designation command and variation contents corresponding to the variation patterns 28 and 29 are as described above.

Next, the fluctuation pattern of the second special symbol display device 21 will be described.
In the variation pattern determination table for the probability variation gaming state shown in FIG. 14, it is determined that the special symbol determination random number value in the second special symbol display device 21 is won and the special symbol type is the second special symbol 1. If the random number value for special figure fluctuation is “0” to “29”, the above-described fluctuation pattern 21 is selected, and if the random number value for special figure fluctuation is “30” to “99”, the fluctuation described above is selected. A pattern 22 is selected. The fluctuation pattern designation command and fluctuation contents corresponding to the fluctuation patterns 21 and 22 are the fluctuation patterns 21 and 22 of the first special symbol display device 20 described above except that the MODE of the fluctuation pattern designation command is “E7H”. It is the same as the variation pattern designation command and variation contents corresponding to.

Further, if the special symbol determination random number value in the second special symbol display device 21 is determined to have been won, and the special symbol type is the second special symbol 2 (stop symbol data “08”), the special symbol variation Regardless of the random number value “0” to “99”, the above-described variation pattern 23 is selected. The variation pattern designation command and variation contents corresponding to the variation pattern 23 are the variation pattern designation of the variation pattern 23 of the first special symbol display device 20 described above except that the MODE of the variation pattern designation command is “E7H”. Same as command and variable contents.
In addition, when it is determined that the special symbol determination random number value in the second special symbol display device 21 has won the jackpot and the type of the special symbol is the second special symbol 3 (stop symbol data “09”), the second Similarly to the special symbol 1, if the random number value for special figure fluctuation is “0” to “29”, the above-described fluctuation pattern 21 is selected, and if the random number value for special figure fluctuation is “30” to “99”. The variation pattern 22 described above is selected.

  Further, when it is determined that the special symbol determination random number value in the second special symbol display device 21 is won by a small hit, that is, when the stop symbol data is “13” “14”, the special symbol variation random value is Regardless of “0” to “99”, the above-described variation pattern 26 is selected. The variation pattern designation command and variation contents corresponding to the variation pattern 26 are the variation pattern designation of the variation pattern 26 of the first special symbol display device 20 except that the MODE of the variation pattern designation command is “E7H”. Same as command and variable contents.

  When the special symbol determination random number in the second special symbol display device 21 is lost (stop symbol data “00”), the first special symbol display is performed except that the MODE of the variation pattern designation command is “E7H”. Since the random number value for special symbol determination in the device 20 is the same as the case of losing, the description is omitted.

<Change pattern determination table for specific game period after small hit>
Next, the configuration of the variation pattern determination table for the specific game period after the small hit shown in FIG. 15 will be described.
First, the fluctuation pattern of the first special symbol display device 20 will be described.
In the variation pattern determination table for the specific game period after the small hit shown in FIG. 15, it is determined that the jackpot is won when the special symbol determination random number value in the first special symbol display device 20 is “7” “317”. When the special symbol type is the first special symbol 1 and the random number value for special symbol variation is “0” to “29”, the variation pattern 21 having a variation time of 40000 ms is selected. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “21H” as special symbol information are generated. The variation content of the variation pattern 21 is a hit effect with reach C, for example.
Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot, and the special symbol type is the first special symbol 1, the special symbol variation random value is “30” to If “99”, the variation pattern 22 having a variation time of 80000 ms is selected. In this case, the fluctuation pattern designation commands “E6H” and “22H” are generated. The variation content of the variation pattern 22 is, for example, a hit effect with reach D.

  Further, if it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot and the type of the special symbol is the first special symbol 2 or 3, regardless of the special symbol variation random value. A fluctuation pattern 23 having a fluctuation time of 60000 ms is set. In this case, variation pattern designation commands “E6H” and “23H” are generated. The variation content of the variation pattern 23 is, for example, a design-striking effect that expects the effect symbol to reach a reach state with a specific symbol.

  In addition, if it is determined that the special symbol determination random value in the first special symbol display device 20 has won the jackpot and the type of the special symbol is the first special symbol 4 or the first special symbol 5, the special symbol variation disturbance Regardless of the numerical value, the fluctuation pattern 24 or the fluctuation pattern 25 having a fluctuation time of 60000 ms is set, and the fluctuation pattern designation commands “E6H”, “24H”, “E6H”, and “25H” are generated at the start of the special symbol fluctuation. The variation content of the variation pattern 24 or 25 is, for example, a chance effect that expects a big hit.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot and the type of the special symbol is the first special symbol 6, the special symbol as in the first special symbol 1 above. If the random number value for variation is “0” to “29”, the above-described variation pattern 21 is set, and if the random number value for special figure variation is “30” to “99”, the above-described variation pattern 22 is set. To do. The fluctuation pattern designation commands and fluctuation contents of the fluctuation patterns 21 and 22 are as described above.

  When the special symbol determination random number value in the first special symbol display device 20 is determined to be a small hit, a variation pattern 26 having a variation time of 60000 ms is set regardless of the special symbol variation random value, and the special symbol is set. At the start of fluctuation, fluctuation pattern designation commands “E6H” and “26H” are generated. The fluctuation content of the fluctuation pattern 26 is the same chance effect as the fluctuation patterns 24 and 25.

Next, a case where the special symbol determination random number value in the first special symbol display device 20 is a loss other than the big hit or the small hit will be described.
When the special symbol determination random number value is lost, the variation pattern of the special symbol is determined based on the number of reserved balls of the first special symbol, the reach determination random value, and the special symbol variation random value.
Specifically, when the number of reserved balls of the first special symbol is “0” to “2” and the reach determination random number value is “0” to “79”, the special figure fluctuation random value “0” The fluctuation pattern 27 is set so that the fluctuation time is set to 10000 ms regardless of "" to "99". Then, at the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “27H” are generated. The fluctuation content of the fluctuation pattern 27 is a normal fluctuation.
On the other hand, the number of reserved balls of the first special symbol is “0” to “2”, the reach determination random number value is “80” to “99”, and the special figure variation random number value is “0” to “69”. In this case, the variation pattern 28 having a variation time of 60000 ms is set, and when the special figure variation random value is “70” to “99”, the variation pattern 29 having a variation time of 90000 ms is set. Then, at the start of the variation of the special symbol, the variation pattern designation command “E6H” “28H” or “E6H” “29H” is generated.
The variation content of the variation pattern 28 is a loss effect with reach C, and the variation content of the variation pattern 29 is a loss effect with reach D.

Next, when the number of reserved balls of the first special symbol is “3” and the reach determination random number value is “0” to “89”, the special figure change random number value is “0” to “99”. Regardless, the variation pattern 30 with a variation time of 5000 ms is set. At the start of the variation of the special symbol, the variation pattern designation commands “E6H” and “30H” are generated. The variation content of the variation pattern 30 is a shortened variation A.
On the other hand, when the number of reserved balls of the first special symbol is “3”, the reach determination random number value is “90” to “99”, and the special figure change random number value is “0” to “69”, The above-described variation pattern 28 is set, and when the special figure variation random values are “70” to “99”, the above-described variation pattern 29 is set. The variation pattern designation commands and variation contents of the variation patterns 28 and 29 are as described above.

Next, the fluctuation pattern of the second special symbol display device 21 will be described.
In the variation pattern determination table for the specific period after the small hit shown in FIG. 15, it is determined that the special symbol determination random number value in the second special symbol display device 21 has won the jackpot, and the type of the special symbol is the second special symbol. 1, if the special figure variation random value is “0” to “29”, the above variation pattern 21 is set, and if the special figure variation random value is “30” to “99”, The variation pattern 22 described above is set. The fluctuation pattern designation command and fluctuation contents of the fluctuation patterns 21 and 22 are the fluctuations of the fluctuation patterns 21 and 22 of the first special symbol display device 20 described above except that the MODE of the fluctuation pattern designation command is “E7H”. It is the same as the pattern specification command and the variation contents.

In addition, if the special symbol determination random number value in the second special symbol display device 21 is determined to have won the jackpot and the type of the special symbol is the second special symbol 2, the special symbol variation random value “0” to “ Regardless of “99”, the above-described variation pattern 23 is set. The variation pattern designation command and variation content of the variation pattern 23 are the variation pattern designation command of the variation pattern 23 of the first special symbol display device 20 described above, except that the MODE of the variation pattern designation command is “E7H”. It is the same as the contents of fluctuation.
Further, when it is determined that the special symbol determination random number value in the second special symbol display device 21 has won the jackpot and the type of the special symbol is the second special symbol 3, the special symbol is the same as the second special symbol 1. If the random number value for variation is “0” to “29”, the above-described variation pattern 21 is set, and if the random number value for special figure variation is “30” to “99”, the above-described variation pattern 22 is set. To do.

  In addition, when the special symbol determination random number value in the second special symbol display device 21 is determined to be a small hit, the above-described variation pattern 26 is set regardless of the special symbol variation random value “0” to “99”. To do. The fluctuation pattern designation command and fluctuation contents of the fluctuation pattern 26 are the fluctuation pattern designation command and fluctuation pattern of the fluctuation pattern 26 of the first special symbol display device 20 described above, except that the MODE of the fluctuation pattern designation command is “E7H”. It is the same as the contents of fluctuation.

  When the random number value for special symbol determination in the second special symbol display device 21 is lost, it is for special symbol determination in the first special symbol display device 20 except that the MODE of the variation pattern designation command is “E7H”. Since the random number value is the same as the case of losing, the description is omitted.

  As described above, in the variation pattern determination table for the normal gaming state (for low probability gaming state) shown in FIG. 13 and the variation pattern determination table for the high probability gaming state shown in FIG. Even so, it is configured such that different variation patterns are determined. Therefore, it is possible to distinguish between a variation pattern determined for a high probability gaming state and a variation pattern determined for a low probability gaming state depending on the type of variation pattern.

Similarly, the variation pattern determination table for the normal gaming state (for low probability gaming state) shown in FIG. 13, and the variation pattern determination table for the specific gaming period (for low probability gaming state) after the small hit shown in FIG. Then, even if the same random number value or the like is referred to, different variation patterns are determined.
Therefore, according to the type of the variation pattern, it is possible to distinguish whether it is a normal gaming state or a specific gaming period after a small hit. In contrast, the variation pattern determination table for the high probability gaming state shown in FIG. 14 and the variation pattern determination table for the specific gaming period (for low probability gaming state) shown in FIG. 15 have the same variation. The pattern can be determined. Therefore, it becomes impossible to distinguish between the low probability gaming state and the high probability gaming state depending on the type of the variation pattern.

  Furthermore, as a feature of the variation pattern determination table shown in FIG. 13 to FIG. 15, the special symbol variation time is set to be short when the gaming state is the short-time gaming state when the jackpot determination result is a loss. . For example, in the variation pattern determination table shown in FIG. 13, if the number of reserved balls is “2” or “3” when the jackpot determination result is a loss, the game is based on the reach determination random number value in the short-time game state. The variation pattern 11 (shortening variation B) with a variation time of 3000 ms is set with a probability of 95%, but in the non-time-saving gaming state, the variation pattern 10 (shortening variation A) with a variation time exceeding 3000 ms is determined. Is done. In this manner, the variation time is set to be short when the time-saving gaming state is entered.

  Furthermore, the variation pattern determination tables shown in FIGS. 13 and 14 are configured such that the reach is easier when the number of reserved balls is smaller than when the number of retained balls is large. For example, in the variation pattern determination table shown in FIG. 13, in the non-time-saving gaming state, the probability of reaching when the jackpot determination result of the first special symbol is lost indicates that the number of reserved balls is “0” to “ When it is “2”, it is 20%, whereas when it is “3”, it is set to 10%.

  When configured in this way, when the number of reserved balls is small, it is easier to reach, so when the number of reserved balls is small, the rate of selection of, for example, the fluctuation patterns 8 and 9 is increased. Therefore, if the player continues to play during the reach period, there is a high possibility that a new reserved ball will be generated during the reach period, and the player's willingness to play will be reduced by stopping the fluctuation of special symbols. It can be prevented from being damaged.

<Normal electric accessory operation mode determination table>
FIG. 16 is a diagram showing a normal electric accessory actuating mode determination table. FIG. 16 (a) is a table referred to in the non-short game state, and FIG. 16 (b) is referred to in the short time game state. It is a table.
Specifically, when the long open symbol is determined by the normal symbol lottery performed due to the passing of the game ball to the gate 15, if the gaming state is a non-short game state, the long open symbol TBL1 is used. Thus, the start opening / closing solenoid 14c is energized. According to the long opening TBL1, the second start port 14 is opened twice, and the total opening time is controlled to 4.200 seconds.
In addition, when the short opening symbol is determined in the non-short game state, the start opening / closing solenoid 14c is energized based on the short opening TBL1. According to the short opening TBL1, the second start port 14 is opened once, and the total opening time is controlled to 0.200 seconds.

On the other hand, when the long open symbol is determined, if the game state is the short-time game state, the start opening / closing solenoid 14c is energized based on the long open TBL2. According to the long opening TBL2, the second start port 14 is opened once, and the total opening time is controlled to be 5.000 seconds.
Further, when the short opening symbol is determined in the short-time gaming state, the start opening / closing solenoid 14c is energized based on the short opening TBL2. According to this short opening TBL2, the second start port 14 is opened once, and the total opening time is controlled to 3.000 seconds.

FIG. 17 is a time chart showing the energization timing of the start port opening / closing solenoid 14c for each table.
As shown in FIG. 17A, when the second starting port 14 is controlled with reference to the long opening TBL1, the second starting port 14 is first opened for 0.2 seconds and then closed for 4 seconds. Again for 4 seconds.
Further, as shown in FIG. 17B, when the second start port 14 is controlled with reference to the long opening TBL2, the second start port 14 is opened for 5.0 seconds.
On the other hand, as shown in FIG. 17 (c), when the second starting port 14 is controlled with reference to the short opening TBL1, the second starting port 14 is opened only for 0.2 seconds. As shown in (d), when the second start port 14 is controlled with reference to the short opening TBL2, the second start port 14 is opened for 3.0 seconds.

<Special symbol pre-judgment table>
FIG. 18 is a diagram showing a prior determination table for determining in advance the results of the big hit lottery.
The pre-determination table shown in FIG. 18 shows the types of special symbol display devices (types of start port detection switches that detect that a game ball has won a start port), special symbol determination random numbers, jackpot symbol random numbers, reach Based on the determination random number value or the like, winning information for determining the result of the jackpot lottery in advance is generated. Then, based on the generated winning information, a start winning designation command for determining the result of the jackpot lottery in advance is generated.

  Here, the start winning designation command is composed of 1-byte MODE data for identifying the command classification and 1-byte DATA data indicating the content (function) of the command. In the present embodiment, when the MODE data is “E8H”, a start winning designation command corresponding to the winning of the game ball is shown at the first start opening 13, and when the MODE data is “E9H”, the second start opening is indicated. 14 shows a start winning designation command corresponding to the winning of a game ball.

First, the prior determination table of the first special symbol display device 20 will be described.
In the special symbol prior determination table shown in FIG. 18, the special symbol determination random number value in the first special symbol display device 20 is determined to be a big hit of “7” or “317”, and the type of the special symbol is the first special symbol 1. (Stop symbol data is “01”), and when the game state is the non-short-time game state and the random number value for special figure variation is “0” to “29”, the winning information 1 is set. Then, when a game ball wins the first start port 13, start winning designation commands “E8H” and “01H” are generated.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has been won, and the special symbol type is the first special symbol 1 and the gaming state is the non-short game state, If the random number value is “30” to “99”, the winning information 2 is set. Then, when a game ball wins the first start port 13, start winning designation commands “E8H” and “02H” are generated.

  In addition, if it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot, the special symbol type is the first special symbol 2 or 3, and the gaming state is a non-short game state. The winning information 3 is set regardless of the random numbers “0” to “99” for changing the figure. Then, when a game ball wins at the first start port 13, start winning designation commands “E8H” and “03H” are generated.

  In addition, it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot, the special symbol type is the first special symbol 4 or the first special symbol 5, and the gaming state is the non-short game state. If there is, the winning information 4 or the winning information 5 is set regardless of the special figure changing random numbers “0” to “99”, and the start winning designation command “E8H” “04H” or “E8H” “05H” is generated. To do.

  Further, when it is determined that the special symbol determination random number value in the first special symbol display device 20 has won the jackpot, the special symbol type is the first special symbol 6, and the gaming state is the non-short game state, the first As with the special symbol 1, if the random number value for special figure variation is “0” to “29”, the winning information 1 is set, and if the random number value for special figure variation is “30” to “99”, the prize is won. Information 2 is set. The start winning designation commands of the winning information 1 and 2 are as described above.

  In addition, when the special symbol determination random number value in the first special symbol display device 20 is determined to be a small hit and the gaming state is a non-short-time gaming state, regardless of the special symbol variation random value “0” to “99”. Then, the winning information 6 is set, and start winning designation commands “E8H” and “06H” are generated.

Next, a case where the special symbol determination random number value in the first special symbol display device 20 is a loss other than the big hit or the small hit will be described.
When the special symbol determination random number value is lost and the gaming state is the non-short game state, the winning information is determined based on the reach determination random value and the special symbol variation random value.
Specifically, when the reach determination random number value is “0” to “89”, the winning information 7 is set regardless of the special figure variation random value “0” to “99”, and the start winning designation command is set. “E8H” and “07H” are generated.
On the other hand, when the reach determination random value is “90” to “99” and the special figure variation random value is “0” to “69”, the winning information 8 is set and the special figure variation random value is “70”. In the case of "" to "99", the winning information 9 is set. Then, when a game ball wins at the first start port 13, a start winning designation command “E8H” “08H” or “E8H” “09H” is generated.

  In addition, during the short-time game, regardless of whether the special symbol determination random number in the first special symbol display device 20 is a big hit, a small hit, or a lost game, Setting of winning information corresponding to winning of a game ball and generation of a start winning designation command are not performed.

  As will be described later, the gaming machine 1 of the present embodiment is a type of gaming machine that prioritizes symbol variation corresponding to the second special symbol display device 21. In this type of gaming machine, as a result of the prior determination as to whether or not the random number value for special symbol determination in the first special symbol display device 20 in which the symbol variation is not prioritized during the short-time game is won by the jackpot, When the player is informed of the jackpot and the jackpot by a pre-decision effect, the player is informed that the jackpot is present on the first special symbol display device 20 where the symbol variation is not prioritized. In the state where the jackpot of the first special symbol display device 20 is kept on hold by winning the game ball at the second starting port where the symbol variation is performed with priority, the jackpot lottery in the second special symbol display device 21 is held. Can receive. In this case, the gambling ability of the gaming machine is remarkably increased, which is not appropriate. Therefore, in the gaming machine 1 of the present embodiment, as described above, setting of winning information and generation of a starting winning designation command corresponding to the winning of a game ball at the first starting port 13 which is the non-priority side during the short-time game are generated. Do not do.

Next, the prior determination table of the second special symbol display device 21 will be described.
In the special symbol prior determination table shown in FIG. 18, the special symbol determination random number value in the second special symbol display device 21 is determined to be a big hit of “7” or “317”, and the type of the special symbol is the second special symbol 1. At this time, if the special figure variation random value is “0” to “29”, the winning information 11 is set, and if the special figure variation random value is “30” to “99”, the prize information 12 is set. Set. Then, when a game ball wins at the second start opening 14, a start winning designation command “E9H” “01H” or “E9H” “01H” is generated.

In addition, if the special symbol determination random number value in the second special symbol display device 21 is determined to have won the jackpot and the type of the special symbol is the second special symbol 2, the special symbol variation random value “0” to “ Regardless of “99”, the winning information 13 is set. Then, when a game ball wins at the first start port 13, start winning designation commands “E9H” and “03H” are generated.
Further, when it is determined that the special symbol determination random number value in the second special symbol display device 21 has won the jackpot and the type of the special symbol is the second special symbol 3, the special symbol is the same as the second special symbol 1. If the random number for variation is “0” to “29”, the winning information 11 is set, and if the random number for changing the special figure is “30” to “99”, the winning information 12 is set. Then, when a game ball wins at the second start opening 14, a start winning designation command “E9H” “01H” or “E9H” “01H” is generated.

  When the special symbol determination random number value in the second special symbol display device 21 is determined to be a small hit, the winning information 14 is set irrespective of the special symbol variation random value “0” to “99”. Then, when a game ball wins at the second start opening 14, start winning designation commands “E9H” and “04H” are generated.

Next, a case where the special symbol determination random number value in the second special symbol display device 21 is a loss other than the big hit or the small hit will be described.
When the special symbol determination random number value is lost, the game state is the non-short game state, and the reach determination random number value is “0” to “89”, the special symbol variation random value “0” to “99” Regardless of, winning information 15 is set, and start winning designation commands “E9H” and “05H” are generated.
On the other hand, the special symbol determination random number value is lost, the gaming state is a non-short game state, the reach determination random value is “90” to “99”, and the special symbol variation random value is “0” to “69”. In this case, the winning information 16 is set, and when the special figure changing random value is “70” to “99”, the winning information 17 is set. Then, when a game ball wins at the second start opening 14, a start winning designation command “E9H” “06H” or “E9H” “07H” is generated.

Further, when the special symbol determination random number value is lost, the game state is the short-time game state, and the reach determination random number value is “0” to “94”, the special symbol variation random value “0” to “99” Regardless of “”, winning information 15 is set, and start winning designation commands “E9H” and “05H” are generated.
Also, the special symbol determination random number value is lost, the gaming state is the short-time gaming state, the reach determination random number value is “90” to “99”, and the special symbol variation random value is “0” to “69”. In this case, the winning information 16 is set, and when the special figure changing random value is “70” to “99”, the winning information 17 is set. Then, when a game ball wins at the second start opening 14, a start winning designation command “E9H” “06H” or “E9H” “07H” is generated.

As described above, in the special symbol pre-determination table, the special symbol determination random number value determines whether it is “big hit”, “small hit”, or “lost”, and the big hit symbol random value for “long hit”, “per development”, The type of special game “short win” and “whether or not to shift to the high probability game state” are determined.
Furthermore, because the reach determination random number value determines whether or not a reach has occurred, it is possible to determine the type of jackpot and the presence or absence of a reach before starting the change of special symbols by using the DATA data of the start winning designation command It becomes. For example, if the start prize designation command is “E8H” or “01H” in the prize information 1, it is possible to discriminate information such as the first start slot prize and the probability variation length. In addition, since it is always accompanied by “reach” in the case of a jackpot, it can also be determined that a reach occurs due to a jackpot.

  The prior determination table shown in FIG. 18 is similar to the variation pattern determination table for the normal gaming state shown in FIG. However, the prior determination table shown in FIG. 18 is used at the time of winning a game ball at the start, whereas the special symbol change pattern determination table shown in FIG. 13 is used at the start of special symbol change. Yes. Furthermore, it is different whether or not “the number of reserved balls” is referred to. For this reason, in the prior determination table shown in FIG. 18, it is possible to determine the type of jackpot or reach, but it is impossible to determine [normal fluctuation] and “shortening fluctuation”.

<Description of gaming state>
Next, the gaming state when the game progresses will be described.
In the present embodiment, the game progresses in any one of the “low probability gaming state”, “high probability gaming state”, “time / short gaming state”, and “non-time / short gaming state”.
However, while the game is in progress, if the game state is “low probability game state” or “high probability game state”, it is always “time-short game state” or “non-time-short game state”. In other words, when it is “low probability gaming state” and “short-time gaming state”, “low probability gaming state” and “non-short-time gaming state”, and “high probability gaming state” There are a case of “time-short gaming state” and a case of “high-probability gaming state” and “non-time-short gaming state”.
Further, in the case of the “low probability gaming state” and the “non-short-time gaming state”, there are a specific game period after the small hit and a non-specific game period after the small hit. In the case of the “low probability gaming state” and the “non-short game state”, the time when it is not the specific game period after the end of the small hit is referred to as the “normal game state”.

  In the present embodiment, the “low probability gaming state” means that in the jackpot lottery performed on the condition that a game ball has entered the first starting port 13 or the second starting port 14, the winning probability of the jackpot is 1 / The game state set to 299.5. The jackpot winning here is to acquire a right to execute a “long win game” or a “short win game” which will be described later.

  On the other hand, the “high probability gaming state” means a gaming state in which the jackpot winning probability is set to 1 / 29.95. Therefore, in the “high probability gaming state”, it is easier to acquire the right to execute “game per long” or “game per short” than in the “low probability gaming state”.

In the present embodiment, the “non-short game state” means that the time required for the lottery is set to 10 seconds in the normal symbol lottery performed on the condition that the game ball has passed through the gate 15 and the game is long open. A game in which the total opening time of the second starting port 14 when the symbol is determined is set to 4.2 seconds and the total opening time of the second starting port 14 when the short symbol is determined is set to 0.2 seconds State.
On the other hand, the “short-time gaming state” means that in the normal symbol lottery performed on the condition that the game ball has passed through the gate 15, the time required for the lottery is set to 1 second, and the long open symbol Is a gaming state in which the total opening time of the second starting port 14 is determined to be 5 seconds, and the total opening time of the second starting port 14 is determined to be 3 seconds when the short opening symbol is determined.

  Also, in the “short-time gaming state”, the probability of winning in the normal symbol lottery is higher than in the “non-short-time gaming state”. Therefore, in the “short time gaming state”, the second start port 14 is more easily controlled to the second mode as long as the game ball passes through the gate 15 than in the “non-short time gaming state”. As a result, in the “short-time gaming state”, the player can advance the game without consuming the game ball, and the game efficiency can be greatly increased as compared to the non-short-time gaming state.

Furthermore, in the gaming machine 1 of the present embodiment, when the game ball enters the second start port 14, the winning percentage that is advantageous to the player is greater than when the game ball enters the first start port 13. Therefore, during the short-time game, it is easier to win a jackpot advantageous to the player than during the normal game.
Note that the probability of winning in the normal symbol lottery may be set so that it does not change in any of the “non-short-time gaming state” and the “time-short gaming state”.

  In this embodiment, the “specific game period after the end of the small hit” is a variation pattern determination table (FIG. 5) that can determine the same effect as the high probability game state in order to have an expectation that the state is a high probability game state. 15) refers to the game period referred to.

Next, the progress of the game in the gaming machine 1 will be described using a flowchart.
<Main processing of main control board>
FIG. 19 is a flowchart for explaining main processing by the main control board.
When power is supplied from the power supply board 170, a system reset occurs in the main CPU 111, and the main CPU 111 performs the following main processing.
First, in step S10, the main CPU 111 performs an initialization process. In this process, the main CPU 111 reads a startup program from the main ROM 112 and initializes a flag stored in the main RAM 113.

In step S20, the main CPU 111 performs a game random number update process for updating the variation pattern random value and the reach determination random value.
In step S30, the main CPU 111 updates the special symbol determination initial value random number, the big hit symbol initial value random number, and the small hit symbol initial value random number.
After that, the main CPU 111 repeats the processes in steps S20 and S30 until a predetermined interrupt process is performed.
(Timer interrupt processing of main control board)

<Timer interrupt processing of main control board>
FIG. 20 is a flowchart for explaining timer interrupt processing by the main control board.
A clock pulse is generated every predetermined period (4 milliseconds, hereinafter referred to as “4 ms”) by the reset clock pulse generation circuit provided on the main control board 110, so that the timer interrupt processing described below is performed. Executed.
First, in step S101, the main CPU 111 saves the information stored in the register to the stack area.
Next, in step S102, the main CPU 111 updates the special symbol time counter, updates the special game timer counter such as the opening time of the special electric accessory, updates the normal symbol time counter, and updates the general electricity release time counter. Time control processing for updating various timer counters such as processing is performed.
Specifically, the main CPU 111 performs a process of subtracting 1 from the special symbol time counter, the special game timer counter, the normal symbol time counter, and the general electricity open time counter.

In step S103, the main CPU 111 performs a random number update process for the special symbol determination random number value, the big hit symbol random number value, the small hit symbol random number value, and the hit determination random number value.
Specifically, 1 is added to each random number counter to update the random number counter. When the addition result exceeds the maximum value in the random number range, the random number counter is reset to 0. When the random number counter makes one round, the random number is updated from the initial random number value at that time.
In step S104, the main CPU 111 performs an initial value random number update process for updating the random number counter by adding one to the special symbol determination initial value random number counter, the big hit symbol initial value random number counter, and the small hit symbol initial value random number counter. .

In step S105, the main CPU 111 performs input control processing.
In this process, the main CPU 111 detects the first start opening detection switch 13a, the second start opening detection switch 14a, the gate detection switch 15a, the first big winning opening detection switch 16a, the second big winning opening detection switch 17a, and the general winning opening detection. An input process for determining whether or not there is an input to each switch of the switch 18a is performed. Specifically, this will be described later with reference to FIGS.
In step S <b> 106, the main CPU 111 performs a special symbol special power control process for controlling special symbols and special electric accessories. Details will be described later with reference to FIGS.
In step S <b> 107, the main CPU 111 performs a normal / normal power control process for controlling the normal symbol and the ordinary electric accessory. Details will be described later with reference to FIGS. 33 to 35.

In step S108, the main CPU 111 performs a payout control process.
In this payout control process, the main CPU 111 determines whether or not a game ball has won a prize in the first grand prize opening 16, the second big prize opening 17, the first starting opening 13, the second starting opening 14, and the general winning opening 18. When a check is made and there is a winning, a payout number designation command corresponding to each is transmitted to the payout control board 130.
More specifically, a general winning opening prize ball counter, a large winning opening prize ball counter, and a starting opening prize ball counter (for example, the first starting opening prize ball counter updated in FIG. 21 (step S132) described later). The payout number designation command corresponding to each winning opening is transmitted to the payout control board 130. Thereafter, predetermined data is subtracted from the prize ball counter corresponding to the sent out number designation command and updated.
In step S109, the main CPU 111 performs data creation processing of external information data, start opening / closing solenoid data, special winning opening opening / closing solenoid data, special symbol display device data, normal symbol display device data, and a storage number designation command.

In step S110, the main CPU 111 performs output control processing.
In this output control process, the main CPU 111 performs a port output process for outputting the signals of the external information data, the start opening / closing solenoid data, and the big prize opening opening / closing solenoid data created in step S109.

The main CPU 111 also turns on the special symbol display device data and the normal symbol created in step S109 to turn on the LEDs of the first special symbol display device 20, the second special symbol display device 21, and the normal symbol display device 22. Display device output processing for outputting display device data is performed. Further, the main CPU 111 also performs command transmission processing for transmitting a command set in the effect transmission data storage area of the main RAM 113.
In step S111, the main CPU 111 restores the information saved in step S101 to the register of the main CPU 111.

<Input control processing>
FIG. 21 is a flowchart for explaining input control processing by the main control board.
First, in step S121, the main CPU 111 determines whether or not a detection signal is input from the general winning opening detection switch 18a, that is, whether or not a game ball has entered the general winning opening 18. When the main CPU 111 receives a detection signal from the general winning opening detection switch 18a, the main CPU 111 adds predetermined data to the general winning opening prize ball counter used for the winning ball and updates it.

In step S122, the main CPU 111 has input a detection signal from the first big prize opening detection switch 16a or the second big prize opening detection switch 17a, that is, the game ball is in the first big prize opening 16 or the second big prize. It is determined whether or not a ball has entered the mouth 17.
When the main CPU 111 receives a detection signal from the first grand prize opening detection switch 16a, the main CPU 111 adds and updates predetermined data to the big prize opening prize ball counter used for the prize ball, and also updates the first grand prize prize. The first grand prize opening entrance counter (C1) for counting the game balls won in the mouth 16 and the second grand prize opening 17 and the second grand prize entrance entrance counter (C2) are added to the storage area counter. Update.

  In step S123, the main CPU 111 determines whether or not the detection signal from the first start port detection switch 13a has been input, that is, whether or not the game ball has entered the first start port 13 and determines the jackpot. Predetermined data to perform is set. Details will be described later with reference to FIG.

In step S124, the main CPU 111 determines whether or not a detection signal from the second start port detection switch 14a has been input, that is, whether or not a game ball has entered the second start port 14.
When the main CPU 111 receives a detection signal from the second start port detection switch 14a, the main CPU 111 performs the same process as in step S123.
However, in this second start port detection switch input process, “1” is added to the second special symbol hold number (U2) storage area, and the extracted special symbol determination random number value, jackpot symbol random number value, small hit value The random number value for symbols and the random number value for reach determination are stored in the second special symbol storage area. That is, the first start port detection switch input process and the second start port detection switch input process are different from each other only in the storage area for storing various data, and all other processes are the same.

  In step S125, the main CPU 111 determines whether the gate detection switch 15a has input a signal, that is, whether the game ball has passed through the normal symbol gate 15. This gate detection switch input process will be described later with reference to FIG.

<First start port detection switch input process>
FIG. 22 is a flowchart for explaining the first start port detection switch input process by the main control board.
First, in step S131, the main CPU 111 determines whether or not a detection signal from the first start port detection switch 13a has been input.
When the detection signal from the first start port detection switch 13a is input (Yes in step S131), the process proceeds to step S132, and when the detection signal from the first start port detection switch 13a is not input. (No in step S131), the first start port detection switch input process is terminated.
In step S132, the main CPU 111 performs a process of adding predetermined data to the start opening prize ball counter used for the prize ball and updating it.

Next, in step S133, the main CPU 111 determines whether or not the number of reservations set in the first special symbol reservation number (U1) storage area is less than four. If the number of reserves set in the first special symbol hold count (U1) storage area is less than 4, the process proceeds to step S134, and the first special symbol hold count (U1) storage area is set. If the number of holdings is not less than 4, the first start port detection switch input process is terminated.
In step S134, the main CPU 111 adds “1” to the first special symbol reservation number (U1) storage area and stores it.

In step S135, the main CPU 111 acquires a random number for determining a special symbol, searches for a free storage unit in order from the first storage unit in the first special symbol storage area, and stores the free storage unit in the free storage unit. The acquired random number for special symbol determination is stored.
In step S136, the main CPU 111 obtains a jackpot symbol random number, searches for a free storage unit in order from the first storage unit in the first special symbol storage area, and acquires it in the free storage unit. The jackpot symbol random number value is stored.

In step S137, the main CPU 111 acquires a random number value for a small bonus symbol, searches for a free storage unit in order from the first storage unit in the first special symbol storage area, and stores the free storage unit in the free storage unit. The acquired random number value for the small hit symbol is stored.
In step S138, the main CPU 111 acquires game random values (variation pattern random values and reach determination random values), and stores storage units that are vacant in order from the first storage unit in the first special symbol storage area. The game random number value (random number value for variation pattern and random number value for reach determination) acquired in the free storage unit is stored.

  In step S139, the main CPU 111 performs a pre-determination process (FIG. 19) for determining each random value acquired in steps S135 to S138 based on a pre-determination table corresponding to the current gaming state.

<Preliminary judgment processing>
FIG. 23 is a flowchart for explaining pre-determination processing by the main control board.
First, in step S151, the main CPU 111 determines the special symbol determination random value newly written in the special symbol hold storage area based on the prior determination table shown in FIG.

Next, in step S152, the main CPU 111 determines whether or not the jackpot determination as a result of the jackpot determination in step S151 has been provisionally determined.
When it is tentatively determined to be a big hit (Yes in step S152), the main CPU 111 moves the process to step S153, and when it is not tentatively decided to be a big hit (No in step S152), the process moves to step S155.
When it is temporarily determined that the jackpot is determined in step S152, the main CPU 111 determines the newly written jackpot symbol random value in step S153, and temporarily determines the type of special symbol (stop symbol data).

Next, in step S154, the main CPU 111 generates a start winning designation command corresponding to the tentatively determined special symbol type, sets it in the effect transmission data storage area, and ends the preliminary determination process.
The start winning designation command is provided so as to be identifiable in the same manner as the variation pattern designation command shown in FIGS. 9 to 11 and is associated with information on big hits, small hits and loses.

  If it is not tentatively determined to be a big hit in step S152 (No in step S152), the main CPU 111 makes a tentative determination as to whether or not it is determined to be a big win in step S155.

  If it is not tentatively determined to be a small hit in step S155 (No in step S155), in step S157, the main CPU 111 sets a start winning designation command indicating a loss in the effect transmission data storage area. The pre-determination process ends.

  On the other hand, if it is tentatively determined to be a small win (Yes in step S155), the main CPU 111 sends a start winning designation command indicating that it is a small win, that is, a chance effect, in step S156. Set in the storage area and end the pre-determination process.

  Even in the second start port detection switch input process shown in step S124 (FIG. 17), the main CPU 111 generates winning information with reference to the pre-determination table, and controls the start winning designation command based on the winning information. A pre-determination process to be transmitted to the substrate 120 is performed.

With the above prior determination process, when the game ball enters the first start port 13 or the second start port 14, the winning information can be transmitted to the effect control board 120 as a start winning designation command.
Therefore, the sub CPU 121 of the effect control board 120 that has received the start winning designation command analyzes the start winning command, and starts the change of the special symbol triggered by the winning of the game ball at the first start opening this time. A predetermined effect can be executed in advance.
However, this pre-determination process is determined according to the game state at the time when the game ball enters the start ports 13 and 14 to the last. Therefore, when the gaming state is changed before processing the first hold or the second hold reserved by the entry, the result of the jackpot determination process described later may be different from the result of the prior determination process. There is.

<Gate detection switch input processing>
FIG. 24 is a flowchart for explaining gate detection switch input processing by the main control board.
First, the main CPU 111 determines whether or not a detection signal from the gate detection switch 15a is input in step S171.

If it is determined in step S171 that the detection signal from the gate detection switch 15a has been input (Yes in step S171), the main CPU 111 determines in step S172 whether or not the normal symbol holding number (G) is less than 4. To do.
When the detection signal from the gate detection switch 15a is not input (No in step S171), the main CPU 111 ends the gate detection switch input process.
In the present embodiment, when the game ball passes through the normal symbol gate 15, the normal symbol is displayed in a variable manner. The upper limit reserved number of the right of the normal symbol for variable display is set to "4".

If it is determined in step S172 that the normal symbol hold count (G) is less than 4 (Yes in step S172), the main CPU 111 stores the normal symbol hold count (G) in the normal symbol hold count (G) storage area in step S173. A value obtained by adding “1” to the normal symbol hold count (G) is stored as a new normal symbol hold count (G).
If it is determined in step S172 that the normal symbol hold number (G) is not less than 4 (4) (No in step S172), the gate detection switch input process is terminated.

Next, in step S174, the main CPU 111 extracts one hit determination random number value from a random number range (for example, 0 to 19) prepared in advance, and stores the extracted random number value in the normal symbol holding storage area. .
Next, in step S175, the main CPU 111 extracts one symbol determination random number value from a random number range (for example, 0 to 10) prepared in advance, and stores the extracted random number value in the normal symbol holding storage area. This completes the gate detection switch input process.

<Special Figure Special Electric Control Process>
FIG. 25 is a flowchart for explaining the special figure special electric control process by the main control board.
First, the main CPU 111 loads the value of the special figure special processing data in step S181, and refers to the branch address from the special figure special processing data loaded in step S182.

If the special figure special electric processing data = 0 in step S183 (Yes in step S183), the main CPU 111 shifts the processing to the special symbol storage determination process (step S184).
When the special figure special electric processing data = 0 is not 0 in step S183 (No in step S183), the main CPU 111 determines whether the special figure special electric treatment data = 1 in step S185.
If the special figure special electricity processing data = 1 in step S185 (Yes in step S185), the main CPU 111 shifts the processing to the special symbol variation process (step S186).

When the special figure special power processing data is not 1 in step S185 (No in step S185), the main CPU 111 determines whether the special figure special power processing data = 2 in step S187.
If the special figure special electric processing data = 2 in step S187 (Yes in step S187), the main CPU 111 shifts the processing to the special symbol stop process (step S188).
When the special figure special electric processing data = 2 is not 2 in step S187 (No in step S187), the main CPU 111 determines whether the special figure special electric treatment data = 3 in step S189.

If the special figure special processing data = 3 in step S189 (Yes in step S189), the main CPU 111 shifts the processing to the jackpot game processing (step S190).
When the special figure special electric processing data = 3 is not 3 in step S189 (No in step S189), the main CPU 111 determines whether the special figure special electric treatment data = 4 in step S191.
If the special figure special electric processing data = 4 in step S191 (Yes in step S191), the main CPU 111 shifts the processing to the small hit game processing (step S192).
If the special figure special power processing data is not 4 in step S191 (No in step S191), the main CPU 111 determines that the special figure special power processing data = 5, and moves the processing to the special game end processing (step S193).

<Special symbol memory determination processing>
FIG. 26 is a flowchart for explaining special symbol memory determination processing by the main control board.
In step S <b> 201, the main CPU 111 determines whether or not special symbols are being displayed in a variable manner. If special symbol variation display is in progress, that is, if the special symbol time counter ≠ 0 (Yes in step S201), the special symbol storage determination process is terminated.
On the other hand, if the special symbol variation display is not in progress, that is, if the special symbol time counter = 0 (No in step S201), the main CPU 111 shifts the processing to step S202 and stores the second special symbol hold count (U2) storage area. Is determined to be 1 or more.

If the second special symbol hold count (U2) storage area is not 1 or more (No in step S202), the CPU 111 moves the process to step S204, and the second special symbol hold count (U2) storage area is “1”. When it determines with it being above, a process is moved to step S203.
Thus, the second special symbol storage area is processed with priority over the first special symbol storage area.
In step S203, the main CPU 111 subtracts “1” from the value stored in the second special symbol hold count (U2) storage area and stores it.

In step S204, the main CPU 111 determines whether or not the first special symbol reservation number (U1) storage area is 1 or more. If the first special symbol reservation number (U1) storage area is not 1 or more (No in step S204), the process proceeds to step S215, and the first special symbol reservation number (U1) storage area is "1" or more. (Yes in step S204), the process proceeds to step S205.
In step S205, the main CPU 111 subtracts “1” from the value stored in the first special symbol hold count (U1) storage area and stores it.

  In step S206, the main CPU 111 determines a predetermined random number value (a special symbol determination random number value stored in a special symbol reservation storage area corresponding to the special symbol reservation number (U) storage area subtracted in steps S202 to S205). The big winning symbol random number value, the small bonus symbol random number value, the reach determination random number value, and the variation pattern random number value) and the start winning designation command are shifted. Specifically, a predetermined random number value and a start winning designation command stored in the first storage unit to the fourth storage unit in the first special symbol storage area or the second special symbol storage area are stored in the previous storage unit. Shift to.

  Here, the predetermined random number value and the start winning designation command stored in the first storage unit are shifted to the determination storage area (the 0th storage unit). At this time, the predetermined random number value and the start winning designation command stored in the first storage unit are written in the determination storage area (0th storage section) and already written in the determination storage area (0th storage section). The stored data will be deleted from the special symbol reserved storage area. Thereby, the predetermined random number value and the start winning designation command used in the previous game are deleted. After the shift, the start winning designation command MODE is processed so as to correspond to the storage area after the shift.

  In step S207, the main CPU 111 reads the data (the special symbol determination random number value, the jackpot symbol random number value, the small bonus symbol symbol) written in the determination storage area (the 0th storage unit) of the special symbol hold storage area in the above step S206. The jackpot determination process is executed based on the random number value. Details will be described later with reference to FIG.

In step S208, the main CPU 111 performs a variation pattern determination process.
In the variation pattern determination process, first, the game state storage area of the main RAM 113 is referenced to determine a variation pattern determination table based on the current game state. Specifically, when the game state is the high probability game state, the variation pattern determination table for the high probability game state shown in FIG. 14 is determined, and when the game state is the low probability game state, the number of specific periods (T) = 0. After determining the fluctuation pattern determination table of the normal gaming state (for low probability gaming state) shown in FIG. 13 and when the number of specific periods (T)> 0 in the low probability gaming state, after the small hit shown in FIG. The variation pattern determination table for the specific gaming period (for the low probability gaming state) is determined.
Then, the variation pattern is determined based on the determined variation pattern determination table with reference to the special symbol determination random number value, the jackpot symbol random number value, the reach determination random number value, and the variation pattern random number value.

In step S209, the main CPU 111 sets a variation pattern designation command corresponding to the determined variation pattern in the effect transmission data storage area.
In step S210, the main CPU 111 confirms the gaming state at the start of variation, and sets a gaming state designation command corresponding to the current gaming state in the effect transmission data storage area.

  In step S211, the main CPU 111 starts the special symbol display on the special symbol display devices 20 and 21. That is, the special symbol variation display data is set in the processing area. Thereby, when the information written in the processing area relates to the first hold (U1), the first special symbol display device 20 blinks, and when the information related to the second hold (U2), the second special symbol display. The device 21 will blink.

In step S212, when the main CPU 111 starts displaying the variation of the special symbol as described above, the variation time (counter value) based on the variation pattern determined in step S208 is displayed in the special symbol time counter in the special symbol time counter. set. The special symbol time counter is subtracted every 4 ms in S110.
In step S213, the main CPU 111 sets 00H to the customer waiting determination flag. That is, the customer waiting determination flag is cleared. Note that the customer waiting determination flag = “00H” indicates that the special symbol is currently being displayed or the special game is being displayed. On the other hand, if the special symbol is not being displayed and the game is not in a special game, the customer waiting determination flag “01H” is stored. If the customer waiting determination flag = “01H” is stored, a customer waiting command is set in step S217, which will be described later, and it is transmitted to the effect control board 120 that there is no special symbol variation display or special game.

In step S214, the main CPU 111 sets special figure special electricity processing data = 1, and ends the special symbol memory determination process.
If it is determined in step S204 that the first hold (U1) is “0”, that is, if neither the first hold (U1) nor the second hold (U2) is reserved, the main CPU 111 In step S215, it is determined whether 01H is set in the customer waiting determination flag.

If 01H is set in the customer waiting determination flag (Yes in step S215), the special symbol storage determination process is terminated, and if 01H is not set in the customer waiting determination flag (No in step S215). Then, the process proceeds to step S216.
In step S216, the main CPU 111 sets 01H to the customer waiting determination flag so that the customer waiting command is not set many times in step S217 to be described later.
In step S217, the main CPU 111 sets a customer waiting command in the effect transmission data storage area, and ends the special symbol memory determination process.

<Big hit judgment processing>
FIG. 27 is a flowchart for explaining the big hit determination process by the main control board.
First, in step S221, the main CPU 111 determines whether or not the high probability game flag is turned on in the high probability game flag storage area. The case where the high probability game flag is turned on is a case where the current game state is a high probability game state. If the high probability game flag is turned on, the process proceeds to step S222. If the high probability game flag is not turned on, the process proceeds to step S223.

If it is determined in step S221 that the high-probability gaming flag is turned on, that is, the current gaming state is the high-probability gaming state (Yes in step S221), the main CPU 111 selects “ Select “Randomness Judgment Table”.
If it is determined in step S221 that the high probability gaming flag is not turned on, that is, the current gaming state is not the high probability gaming state (low probability gaming state) (No in step S221), the main CPU 111 performs step In S223, the “random probability determination table at low probability” is selected.

In S224, the main CPU 111 selects the special symbol determination random number value written in the determination storage area (the 0th storage unit) of the special symbol hold storage area in Step S206 (FIG. 26) in Step S222 or S223. The determination is made based on the “high probability random number determination table” or the “low probability random number determination table”.
More specifically, when the special symbol reserved storage area shifted in step S206 (FIG. 26) is the first special symbol storage area, the jackpot for the first special symbol display device of FIG. Referring to the determination table, if the special symbol storage area shifted in step S206 (FIG. 26) is the second special symbol storage area, the jackpot for the second special symbol display device of FIG. With reference to the determination table, it is determined whether it is “big hit”, “small hit”, or “lost” based on the special symbol determination random number.

In step S225, the main CPU 111 determines whether or not the jackpot determination is made as a result of the jackpot determination in S224.
If it is determined that the jackpot is determined (Yes in step S225), the process proceeds to step S226. If it is not determined that the jackpot is determined (Yes in step S225), the process proceeds to step S229.

  In step S226, the main CPU 111 determines the jackpot symbol random number value written in the determination symbol storage area (the 0th storage unit) of the special symbol reservation storage area in step S206 (FIG. 26), and determines the special symbol type (stop). Jackpot symbol determination processing is performed for determining the symbol data) and setting the determined stop symbol data in the stop symbol data storage area.

Specifically, when the special symbol holding storage area shifted in step S206 (FIG. 26) is the first special symbol storage area, the jackpot symbol determination table for the first special symbol display device (FIG. 7 ( If the special symbol storage area shifted in step S206 (FIG. 26) is the second special symbol storage area with reference to a), the jackpot symbol determination table for the second special symbol display device ( Referring to FIG. 7A), stop symbol data indicating the type of the special symbol to be stopped is determined based on the jackpot symbol random number value, and the determined stop symbol data is set in the stop symbol data storage area. .
Note that the determined special symbol is used to determine “big hit” or “small hit” in the special symbol stop process of FIG. 29 as will be described later, as well as the big hit game process of FIG. 30 and the small hit of FIG. It is also used to determine the operating mode of the big prize opening in the game process, and is also used to determine the gaming state after the jackpot end in the special game end process of FIG.

In step S227, the main CPU 111 generates an effect symbol designation command corresponding to the special symbol for jackpot, and sets it in the effect transmission data storage area in order to transmit data corresponding to the special symbol to the effect control board 120. .
In step S228, the main CPU 111 determines the gaming state at the time of winning the big win from the information set in the gaming state storage area (the short-time gaming flag storage area, the high probability gaming flag storage area), and indicates the gaming state at the time of winning the big win. The game state information is set in the game state buffer. Specifically, if both the short-time game flag and the high-probability game flag are not set, 00H is set. If the short-time game flag is not set but the high-probability game flag is set, 01H is set. If the short-time game flag is set but the high-probability game flag is not set, 02H is set. If both the short-time game flag and the high-probability game flag are set, 03H is set.

  In this way, apart from the game state storage area (time-short game flag storage area, high-probability game flag storage area), the game state at the time of winning the jackpot is set in the game state buffer. Since the high-probability game flag and the short-time game flag in the state memory area (time-short game flag memory area, high-probability game flag memory area) will be reset, This is because the game state storage area cannot be referred to when determining the game state at the time of the big hit. As described above, by providing a game state buffer for storing game information indicating the game state at the time of winning the big hit, apart from the game state storage area, it is possible to refer to the game information in the game state buffer after the end of the big win Based on the gaming state at the time of winning the jackpot, it is possible to newly set a gaming state after the jackpot (such as a short-time gaming state and a short-time number of times).

If it is not determined in step S225 that the jackpot is large (No in step S225), the main CPU 111 determines whether or not it is determined that the jackpot is determined in step S229.
If it is determined that a small hit (Yes in step S229), the process proceeds to step S230, and if it is not determined to be a small hit (No in step S229), the process proceeds to step S232.
In step S230, the main CPU 111 determines the random symbol value for the small symbol written in the determination storage area (the 0th storage unit) of the special symbol storage area in step S206 (FIG. 26), and determines the type of the special symbol. And a small hit symbol determination process for setting the determined stop symbol data in the stop symbol data storage area is performed.

  Specifically, referring to the small hit symbol determination table in FIG. 7B, stop symbol data indicating the type of the special symbol is determined based on the random number value for the small hit symbol, and the determined stop symbol data is Set in the stop symbol data storage area. In the present embodiment, “small hit A” and “small hit B” are provided as the types of “small hit”. However, regardless of which “small hit” is won, the contents of the small hit games executed thereafter are exactly the same, and the “small hit A” and the “small hit B” indicate that the special symbol display device 20, Only the special symbol stopped and displayed at 21 is different.

In step S231, in order to transmit data corresponding to the special symbol to the effect control board 120, the main CPU 111 generates an effect symbol designation command corresponding to the special symbol for the small hit and sets it in the transmission data storage area for the effect. Then, the process proceeds to step S228.
In step S232, the main CPU 111 determines a special symbol for losing with reference to the loss symbol determination table of FIG. 7C, and sets the determined stop symbol data for loss in the stop symbol data storage area.
In step S233, the main CPU 111 generates an effect designating command corresponding to the special symbol for losing in order to transmit the data corresponding to the special symbol to the effect control board 120, and sets it in the transmission data storage area for the effect. The jackpot determination process ends.

<Special symbol variation processing>
FIG. 28 is a flowchart for explaining special symbol variation processing by the main control board.
In step S241, the main CPU 111 determines whether or not the variation time set in step S212 (FIG. 26) has elapsed (special symbol time counter = 0?). As a result, when it is determined that the variation time has not elapsed (No in step S241), the special symbol variation process is terminated.
When it is determined that the time set in step S212 has elapsed (Yes in step S241), in step S242, the main CPU 111 performs the above step in the routine process (big hit determination process) before the special symbol variation process. The special symbols set in S227, S231, and S233 are stopped and displayed on the special symbol display devices 20 and 21. As a result, the jackpot determination result is notified to the player.

In step S243, the main CPU 111 sets a symbol determination command in the effect transmission data storage area.
In step S244, when the main CPU 111 starts the special symbol stop display as described above, the main CPU 111 sets the symbol stop time (0.5 seconds = 250 counter) in the special symbol time counter. The special symbol time counter is decremented by -1 every 2 ms in S110.
In step S245, the main CPU 111 sets 2 in the special figure special electricity processing data, and ends the special symbol variation process.

<Special symbol stop processing>
FIG. 29 is a flowchart for explaining special symbol stop processing by the main control board.
In step S251, the main CPU 111 determines whether or not the symbol stop time set in step S244 has passed (special symbol time counter = 0). As a result, when it is determined that the symbol stop time has not elapsed (No in step S251), the special symbol stop process is terminated.

In step S252, the main CPU 111 determines whether or not a flag is turned on in the time-saving game flag storage area. The case where the flag is turned on in the short-time game flag storage area is a case where the current game state is the short-time game state.
If the flag is turned on in the time-short game flag storage area (Yes in step S252), the process proceeds to step S253, and if the flag is turned off in the time-short game flag storage area (No in step S252). Then, the process proceeds to step S254.

In step S253, the main CPU 111 performs a time-saving game end determination process.
Specifically, “1” is subtracted from (J) stored in the short-time game count (J) storage area and stored as a new remaining variation count (J), and the stored short-time game count (J) ) Is “0”, and if the number of short-time games (J) = 0, the flag stored in the short-time game flag storage area is cleared (OFF). On the other hand, if the number of hourly games (J) is not 0, the flag stored in the hourly game flag storage area remains on, and the process proceeds to step S254.

In step S254, the main CPU 111 determines whether or not a flag is turned on in the high probability game flag storage area. The case where the flag is turned on in the high probability game flag storage area is a case where the current gaming state is the high probability gaming state.
If the flag is turned on in the high probability game flag storage area (Yes in step S254), the process proceeds to step S255, and if the flag is turned off in the high probability game flag storage area (in step S254). No), the process proceeds to step S256.

  In step S255, the main CPU 111 performs a high probability game end determination process. Specifically, “1” is subtracted from (X) stored in the high-probability game count (X) storage area and stored as a new high-probability game count (X). It is determined whether or not the number of times (X) is “0”. If it is determined that the number of times of high probability games (X) = 0, the flag stored in the high probability game flag storage area is cleared. (OFF). On the other hand, if it is determined that the number of high probability games (X) = 0 is not satisfied, the process proceeds to step S256.

In step S256, the main CPU 111 determines whether or not the specific period number counter (T) = 0. If the specific period number counter (T) = 0 (Yes in step S256), the main CPU 111 proceeds to step S258. If the specific period number counter (T) = 0 is not satisfied (No in step S256), the process proceeds to step S257.
In step S257, the main CPU 111 stores the calculated value obtained by subtracting “1” from the specific period number counter (T) as a new specific period number counter (T).

In step S258, the main CPU 111 confirms the current gaming state and sets a gaming state designation command in the effect transmission data storage area.
In step S259, the main CPU 111 determines whether or not it is a big hit. Specifically, it is determined whether or not the stop symbol data stored in the stop symbol data storage area is that of a jackpot symbol (stop symbol data = 01 to 10). If it is determined that the symbol is a jackpot symbol (Yes in step S259), the process proceeds to step S263. If the symbol is not determined to be a jackpot symbol (No in step S259), the process proceeds to step S260.

In step S260, the main CPU 111 determines whether or not it is a small hit. Specifically, it is determined whether or not the stop symbol data stored in the stop symbol data storage area is a small hit symbol (stop symbol data = 11 to 14).
Here, when it is determined that the symbol is a small winning symbol (Yes in step S260), the main CPU 111 sets 4 in the special figure special electric processing data in step S261, and moves the process to step S265.

If it is not determined that the symbol is a small winning symbol (No in step S260), the process proceeds to step S262, 0 is set in the special symbol special electric processing data, and the special symbol stop processing is terminated.
If it is determined in step S259 that the symbol is a jackpot symbol (Yes in step S259), the main CPU 111 sets 3 in the special figure special processing data in step S263.

In step S264, the main CPU 111 resets the gaming state and the number of time reductions. Specifically, the data in the high probability game flag storage area, the high probability game count (X) storage area, the short time game flag storage area, and the short time game count (J) storage area are cleared.
In step S265, the main CPU 111 determines whether it is “long hit”, “short hit”, or “small hit” according to the stop symbol data, and transmits an opening command corresponding to these types for production. Set in the data storage area.

  In step S266, the main CPU 111 determines whether it is “long hit”, “short hit”, or “small hit” according to the stop symbol data, and sets the opening time according to these types as a special game timer. Set to the counter. The special game timer counter is subtracted every 4 ms in step S110. When this process ends, the main CPU 111 ends the special symbol stop process.

<Big hit game processing>
FIG. 30 is a flowchart for explaining the jackpot game process by the main control board.
First, in step S271, the main CPU 111 determines whether or not it is currently opening. For example, if “0” is stored in the round game count (R) storage area, it is currently open, so it is determined whether the round game count (R) storage area is currently open.
If the main CPU 111 determines that it is currently opening (Yes in Step S271), it moves the process to Step S272, and if it determines that it is not currently opening (No in Step S271), it performs the process in Step S276. Move.

In step S272, the main CPU 111 determines whether or not a preset opening time has elapsed. That is, it is determined whether or not the special game timer counter set in step S266 (FIG. 29) has become “0”. If the special game timer counter = 0, it is determined that the opening time has elapsed.
As a result, if the opening time has not elapsed (No in step S272), the jackpot game process is terminated, and if the opening time has elapsed (Yes in step S272), the process proceeds to step S273. .

In step S273, the main CPU 111 performs a jackpot start setting process.
In the jackpot start setting process, first, an open mode determination table corresponding to the jackpot type is determined according to the stop symbol data. Specifically, as shown in FIG. 11, according to the stop symbol data, an open mode determination table for 1 per long, an open mode determination table for 2 per long, an open mode determination table for short hits, an open for 1 per development Either the mode determination table or the open mode determination table for 2 per development is determined and set. Next, “1” is added to the current round game number (R) stored in the round game number (R) storage area and stored.
In step S273, nothing is stored in the round game number (R) storage area. That is, since no round game has been performed yet, “1” is stored in the round game count (R) storage area.

  In step S274, the main CPU 111 performs a special prize opening process. In this big winning opening opening process, the energization start data of the first big winning opening / closing solenoid 16c and the second big winning opening / closing solenoid 17c are set, and the current round is referred to by referring to the table set in step S273. Based on the number of games (R) and the number of times of opening (K), the opening times of the first big prize opening 16 and the second big prize opening 17 are set in the special game timer counter.

  In step S275, the main CPU 111 determines whether or not K = 1. If K = 1, in order to transmit information on the number of round games to the effect control board 120, the number of round games (R ), A special winning opening (R) round designation command is set in the effect transmission data storage area. For example, at the start of the first round game of jackpot, since the number of round games (R) is set to “1” and K = 1, the winning prize opening 1 round designation command is transmitted to the transmission data for production Set in the storage area. On the other hand, if K = 1 is not set, the jackpot game process is terminated without setting the big winning opening (R) round designation command in the effect transmission data storage area. In other words, the case where K = 1 means the start of a round, and therefore, the winning prize opening (R) round designation command is transmitted only at the start of the round.

In step S276, the main CPU 111 determines whether it is currently ending. Ending here refers to processing after all preset round games have been completed.
Therefore, if it is determined that the current ending is in progress (Yes in step S276), the process proceeds to step S289, and if it is determined that the current ending is not in progress (No in step S276), the process proceeds to step S277. It is.

  In step S277, the main CPU 111 determines whether or not the first big prize opening 16 and the second big prize opening 17 are being closed. If it is determined that the first grand prize port 16 and the second grand prize port 17 are being closed (Yes in step S277), the process proceeds to step S278, and the first grand prize port 16 and the second grand prize port 17 are processed. Is determined not to be closed (No in step S277), the process proceeds to step S279.

In step S278, the main CPU 111 determines whether or not the closing time set in step S280 described later has elapsed. Note that the closing time is also determined by whether or not the special game timer counter = 0 as in the opening time. As a result, if the closing time has not elapsed (No in step S278), the jackpot game process is terminated.
On the other hand, when the closing time has elapsed (Yes in step S278), the main CPU 111 shifts the processing to step S274.

In step S <b> 279, the main CPU 111 determines whether or not an “opening end condition” for ending the opening of the first big winning opening 16 and the second big winning opening 17 is satisfied.
This “opening end condition” is that the value of the first grand prize opening entrance counter (C1) and the second big winning entrance entrance counter (C2) have reached the maximum number (for example, 9) or the maximum opening time. It means that the elapse of time (special game timer counter = 0).
If the main CPU 111 determines that the “opening end condition” is satisfied (Yes in step S279), the main CPU 111 shifts the process to step S280, and determines that the “opening end condition” is not satisfied, the jackpot game process. Exit.

In step S280, the main CPU 111 performs a special winning opening closing process.
In the big prize opening closing process, the main CPU 111 energizes stop data of the first big prize opening / closing solenoid 16c and the second big prize opening solenoid 17c in order to close the first big prize opening 16 and the second big prize opening 17. , And with reference to the release mode determination table (see FIG. 11) determined in step S273, based on the current number of round games (R) and the number of releases (K), the first big prize opening 16 The closing time of the second big winning opening 17 is set in the special game timer counter. As a result, the first big prize opening 16 and the second big prize opening 17 are closed.

In step S281, the main CPU 111 determines whether or not one round has been completed. Specifically, in one round, the number of times of opening (K) is the maximum number of times of opening, or the values of the first grand prize opening entrance counter (C1) and the second grand prize opening entrance counter (C2). Is terminated on the condition that the maximum number (for example, 9) has been reached, it is determined whether or not such a condition is satisfied.
If the main CPU 111 determines that one round has ended (Yes in step S281), the main CPU 111 proceeds to step S282, and if it determines that one round has not ended (in step S282). No), the jackpot game process is terminated.
In step S282, the main CPU 111 sets 0 in the number-of-openings (K) storage area and sets 0 in the number-of-stakes (C) storage area. That is, the number-of-openings (K) storage area and the number of balls received in the big prize opening (C) storage area are cleared.

In step S283, the main CPU 111 determines whether or not the round game number (R) stored in the round game number (R) storage area is the maximum. If the number of round games (R) is the maximum (Yes in step S283), the process proceeds to step S286. If the number of round games (R) is not the maximum (No in step S283), the process proceeds to step S284. Move.
In step S284, the main CPU 111 sets a round end designation command in the effect transmission data storage area according to the number of round games (R) in order to transmit the end information of the round game to the effect control board 120.

Next, in step S285, the main CPU 111 adds “1” to the current round game number (R) stored in the round game number (R) storage area and stores it.
On the other hand, when it is determined in step S283 that the round game number (R) is the maximum, the main CPU 111 resets the round game number (R) stored in the round game number (R) storage area.

Next, the main CPU 111 determines whether it is a big hit of “long win” or “short win” according to the stop symbol data, and transmits an ending command corresponding to the type of big hit to the effect control board 120. Therefore, it is set in the transmission data storage area for production.
In step S288, the main CPU 111 determines whether it is a big hit or "short win" according to the stop symbol data, and sets an ending time according to the type of the big win in the special game timer counter. To do.

In step S289, the main CPU 111 determines whether or not the set ending time has elapsed.
If the main CPU 111 determines that the ending time has elapsed (Yes in step S289), the main CPU 111 sets 5 in the special figure special processing data in step S290 and ends the jackpot game processing.
If it is determined in step S289 that the ending time has not elapsed (No in step S289), the jackpot game process is terminated as it is.

<Small hit game processing>
FIG. 31 is a flowchart for explaining small hit game processing by the main control board.
First, in step S301, the main CPU 111 determines whether or not it is currently opening.
If it is determined that the current opening is being performed (Yes in step S301), the process proceeds to step S302. If it is determined that the current opening is not currently performed (No in step S301), the process proceeds to step S305.

In step S302, the main CPU 111 determines whether or not a preset opening time has elapsed. That is, it is determined whether or not the special game timer counter = 0, and when the special game timer counter = 0, it is determined that the opening time has elapsed.
As a result, if the opening time has not elapsed, the small hit game process is terminated, and if the opening time has elapsed, the process proceeds to step S303.

In step S303, the main CPU 111 performs a small hitting start setting process.
The small hitting start setting process determines an opening mode determination table corresponding to the small hitting type according to the stop symbol data.
Specifically, as shown in FIG. 10, a small hitting release mode determination table (FIG. 12) is determined according to the stop symbol data.

In step S304, the main CPU 111 performs a special prize opening process.
In the special winning opening opening process, first, “1” is added to the number of times of opening (K) stored in the number of times of opening (K) storage area and stored. In addition, in order to open the opening / closing door 16b of the first grand prize winning port 16 and the movable piece 17b of the second grand prize winning port, energization start data of the first grand prize winning opening / closing solenoid 16c and the second grand prize winning port solenoid 17c are set. In addition, with reference to the release mode determination table (see FIG. 11) determined in step S303, the opening times of the first grand prize winning port 16 and the second grand prize winning port 17 are specially set based on the number of times of opening (K). Set to the game timer counter.

  In step S305, the main CPU 111 determines whether it is currently ending. Ending here refers to processing after the game of the preset number of times of opening (K) has been completed. Accordingly, if it is determined that the current ending is in progress (Yes in step S305), the process proceeds to step S304. If it is determined that the current ending is not currently performed (No in step S305), the process proceeds to step S306. It is.

  In step S <b> 306, the main CPU 111 determines whether or not the first big prize opening 16 and the second big prize opening 17 are being closed. If it is determined that the first grand prize port 16 and the second grand prize port 17 are closed, the process proceeds to step S307, and it is determined that the first grand prize port 16 and the second grand prize port 17 are not closed. If so, the process moves to step S308.

  In step S307, the main CPU 111 determines whether or not the closing time set in step S309 described later has elapsed. Note that the closing time is also determined by whether or not the special game timer counter = 0 as in the opening time. As a result, if the closing time has not elapsed (No in step S307), the small hit game process is terminated, and if the closing time has elapsed (Yes in step S307), the process proceeds to step S304. .

In step S <b> 308, the main CPU 111 determines whether or not an “opening end condition” for ending the opening of the first big winning opening 16 and the second big winning opening 17 is satisfied.
This “opening end condition” is that the value of the first grand prize opening entrance counter (C1) and the second big prize opening entrance counter (C2) have reached the maximum number (for example, 9), or This corresponds to the fact that one opening time of the winning opening 16 and the second major winning opening 17 has elapsed (special game timer counter = 0).
If it is determined that the “opening end condition” is satisfied (Yes in step S308), the process proceeds to step S309, and if it is determined that the “opening end condition” is not satisfied (No in step S308), the process proceeds to step S309. The winning game process is terminated.

In step S309, the main CPU 111 performs a special winning opening closing process.
The big prize opening closing process is performed by the first big prize opening / closing solenoid 16c and the second big prize opening solenoid 17c in order to close the open / close door 16b of the first big prize opening 16 and the movable piece 17b of the second big prize opening 17. The energization stop data is set, and with reference to the release mode determination table (see FIG. 10) determined in step S303, the first grand prize winning port 16, the second large size are based on the current number of times of opening (K). The closing time of the winning opening 17 is set in the special game timer counter. As a result, the first big prize opening 16 and the second big prize opening 17 are closed.

In step S310, the main CPU 111 determines whether or not the small hit end condition is satisfied. As a condition for ending a small hit, the number of times of opening (K) becomes the maximum number of times of opening, or the values of the first big winning opening entrance counter (C1) and the second big winning opening entrance counter (C2) are the maximum number ( For example, 9).
If it is determined that the small hit end condition is satisfied (Yes in step S310), the process proceeds to step S311. If it is determined that the small hit end condition is not satisfied (No in step S310), The small hit game process is terminated.

In step S <b> 311, the main CPU 111 sets 0 in the number-of-openings (K) storage area, and also sets 0 in the number-of-stakes (C) storage area. That is, the number-of-openings (K) storage area and the number of balls received in the big prize opening (C) storage area are cleared.
In step S <b> 312, the main CPU 111 sets an ending command corresponding to the small hit type in the effect transmission data storage area in order to transmit to the effect control board 120 according to the stop symbol data.

In step S313, the main CPU 111 sets the ending time corresponding to the small hit type in the special game timer counter according to the stop symbol data.
In step S314, the main CPU 111 determines whether or not the set ending time has elapsed. If it is determined that the ending time has elapsed (Yes in step S314), the main CPU 111 converts the special figure special electricity processing data in step S315. 5 is set and the small hit game processing is terminated.
If it is determined in step S314 that the ending time has not elapsed (No in step S314), the main CPU 111 ends the small hit game process as it is.

<Special game end processing>
FIG. 32 is a flowchart for explaining special game end processing by the main control board.
In step S321, the main CPU 111 loads the stop symbol data set in the stop symbol data storage area and the game information in the game state buffer.
In step S322, the main CPU 111 refers to the jackpot end setting data table shown in FIG. 9, and based on the stop symbol data loaded in step S321 and the game information in the game state buffer, the high probability game flag at the end of the jackpot. Processing for determining whether or not to set a high probability game flag in the storage area is performed. For example, if the stop symbol data is “02”, a high probability flag is set (turned on) in the high probability game flag storage area.

  In step S323, the main CPU 111 refers to the jackpot end setting data table shown in FIG. 9, and based on the stopped symbol data loaded in step S321 and the game information in the game state buffer, the high probability game count (X). A predetermined number of times is set in the storage area. For example, if the stop symbol data is “02”, 10000 times is set in the high probability game number (X) storage area.

  In step S324, the main CPU 111 refers to the jackpot end setting data table shown in FIG. 9 and sets a flag in the short-time game flag storage area based on the stop symbol data loaded in step S321 and the game information in the game state buffer. Whether or not to set is performed. For example, when the stop symbol data is “01”, a flag is set (turned on) in the time-saving game flag storage area (see FIG. 9).

  In step S325, the main CPU 111 refers to the jackpot end setting data table shown in FIG. 9, and based on the stop symbol data loaded in S321 and the game information in the game state buffer, the number of short-time game count (J) storage areas Is set a predetermined number of times. For example, when the stop symbol data is “01”, 10000 is set in the time-saving game count (J) storage area.

In step S326, the main CPU 111 refers to the jackpot end setting data table shown in FIG. Is set a predetermined number of times. Specifically, when the stop symbol data is “11” to “14” and the game state buffer is 00H, 50 is set in the specific period number counter (T).
In step S327, the main CPU 111 confirms the gaming state and sets a gaming state designation command in the effect transmission data storage area.
In step S328, the main CPU 111 sets 0 in the special figure special power processing data, and ends the special game end processing.

<General-purpose power control processing>
FIG. 33 is a flowchart for explaining ordinary power control processing by the main control board.
First, in step S331, the value of ordinary power transmission processing data is loaded, and a branch address is calculated from the loaded ordinary power transmission processing data in step S332.
If the normal map normal power process data = 0 (Yes in step S333), the main CPU 111 performs the normal symbol variation process in step S334, and ends the normal map normal power control process.
If it is not general map power transmission processing data = 0 (No in step S333), it is determined that general power transmission processing data = 1, and in step S335, an ordinary electric utility control process (step S335) is performed. The control process ends.

<Normal symbol variation processing>
FIG. 34 is a flowchart for explaining normal symbol variation processing by the main control board.
In step S341, the main CPU 111 determines whether or not the normal symbol variation display is in progress. If the normal symbol variation display is in progress (Yes in step S341), the process proceeds to step S358. If the normal symbol variation display is not in progress (No in step S341), the process proceeds to step S342.

When it is determined in step S341 that the variable display is not being performed (No in step S341), in step S342, the main CPU 111 determines whether the normal symbol stop display time set in step S361 described later has elapsed. judge.
As a result, if it is determined that the normal symbol stop time has elapsed (Yes in step S342), the process proceeds to step S343, and if it is determined that the normal symbol stop time has not elapsed, The normal symbol variation process is terminated.

  If it is determined in step S342 that the normal symbol stop time has elapsed, in step S343, the main CPU 111 determines that the normal symbol hold count (G) stored in the normal symbol hold count (G) storage area. Is determined to be 1 or more. As a result, when the number of held normal symbols (G) stored in the normal symbol holding number (G) storage area is 1 or more, the process proceeds to step S344, and the number of held (G) is “0”. Since the normal symbol variation display is not performed, the normal symbol variation processing is terminated.

  If it is determined in step S342 that the number of normal symbols held (G) is equal to or greater than “1” (Yes in step S343), the main CPU 111 stores the number of reserved symbols in the special symbol (G) storage area. The new hold number (G) obtained by subtracting “1” from the existing value (G) is stored.

  Next, the main CPU 111 performs a shift process on the data stored in the normal symbol holding storage area. Specifically, each data stored in the first storage unit to the fourth storage unit is shifted to the previous storage unit. At this time, the data stored in the previous storage unit is written into a predetermined processing area and is erased from the normal symbol holding storage area.

  Next, the main CPU 111 determines the hit determination random number value stored in the normal symbol holding storage area. When a plurality of hit determination random number values are stored, the hit determination random number values are read in the stored order.

Specifically, with reference to the hit determination table shown in FIG. 6C, it is determined whether or not the hit determination random number value shifted to the processing area is hit in the above table. For example, according to the above table, one hit determination random number value of “0” out of the hit random numbers “0” to “19” in the non-short-time gaming state is determined to be a hit, For example, among the winning random numbers “0” to “19”, 19 winning determination random numbers “0” to “18” are determined to be winning, and the other random numbers are determined to be lost.
As a result, if it is determined to be a win (Yes in step S347), the process proceeds to step S348. If it is not determined to be a win (No in step S347), the process proceeds to step S352.

  If it is determined in step S347 that the game is a win, the main CPU 111 performs a symbol determination process (step S348). Here, with reference to the normal symbol determination table shown in FIG. 7A, the symbol determination random number value shifted to the processing area is determined to determine either the long open symbol or the short open symbol. Specifically, when the design determination random value shifted to the processing area is “0” or “1”, it is determined as a long open symbol, and when “2” to “10”, a short open symbol is determined. judge.

If the result of the symbol determination process in step S348 is determined to be a long open symbol (Yes in step S349), a long open symbol is set (step S350), and if it is determined to be a short open symbol ( In step S349, No) a short open symbol is set (step S351).
If it is not determined to be a win in step S347 (No in step S347), the main CPU 111 sets a lost symbol in step S352.

  Next, the main CPU 111 sets a general-use fluctuation pattern designation command in the effect transmission data storage area. Note that the normal pattern variation pattern designation command indicates whether the determined normal symbol is a long open symbol, a short open symbol, or a lost symbol, and the command is transmitted to the effect control board 120. Then, the effect related to the normal symbol lottery (ordinary symbol variation effect) is executed on the effect control board 120.

Next, in step S354, the main CPU 111 determines whether or not a flag is turned on in the time-saving game flag storage area.
When the flag is turned on in the short-time game flag storage area, the game state is in the short-time game state, and when the flag is not turned on, the game state is in the non-short-time game state. Is the time.
If it is determined that the short-time game flag is on (Yes in step S354), the process proceeds to step S355, and if it is determined that the short-time game flag is not on (No in step S354), step S356 is performed. Move processing to.

  If it is determined in step S354 that the flag is turned on in the short time game flag storage area, the main CPU 111 sets a counter corresponding to 1 second in the normal symbol time counter (step S355), and the short time game flag. If it is determined that the flag is not turned on in the storage area, a counter corresponding to 10 seconds is set in the normal symbol time counter (step S356). By the process of step S355 or step S356, the time for the normal symbol variation display is determined. The normal symbol time counter is subtracted every 4 ms in step S102.

  Next, the main CPU 111 starts normal symbol variation display on the normal symbol display device 22. The normal symbol variation display is to flash the LED at a predetermined interval in the normal symbol display device 22 and give the player an impression as if it is currently being drawn. This normal symbol variation display is continuously performed for the time set in step S355 or step S356. When this process ends, the normal symbol variation process ends.

If it is determined in step S341 that the variation display is being performed (No in step S341), the main CPU 111 determines in step S348 whether the set variation time has elapsed.
That is, the normal symbol time counter is subtracted every 4 ms, and it is determined whether the set normal symbol time counter is zero. As a result, if it is determined that the set variation time has not elapsed, it is necessary to continue the variation display as it is, so that the normal symbol variation process is terminated and the next subroutine is executed.

If the main CPU 111 determines in step S358 that the set variation time has elapsed (Yes in step S358), the main CPU 111 stops the variation of the normal symbol in the normal symbol display device 22 in step S359.
At this time, the normal symbol (long open symbol, short open symbol or lost symbol) set by the routine processing before that is stopped and displayed on the normal symbol display device 22. As a result, the result of the normal symbol lottery is notified to the player.

Next, the main CPU 111 sets a normal symbol confirmation command in the effect transmission data storage area in step S360 in order to transmit to the effect control board 120 that the normal symbol variation display is stopped and the symbol has been confirmed. Note that the normal symbol determination command can identify which symbol is the symbol that is stopped and displayed.
Next, in step S361, the main CPU 111 sets the time for which the normal symbol display device 22 stops displaying the normal symbol. Here, in order to allow the player to recognize the confirmed symbol, the normal symbol stop time is set to 1 second, and a counter corresponding to 1 second is set in the normal symbol time counter.

  Next, in step S362, the main CPU 111 determines whether or not the set normal symbol is a winning symbol (long open symbol or short open symbol), and the set normal symbol is a winning symbol. In the case (Yes in step S362), in the step S363, the ordinary figure electric power processing data = 1 is set, and the processing is transferred to the ordinary electric accessory control process, and the set ordinary symbol is a lost symbol. (No in step S362), the normal symbol variation process is terminated as it is.

<Normal electric accessory control processing>
FIG. 35 is a flowchart for explaining the ordinary electric accessory control process by the main control board.
This ordinary electric accessory control process is executed when it is determined to be “winning” in step S362 of the ordinary symbol variation process shown in FIG.

  In step S371, the main CPU 111 determines whether the normal symbol stop time set in step 361 (FIG. 34) has elapsed. As a result, when it is determined that the normal symbol stop time has elapsed, the process proceeds to step S372, and when it is determined that the normal symbol stop time has not elapsed (No in step S371), the normal electric accessory. The control process ends.

  If it is determined in step S371 that the normal symbol stop time has elapsed, the main CPU 111 determines in step S372 whether the start port opening / closing solenoid 14c is already in the open control. As a result, when it is determined that the start opening / closing solenoid 14c is under open control (Yes in step S372), the process proceeds to step S382, and when it is determined that the start opening open / close solenoid 14c is not under open control. (No in step S372), the process proceeds to step S373.

If it is determined in step S372 that the start opening / closing solenoid 14c is not under open control, the main CPU 111 determines whether the short-time game flag is on, that is, whether the current game state is the short-time game state. To do.
As a result, when it is determined that the current gaming state is the short-time gaming state (Yes in step S373), the process proceeds to step S378, and when it is determined that the current gaming state is not the short-time gaming state (step S37). No in S373), the process proceeds to step S374.

If it is determined in step S373 that the current gaming state is not the time-saving gaming state, the main CPU 111 stops the normal symbol display device 22 in step S374, that is, step S361 (FIG. 34). It is determined whether the symbol set in step 1 is a long open symbol.
As a result, when it is determined that the stopped display symbol is a long open symbol (Yes in step S374), in step S375, a counter corresponding to 4.2 seconds is set in the public power open time counter.
Further, when it is determined that the symbol stopped and displayed in step S374 is not a long open symbol (short open symbol) (No in step S374), the power open time counter is set to 0.2 seconds in step S377. Set the corresponding counter.

  Next, the main CPU 111 sets a long release start command in the effect transmission data storage area to transmit to the effect control board 120 that the opening of the second start port 14 starts. In the present embodiment, the long open symbol is transmitted to the effect control board 120 at the start of energization of the start opening / closing solenoid 14c only in the non-time-short game state and when the long open symbol is determined. . However, at the start of energization of the start opening / closing solenoid 14c, it may be transmitted to the effect control board 120 so that the type of the normal symbol and the game state can be identified.

  Even when it is determined in step S373 that the current gaming state is the short-time gaming state, the main CPU 111 stops and displays the symbols that are normally displayed on the normal symbol display device 22 in step S378, as in step S374. It is determined whether is a long open symbol.

As a result, when it is determined that the symbol that is stopped and displayed is a long open symbol (Yes in step S378), the main CPU 111 sets a counter corresponding to 5 seconds in the normal power release time counter in step S379. .
Further, when it is determined in step S378 that the symbol that is stopped is not a long open symbol (a short open symbol), the main CPU 111 corresponds to 3 seconds in the utility power open time counter in step S380. Set the counter to be used.

In step S381, the main CPU 111 sets a table for energizing the start port opening / closing solenoid 14c. Specifically, when the process of step S375 is performed, the long release TBL1 illustrated in FIG. 17A is set, and when the process of step S377 is performed, the process is illustrated in FIG. Set short release TBL1. When the process of step S379 is performed, the long release TBL2 shown in FIG. 17B is set, and when the process of step S380 is performed, the short release TBL2 shown in FIG. Set.
Then, energization of the start opening / closing solenoid 14c is started based on the set table. As a result, the second start port 14 is opened and controlled to the second mode.

  In step S382, the main CPU 111 determines whether or not the set public power open time has elapsed. That is, the normal power open time counter is subtracted every 4 ms, and it is determined whether or not the set normal power open time counter = 0. As a result, if it is determined that the utility power open time counter = 0 (Yes in step S382), the process proceeds to step S383, and if it is determined that the utility power open time counter = 0 is not satisfied ( In step S382, No) the ordinary electric accessory control process is terminated.

If it is determined in step S382 that the set normal power release time has elapsed, the main CPU 111 sets start-port solenoid energization stop data in step S383 and stops energization of the start-port opening / closing solenoid 14c. . As a result, the second start port 14 returns to the first mode, and it becomes impossible or difficult to enter the game ball again, and the ordinary game that has been executed ends.
Next, the main CPU 111 sets the ordinary power transmission process data = 0 in step S384, and the ordinary electric accessory control process ends.

  Next, details of various tables stored in the sub ROM 122 will be described with reference to FIGS. 36 and 37.

<Variation production pattern determination table>
36 and 37 are diagrams showing a variation effect pattern determination table for determining the variation pattern of the effect symbol in the first special symbol display device 20, and FIG. 36 shows the special symbol in the first special symbol display device 20. FIG. 37 is a diagram showing an example of a variation effect pattern determination table based on a variation pattern of a special symbol in the second special symbol display device 21. FIG. is there.

The variation effect pattern determination table refers to, for example, one variation effect pattern determination table from among a plurality of variation effect pattern determination tables according to the current gaming state and effect mode. One example will be described.
The effect mode is a mode in which background, BGM, variation effect options, and the like are different, for example, and can be appropriately shifted in order to eliminate the monotony of the game during the game.

The “variation effect pattern” is a specific effect mode in effect means (image display device 31, effect accessory device 32, effect illumination device 33, audio output device 34) performed during the change of the special symbol. Say. For example, in the image display device 31, the variation mode of the effect symbol 35 is determined by the variation effect pattern.
In addition, “reach” in the present embodiment refers to a state in which a part of the combination of effect symbols 35 that informs the transition to the special game is stopped and the other effect symbol images 36 are variably displayed. Say. For example, when the combination of the three-digit effect symbol 35 of “777” is set as the combination of the effect symbols 35 for informing that the game will shift to the jackpot game, the two effect symbols 35 are stopped and displayed at “7”. The state where the remaining effect symbols 35 are displayed in a variable manner.

The variation effect pattern determination tables shown in FIGS. 36 and 37 are configured by associating the variation pattern designation command received from the main control board 110, the effect random number 1 and the variation effect pattern.
The sub CPU 121 acquires the effect random number value 1 and refers to the change effect pattern determination table shown in FIGS. 36 and 37, and uses the change pattern designation command received from the main control board 110 and the acquired effect random number value 1. Based on this, a variation production pattern is determined. Then, an effect pattern designation command corresponding to the determined variation effect pattern is transmitted to the host CPU 151 of the image control board 150.

  In the variation effect pattern determination table shown in FIG. 36, if the variation pattern designation command received from the main control board 110 is “E6H” “01H” and the effect random number 1 is “0” to “49”, the variation effect is determined. Select pattern 1. Then, at the start of the variation of the special symbol, the production pattern designation commands “A1H” and “01H” corresponding to the variation production pattern 1 are generated and transmitted to the image control board 150. The effect content of the variation effect pattern 1 is, for example, a reach A1 effect (winning effect).

  Further, if the variation pattern designation command received from the main control board 110 is “E6H” “01H” and the rendering random number value 1 is “50” to “99”, the variation rendering pattern 2 is selected. At the start of the variation of the special symbol, the production pattern designation commands “A1H” and “02H” corresponding to the variation production pattern 2 are generated and transmitted to the image control board 150. The effect content of the variation effect pattern 2 is, for example, a reach A2 effect (winning effect).

  If the variation pattern designation command received from the main control board 110 is “E6H” “02H” and the random number for rendering 1 is “0” to “49”, the variation rendering pattern 3 is selected and the variation of the special symbol is selected. At the start, production pattern designation commands “A1H” and “03H” corresponding to the variation production pattern 3 are generated and transmitted to the image control board 150. The effect content of the change effect pattern 3 is, for example, a reach B1 effect (winning effect).

  If the variation pattern designation command received from the main control board 110 is “E6H” “02H” and the rendering random number 1 is “50” to “99”, the variation rendering pattern 4 is selected. Then, at the start of the variation of the special symbol, the production pattern designation commands “A1H” and “04H” corresponding to the variation production pattern 2 are generated and transmitted to the image control board 150. The effect content of the variation effect pattern 4 is, for example, a reach B2 effect (winning effect).

When the variation pattern designation command received from the main control board 110 is “E6H” or “03H”, the variation effect pattern 5 is selected regardless of the value “0” to “99” of the effect random number 1. Then, at the start of the variation of the special symbol, the production pattern designation commands “A1H” and “05H” corresponding to the variation production pattern 5 are generated and transmitted to the image control board 150. The effect content of the variation effect pattern 5 is, for example, a design-striking effect.
Similarly, when the variation pattern designation command received from the main control board 110 is “E6H”, “04H” to “E6H”, “06H”, regardless of the value “0” to “99” of the rendering random number value 1, When the variation effect patterns 6 to 8 are selected and the variation of the special symbol is started, the variation pattern designation commands “A1H”, “06H” to “A1H” and “08H” corresponding to the variation patterns 6 to 8 are generated to generate the image control board. 150. The effect contents of the change effect patterns 6 to 8 are, for example, chance effects.

  When the variation pattern designation command received from the main control board 110 is “E6H” or “07H”, the variation effect pattern 9 is selected regardless of the value “0” to “99” of the effect random number 1. Then, at the start of the variation of the special symbol, the production pattern designation commands “A1H” and “09H” corresponding to the variation production pattern 9 are generated and transmitted to the image control board 150. The effect content of the change effect pattern 9 is, for example, a normal change effect.

  If the variation pattern designation command received from the main control board 110 is “E6H” “08H” and the random number for rendering 1 is “0” to “49”, the variation rendering pattern 10 is selected and the variation of the special symbol is selected. At the start, production pattern designation commands “A1H” and “0AH” corresponding to the fluctuation production pattern 10 are generated and transmitted to the image control board 150. The effect content of the change effect pattern 10 is, for example, reach A1 effect (losing).

  If the variation pattern designation command received from the main control board 110 is “E6H” “08H” and the random number for rendering 1 is “50” to “99”, the variation rendering pattern 11 is selected and the variation of the special symbol is selected. At the start, production pattern designation commands “A1H” and “0BH” corresponding to the fluctuation production pattern 11 are generated and transmitted to the image control board 150. The effect content of the change effect pattern 11 is, for example, a reach A2 effect (losing).

  Similarly, if the variation pattern designation command received from the main control board 110 is “E6H” “09H” and the rendering random number 1 is “0” to “49”, the variation rendering pattern 12 is selected, and the rendering disturbance If the numerical value 1 is “50” to “99”, the variation effect pattern 13 is selected. Then, at the start of the variation of the special symbol, the production pattern designation commands “A1H”, “0CH”, “A1H”, and “0DH” corresponding to the variation production patterns 12 and 13 are generated and transmitted to the image control board 150. The production contents of the fluctuation production patterns 12 and 13 are, for example, reach B1 production (losing) and reach B2 production (losing).

  Similarly, when the variation pattern designation command received from the main control board 110 is “E6H” “0AH”, “E6H” “0BH”, regardless of the value “0” to “99” of the production random number value 1, When the variation effect patterns 14 and 15 are selected and the variation of the special symbol is started, the variation pattern designation commands “A1H”, “0EH”, “A1H” and “0FH” corresponding to the variation patterns 14 and 15 are generated to generate the image control board. 150. The contents of the effects of the fluctuation effect patterns 14 and 15 are, for example, a shortened fluctuation A effect and a shortened fluctuation B effect.

  When the variation pattern designation command received from the main control board 110 is “E6H”, “21H” to “E6H”, “2BH”, the variation pattern 1 to 15 is selected by the same selection process as described above, and the variation of the special symbol At the start, variation pattern designation commands “A1H”, “11H” to “A1H”, and “1DH” respectively corresponding to the variation patterns 1 to 15 are generated and transmitted to the image control board 150.

  Note that the variation effect pattern determination table in the second special symbol display device 20 shown in FIG. 37 indicates that the MODE of the variation pattern designation command received from the main control board is “E7H” and the effect pattern transmitted to the image control board. Except that the MODE of the designated command is “B1H”, the description is omitted because it is the same as the variation effect pattern determination table in the first special symbol display device 20 shown in FIG.

  As described above, in the gaming machine according to the present embodiment, even if the variation pattern designation command has the same special symbol, a different variation effect pattern can be determined based on the random number value 1 for the effect. The number of fluctuation pattern designation commands is reduced to reduce the storage capacity of the main control board 110.

  Although illustration is omitted, in addition to the effect pattern specifying command corresponding to the variable effect pattern, the MODE setting value is changed to “effect pattern specifying command corresponding to the customer waiting effect pattern (MODE = 01H). ) ”,“ Effect pattern designation command corresponding to the hit start effect pattern (MODE = 0H) ”,“ effect pattern designation command corresponding to the big hit effect pattern (MODE = 03H) ”,“ effect pattern corresponding to the hit end effect pattern Various effect pattern designation commands such as “designation command (MODE = 04H)” are transmitted to the image control board 150.

  Next, processing executed by the sub CPU 121 in the effect control board 120 will be described.

<Main process of production control board>
FIG. 38 is a flowchart for explaining the main processing by the effect control board.
In step S510, the sub CPU 121 performs an initialization process. In this process, the sub CPU 121 reads a main processing program from the sub ROM 122 and initializes and sets a flag stored in the sub RAM 123 in response to power-on. If this process ends, the process moves to a step S520.

  In step S520, the sub CPU 121 performs an effect random value update process. In this processing, the sub CPU 121 performs processing for updating various random numbers stored in the sub RAM 123. Thereafter, the process of step S510 is repeated until a predetermined interrupt process is performed.

<Timer interrupt processing of production control board>
FIG. 39 is a flowchart for explaining timer interrupt processing by the effect control board.
Although not shown in the figure, a clock pulse is generated every predetermined period (2 milliseconds) by a reset clock pulse generation circuit provided on the effect control board 120, and a timer interrupt processing program is read to display the effect control board 120. Timer interrupt processing is executed.

First, in step S601, the sub CPU 121 saves information stored in the register of the sub CPU 121 to the stack area.
In step S <b> 602, the sub CPU 121 performs update processing of various timer counters used in the effect control board 120.
In step S603, the sub CPU 121 performs command analysis processing. In this process, the sub CPU 121 performs a process of analyzing a command stored in the reception buffer of the sub RAM 123. Specific description of the command analysis processing will be described later with reference to FIGS. 40 and 41. When the effect control board 120 receives a command transmitted from the main control board 110, a command reception interrupt process of the effect control board 120 (not shown) occurs, and the received command is stored in the reception buffer. Thereafter, the received command is analyzed in step S603.

  In step S <b> 604, the sub CPU 121 checks the signal of the effect button detection switch 8 a input via the lamp control board 140 and performs effect input control processing related to the effect button 8. A specific description of the effect input control process will be described later with reference to FIG.

In step S <b> 605, the sub CPU 121 transmits various data set in the transmission buffer of the sub RAM 123 to the image performance control board 150 and the lamp control board 140.
In step S606, the sub CPU 121 restores the information saved in step S601 to the register of the sub CPU 121.

<Command analysis processing>
40 and 41 are flowcharts for explaining command analysis processing by the effect control board. The command analysis process 2 shown in FIG. 41 is performed subsequent to the command analysis process 1 shown in FIG.
In step S611, the sub CPU 121 confirms whether or not the command is received in the reception buffer, and confirms whether the command is received.
If there is no command in the reception buffer (No in step S611), the sub CPU 121 ends the command analysis process. If there is a command in the reception buffer (Yes in step S611), the sub CPU 121 moves the process to step S621.

In step S621, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a customer waiting command. The customer waiting command is set in step S217 (FIG. 26) of the main control board 110.
If the command stored in the reception buffer is a customer waiting command (Yes in step S621), the sub CPU 121 moves the process to step S622, and if it is not a customer waiting command (No in step S621), the sub CPU 121 proceeds to step S631. Move.
In step S622, the sub CPU 121 performs a customer waiting effect pattern determination process for determining a customer waiting effect pattern. Specifically, the customer waiting effect pattern is determined, the determined customer waiting effect pattern is set in the effect pattern storage area, and information on the determined customer waiting effect pattern is transmitted to the image performance control board 150 and the lamp control board 140. Therefore, the data based on the determined customer waiting effect pattern is set in the transmission buffer of the sub RAM 123.
Thereby, the customer waiting effect is started by the image control board 150.

In step S631, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a start winning designation command. The start winning designation command is set in step S154, step S156 or step S157 (FIG. 23) of the main control board 110.
If the command stored in the reception buffer is a start winning designation command (Yes in step S631), the sub CPU 121 moves the process to step S632, and if it is not a starting winning designation command (No in step S631), proceeds to step S641. Move processing.

  In step S632, the sub CPU 121 analyzes the received start winning designation command and executes data update processing corresponding to the starting winning designation command. The start winning designation command is associated with information related to the big hit, the small hit, and the loss that are provisionally determined by the preliminary determination process. Therefore, here, information about the first hold (U1) or the second hold (U2) newly reserved is stored in a predetermined storage area of the sub-RAM 123.

  In step S633, the sub CPU 121 analyzes the start winning designation command and performs a hold display mode determination process for transmitting a hold display command to the image performance control board 150 and the lamp control board 140 so as to perform the hold display in a predetermined mode. As a result, the current reserved number of the first hold (U1) and the second hold (U2) is displayed on the image display device 31.

In step S641, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a variation pattern designation command. The variation pattern designation command is set in step S209 (FIG. 26) of the main control board 110.
If the command stored in the reception buffer is a variation pattern designation command (Yes in step S641), the sub CPU 121 moves the process to step S642, and if it is not a variation pattern designation command (No in step S641), step S651. Move processing to.

  In step S642, based on the received variation pattern designation command, the sub CPU 121 performs variation effect pattern determination processing for determining one variation effect pattern from among a plurality of variation effect patterns. This variation effect pattern determination process will be described later with reference to FIG.

  In step S643, the sub CPU 121 shifts the hold display data stored in the first hold storage area and the second hold storage area and the data corresponding to the start winning designation command, and information on the hold display data after the shift. Is transmitted to the image performance control board 150 and the lamp control board 140.

In step S651, the sub CPU 121 confirms whether or not the command stored in the reception buffer is an effect designating command. The effect designating command is set in step S227, step S231, and step S232 (FIG. 27) of the main control board 110.
If the command stored in the reception buffer is an effect symbol designation command (Yes in step S651), the sub CPU 121 moves the process to step S652, and if it is not an effect symbol designation command (No in step S651), step S661. Move processing to.

  In step S652, the sub CPU 121 performs an effect symbol determination process for determining an effect symbol 35 to be stopped and displayed on the image display device 31, based on the content of the received effect symbol designation command. Specifically, the effect designating command is analyzed, the effect symbol data constituting the combination of the effect symbols 35 is determined according to the presence / absence of jackpot and the type of jackpot, and the determined effect symbol data is stored in the effect symbol storage area Set to.

In step S661, the sub CPU 121 checks whether or not the command stored in the reception buffer is a symbol determination command. The symbol confirmation command is set in step S243 (FIG. 28) of the main control board 110.
If the command stored in the reception buffer is a symbol confirmation command (Yes in step S661), the sub CPU 121 moves the process to step S662, and if it is not a symbol confirmation command (No in step S661), the sub CPU 121 proceeds to step S671. Move.

  In step S 662, the sub CPU 121 transmits data based on the effect symbol data determined in step S 652 and stop instruction data for stopping and displaying the effect symbol to stop display of the effect symbol 35. The effect design stop process to be set is performed.

In step S671, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a common map variation pattern designation command. It should be noted that the common map change pattern designation command is set in step S353 (FIG. 34) of the main control board 110.
If the command stored in the reception buffer is a common map variation pattern designation command (Yes in step S71), the sub CPU 121 moves the process to step S672, and if it is not a common diagram variation pattern designation command (No in step S671). ), The process proceeds to step S681.

  In step S <b> 672, the sub CPU 121 performs a general variation variation effect pattern determination process for determining one general variation variation effect pattern from a plurality of ordinary variation variation patterns based on the received normal variation variation designation command.

In step S681, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a long release start command. The long release start command is set in step S376 (FIG. 35) of the main control board 110.
If the command stored in the reception buffer is a long release start command (Yes in step S681), the sub CPU 121 moves the process to step S682, and if it is not a long release start command (No in step S681), step S700. Move processing to.

  In step S682, the sub CPU 121 performs a long open effect process. Here, a notification effect is executed in order to notify the player that the second start port 14 is opened for a long time (4.2 seconds) in the non-short-time gaming state.

In step S691, the sub CPU 121 checks whether or not the command stored in the reception buffer is a normal symbol determination command. The normal symbol confirmation command is set in step S360 (FIG. 34) of the main control board 110.
If the command stored in the reception buffer is a normal symbol determination command (Yes in step S691), the sub CPU 121 moves the process to step S692, and if it is not a normal symbol determination command (No in step S691), step S700. Move processing to.

  In step S 692, the sub CPU 121 displays effect symbol data corresponding to the received normal symbol confirmation command and stop instruction data for stopping and displaying the general symbol effect symbol in the sub RAM 123 in order to stop and display the normal symbol effect symbol. Normal symbol variation stop processing to be set in the transmission buffer is performed.

In step S700, the sub CPU 121 determines whether or not the command stored in the reception buffer is a gaming state designation command. The game state designation command is set in step S258 (FIG. 29) and step S32 (FIG. 32) of the main control board 110.
If the command stored in the reception buffer is a gaming state designation command (Yes in step S700), the sub CPU 121 moves the process to step S701, and if it is not a gaming state designation command (No in step S700), step S711. Move processing to.

In step S <b> 701, the sub CPU 121 sets a gaming state based on the received gaming state designation command in a gaming state storage area in the sub RAM 123.
In step S711, the sub CPU 121 confirms whether or not the command stored in the reception buffer is an opening command. The opening command is set in step S265 (FIG. 29) of the main control board 110.
If the command stored in the reception buffer is an opening command (Yes in step S711), the sub CPU 121 moves the process to step S712, and if not a opening command (No in step S711), moves the process to step S721. .

  In step S712, the sub CPU 121 performs a hit start effect pattern determination process for determining a hit start effect pattern. Specifically, the hit start effect pattern is determined based on the opening command, the determined hit start effect pattern is set in the effect pattern storage area, and information on the determined hit start effect pattern is displayed on the image performance control board 150 and the lamp. In order to transmit to the control board 140, data based on the determined hit start effect pattern is set in the transmission buffer of the sub RAM 123.

In step S721, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a special winning opening opening designation command. The special winning opening opening designation command is set in step S275 (FIG. 30) of the main control board 110.
If the command stored in the reception buffer is a big winning opening release designation command (Yes in step S721), the sub CPU 121 moves the process to step S722, and if it is not a big winning opening opening designation command (No in step S721). ), And the process proceeds to step S731.

  In step S722, the sub CPU 121 performs a mid-round effect pattern determination process for determining a jackpot effect pattern. Specifically, the in-round effect pattern is determined for each round to be started, based on a special winning opening release designation command having information on how many round games start. Then, the determined effect pattern during the round is set in the effect pattern storage area, and information on the effect pattern is transmitted to the image performance control board 150 and the lamp control board 140, so that the corresponding data is set in the transmission buffer of the sub RAM 123. To do.

In step S731, the sub CPU 121 confirms whether or not the command stored in the reception buffer is a round end designation command. The round end designation command is set in step S284 (FIG. 30) of the main control board 110.
If the command stored in the reception buffer is a round end designation command (Yes in step S731), the sub CPU 121 moves the process to step S732, and if the command is not a round end designation command (No in step S731), step S741. Move processing to.

In step S732, the sub CPU 121 performs a pause effect pattern determination process for determining an effect pattern between rounds.
In step S741, the sub CPU 121 confirms whether or not the command stored in the reception buffer is an ending command. The ending command is set in step S287 (FIG. 30) and step S312 (FIG. 31) of the main control board 110.
If the command stored in the reception buffer is an ending command (Yes in step S741), the sub CPU 121 moves the process to step S742, and if not a ending command (No in step S741), ends the command analysis process. .

  In step S742, the sub CPU 121 performs a hit end effect pattern determination process for determining a hit end effect pattern. Specifically, the winning end effect pattern is determined based on the ending command, the determined hit end effect pattern is set in the effect pattern storage area, and information on the determined hit end effect pattern is displayed on the image performance control board 150 and the lamp. In order to transmit to the control board 140, data based on the determined hit end effect pattern is set in the transmission buffer of the sub RAM 123.

<Variation effect pattern determination processing>
FIG. 42 is a flowchart for explaining the changing effect pattern determination process by the effect control board.
The variation effect pattern determination process shown in FIG. 42 is executed by the sub CPU 121 when the variation pattern designation command transmitted from the main control board 110 is stored in the reception buffer of the effect control board 120. This variation effect pattern determination process determines a variation effect pattern indicating how to control various effect devices including the image display device 31 during the special symbol variation display.
First, in step S801, the sub CPU 121 acquires the effect random number value updated in step S520.
Next, in step S802, the sub CPU 121 sets a variation effect pattern determination table with reference to the current gaming state and effect mode.

Next, in step S803, the sub CPU 121 determines one variation effect pattern based on the variation effect pattern determination table set in step S802 and the effect random number obtained in step S801.
In addition, the presence / absence of execution of the notice effect and the type of the notice effect when executed may be determined using the notice effect determination table.
Next, in step S804, the sub CPU 121 sends an effect pattern designation command to transmit to the image control board 150 and the lamp control board 140 the variation effect pattern (and the presence / absence and type of the notice effect) determined in step S803. Set in the transmission data storage area. When the effect pattern designation command is transmitted to the image control board 150 and the lamp control board 140, the image display device 31, the effect accessory device 32, the effect illumination device 33, and the audio output device based on the effect pattern designation command. 34 is controlled.

Next, in step S805, the sub CPU 121 sets an effect time timer so as to time the elapsed time since the start of the change effect. For example, when the variation effect pattern related to reach A is determined, a counter corresponding to 60 seconds is set.
Next, in step S806, the sub CPU 121 sets a symbol determination period, which is a period during which the effect symbol 35 is stopped and displayed on the image display device 31. The symbol determination period is from 3 seconds before the end of the variation effect until the end of the variation effect.

<Production input control processing>
FIG. 43 is a flowchart for explaining the effect input control process by the effect control board.
First, in step S811, the sub CPU 121 determines whether or not there is a valid effect button detection signal from the effect button detection switch 8a based on the effect button detection command from the lamp control board 1140. If the sub CPU 121 determines that there is no effect button detection signal (No in step S811), the sub CPU 121 ends the process, and if it determines that there is an effect button detection signal (Yes in step S811), the process proceeds to step S812. Transition to processing.

  In step S812, the sub CPU 121 determines whether or not the button operation effect executable flag = 01 is set in the storage area of the sub RAM 123. Here, if the button operation effect executable flag = 01 is not set (No in step S812), the sub CPU 121 ends the process, and if the button operation effect executable flag = 01 is set (step S812). Yes in S812), the process proceeds to step S813.

  The button operation effect executable flag is used to determine whether or not an effect corresponding to the operation can be executed based on the button operation being performed. ”Indicates that an effect corresponding to the operation can be executed, and a flag“ 00 ”indicates that an effect corresponding to the operation cannot be executed. The flag “01” is set in accordance with the start, and the effect button is operated, or the flag “00” is set when the operation effective period ends without the effect button being operated.

In step S813, the sub CPU 121 sets a button operation effect execution command in the transmission buffer. This command is a command for causing the image control board 150 to execute an effect corresponding to the operation of the effect button 8.
Here, the sub CPU 121 transmits the command set in the transmission buffer in step S605 (see FIG. 39) after the effect input control process to the image control board 150 and the lamp control board 140. The image control board 150 operates the image display device 31 and the audio output device 32 based on the received command, and the lamp control board 140 operates the effect accessory device 32 and the effect lighting device 33 based on the received command. Let

Next, the image control board 150 will be described.
In the image control board 150, when receiving the production command from the production control board 120, the host CPU 151 reads out the audio output device control program from the host ROM 153 based on the received production command, and the audio output device 342 performs the audio. And the host CPU 151 reads an animation control program from the host ROM 153 to control image display on the image display device 31.

  Here, processing executed by the host CPU 151 in the image control board 150 will be described.

<Host CPU main processing>
FIG. 44 is a flowchart for explaining main processing by the image control board.
When power is supplied from the power supply board 170, a system reset occurs in the host CPU 151, and the host CPU 151 performs the following main processing.

  First, in step S901, the host CPU 151 performs an initialization process. In this processing, the host CPU 151 reads the main processing program from the host ROM 153 and instructs the initial setting of the various modules of the host CPU 151 and the VDP 200 in response to power-on.

In step S <b> 902, the host CPU 151 performs effect pattern designation command analysis processing for analyzing the effect pattern designation command (command stored in the reception buffer of the host RAM 152) transmitted from the effect control board 120.
When the image control board 150 receives a command transmitted from the effect control board 120, a command reception interrupt process of the image control board 150 (not shown) occurs, and the received command is stored in the reception buffer. Thereafter, the received command is analyzed in step S902.

The effect pattern designation command analysis process confirms whether or not an effect pattern designation command is stored in the reception buffer. If the effect pattern designation command is not stored in the reception buffer, the process proceeds to step S903 as it is.
If a production pattern designation command is stored in the reception buffer, a new production pattern designation command is read, and one or more animation groups to be executed are determined based on the read production pattern designation command, and each animation An animation pattern is determined from the group (see FIG. 47). When the animation pattern is determined, the read effect pattern designation command is deleted from the transmission buffer.

In step S903, the host CPU 151 performs animation control processing. In this process, the addresses of various animation scenes are updated based on the “scene switching counter”, “weight frame”, “frame counter” updated in step S921, which will be described later, and the animation pattern determined in step S902. To do.
In step S904, the host CPU 151 determines the display list from the display information (sprite identification number, display position, etc.) of the animation scene at the updated address according to the priority order (drawing order) of the animation group to which the animation scene belongs. Are generated (see FIG. 47). When the generation of the display list is completed, the host CPU 151 outputs the display list to the VDP 200. The display list output here will be described later with reference to FIG.
The display list output here is stored in the display list storage area 156a of the VRAM 156 via the CPU I / F 203 in the VDP 200.

In step S905, the host CPU 151 determines whether or not the FB switching flag = 01.
Here, as will be described later with reference to FIG. 45B, the FB switching flag is set to FB if the previous display list has been drawn in a V blank interrupt every 1/60 seconds (about 16.6 ms). Switching flag = 01. That is, in step S905, it is determined whether or not the previous drawing has been completed.
If the FB switching flag = 01 (Yes in step S905), the host CPU 151 proceeds to step S906, and if the FB switching flag = 00 (No in step S905), the host CPU 151 waits until the FB switching flag = 01. do.

In step S906, the host CPU 151 sets the FB switching flag = 00 (turns the FB switching flag off), and proceeds to step S906.
In step S907, the host CPU 151 performs drawing execution start processing.
In this process, in order to instruct the VDP 200 to execute drawing on the display list that has already been output, drawing execution start data is set in the drawing register. That is, execution of drawing for the display list output in S904 is instructed.
Thereafter, the processing from step S902 to step S907 is repeated until a predetermined interrupt shown in FIG. 45 occurs.

<Image control board interrupt processing>
The interrupt process of the image control board 150 will be described with reference to FIG.
The interrupt process of the image control board 150 includes at least a drawing end interrupt process performed by inputting a drawing end interrupt signal and a V blank interrupt process performed by inputting a V blank interrupt signal. Yes.

<Host CPU drawing end interrupt processing>
FIG. 45A is a flowchart for explaining a drawing end interrupt process by the image control board.
When drawing of a predetermined unit frame (one frame) is completed, the VDP 200 outputs a drawing end interrupt signal to the host CPU 151 via the CPU I / F 203.
When the host CPU 151 receives a drawing end interrupt signal from the VDP 200, the host CPU 151 executes a drawing end interrupt process.
In the drawing end interrupt process, in step S911, the host CPU 151 sets the drawing end flag = 01 (turns on the drawing end flag), and ends the current drawing end interrupt process. That is, the drawing end flag is turned on every time drawing ends.

<Host CPUV blank interrupt processing>
FIG. 45B is a flowchart for explaining the V blank interrupt processing by the image control board.
The VDP 200 outputs a V blank interrupt signal (vertical synchronization signal) to the host CPU 151 via the CPU I / F 203 every 1/60 seconds (about 16.6 ms).
When the host CPU 151 receives a V blank interrupt signal from the VDP 200, the host CPU 151 executes a V blank interrupt process.

In step S921, the host CPU 151 performs processing for updating various counters such as “scene switching counter”, “wait frame”, and “frame counter”.
In step S922, the host CPU 151 determines whether or not the drawing end flag is “01”. That is, it is determined whether or not drawing of a predetermined unit frame has been completed.
If the drawing end flag = 01 (Yes in step S922), the host CPU 151 moves the process to step S923. If the drawing end flag = 01 (No in step S922), the host CPU 151 ends the current V blank interrupt process. To do. That is, even if the V blank interrupt signal is input, if the drawing is not completed, the processing after step S923 is not performed.

In step S923, the host CPU 151 sets a drawing end flag = 00 (turns the drawing end flag off).
In step S924, the host CPU 151 instructs the memory controller 209 of the VDP 200 to switch between “display frame buffer” and “drawing frame buffer”.
In step S925, the host CPU 151 sets the FB switching flag = 01 (turns on the FB switching flag), cancels the standby state in step S905 (see FIG. 44), and ends the current V blank interrupt processing. To do.

  Next, with reference to FIGS. 46 and 47, an animation pattern determination method and a display list generation method will be described.

<Anime pattern>
FIG. 46 is an example of an animation pattern for displaying an animation of a production pattern.
As shown in FIG. 46A, the animation pattern is grouped for each object or scene displayed on the image display device 31, and displays a background group for displaying the background animation and an animation of the character used for the notice A. Notice group A for displaying, animation group B for displaying the animation of the character used for the notice B, reach group for displaying the animation of the reach character, effect symbol group for displaying the animation of the effect symbol 35, jackpot There are a large number of groups such as a jackpot directing group for displaying the animation of the directing. A large number of animation patterns are associated with each group and stored in the host ROM 153.
Based on the effect pattern designation command received from the sub CPU 121, the host CPU 151 determines one or a plurality of animation groups to be executed and also determines an animation pattern from each animation group.

  46 (b) to 46 (e) show the animation pattern determined when the variation pattern designation command (E6H07H) corresponding to the variation pattern 7 (the special symbol variation pattern 7 of 10 seconds) shown in FIG. 13 is received. An example is shown.

  When the host CPU 151 receives the effect pattern specification command (A1H09H) corresponding to the change pattern specification command (E6H07H) of the change pattern 7, the host CPU 151 causes the background CPU, the notice A group, the notice B group, and the effect symbol group 4 to be displayed. One group is determined, and the anime pattern 1 is determined from the background group, the anime pattern 11 is determined from the notice A group, the anime pattern 21 is determined from the notice B group, and the anime pattern 501 is determined from the effect pattern group.

Here, as shown in FIGS. 46B to 46E, the animation pattern stores a combination of animation scene information, a display order of each animation scene information, and the like.
For example, in the effect symbol group / animation pattern 501 shown in FIG. 46E, the animation scene 501 is executed first and the animation scene 511 is executed second.
The host RAM 151 has a “scene switching counter” that is updated every frame. If the scene switching counter measures “540” while the first animation scene 501 is being executed, the second animation is displayed. The animation scene switches to the scene 511. When the scene switching counter measures “60” while the second animation scene 511 is being executed, the animation scene of the production symbol group / animation pattern 501 ends.
Note that “one frame” is the update timing of the image display device (vertical synchronization signal update timing), and one frame is updated every 1/60 seconds (about 16.6 ms). That is, 60 frames are measured in 1 second.

Each animation scene stores animation scene information, and wait frames (that is, display time) updated every frame, target data (sprite identification number, transfer source address, etc.), parameters (sprite Display information such as a display position, a transfer destination address, and a drawing method.
For example, in the animation display, in the animation scene 501 shown in FIG. 46 (e), the first design to the fourth design are continuously displayed up to 20 frames (about 0.33 seconds) at predetermined coordinates. Thereafter, the first symbol to the fourth symbol are continuously displayed at different coordinates for 15 frames (about 0.25 seconds). Similarly, when the first symbol to the fourth symbol are continuously displayed at different coordinates up to a predetermined frame, an animation is displayed in which the first symbol to the fourth symbol is moved and displayed. be able to.

46 (b)-(e), the background group anime pattern 1, the anime pattern 11 from the notice A group, the anime pattern 21 from the notice B group, and the animation from the effect design group. A plurality of animation patterns with the pattern 501 are determined, and the animations of these animation patterns are executed in parallel.
That is, in the display area of the image display device 31, images of BG1 and BG2 continue to be displayed as the background from the start to the end of the animation pattern, and the notice of the character A is displayed 2 seconds (120 frames) after the start of the animation pattern. An image for display animation is displayed for 3 seconds (180 frames), and after 3 seconds (180 frames) from the start of the animation pattern, an image for animation display of character B is displayed for 4 seconds (240 frames). Furthermore, an image for performing animation for normal variation display of effect symbols is performed for 9 seconds (540 frames), and then an image for performing animation for temporary stop display for 1 second (60 frames) is displayed.
Note that these images are displayed in an overlapping manner in the display area of the image display device 31, and the first drawn image is overwritten and erased by the image drawn later. This image generation method will be described in the display list described later.

<Display list>
FIG. 47 is a diagram showing an example of a display list including drawing control command groups.
When the host CPU 151 determines the animation pattern as shown in FIG. 46, the host CPU 151 generates a display list for each predetermined frame (one frame), and outputs the generated display list to the VDP 200.
Here, regarding the display list generation method, the host CPU 151 follows the contents of the animation scene at the current number of frames based on the “frame counter” indicating the current frame and the determined animation pattern (animation scene). By generating the drawing control commands according to the priority order (drawing order) of each animation group, a display list for the current number of frames is generated.

For example, as the priority order of the animation group shown in FIGS. 46B to 46E, the background group is associated with the lowest priority 10 data, and the notice A group is associated with the priority 9 data. The priority B data is associated with the notice B group, the priority 2 data is associated with the jackpot effect group, and the highest priority 1 data is associated with the effect symbol group. Shall.
46 (b) to 46 (e), the background group anime pattern 1, the anime pattern 11 from the notice A group, the anime pattern 21 from the notice B group, and the effect design group It is assumed that a plurality of anime patterns with the anime pattern 501 are determined.

Next, drawing control commands were sequentially generated and determined from the animation pattern 1 of the lowest priority animation group (background group) according to the contents of the animation scene in the current frame counter (current number of frames). When the drawing control commands up to the highest priority animation group (production symbol group) among the animation groups are generated, a drawing end command is finally generated to complete the display list as shown in FIG.
Such a display list is generated by program processing while referring to data necessary for the host CPU 151.

  As described above, when the host CPU 151 outputs a display list in which drawing control command groups are grouped in predetermined frames (every frame) to the VDP 200, the drawing circuit 207 in the VDP 200 performs specific drawing processing. The processing load on the host CPU 151 can be reduced.

Next, an outline of the lamp control board 140 will be briefly described.
When the lamp control board 140 receives an effect command from the effect control board 120, it reads out the effect accessory device operation program based on the received effect command and controls the operation of the effect accessory device 32. At the same time, an effect lighting device control program is read based on the received effect command, and the effect lighting device 33 is controlled.
When the lamp control board 140 receives the command for the effect button from the image control board 130 via the effect control board 120, the effect button operation program is read based on the received command for the effect button, and the effect button 8 is controlled.

<Configuration of voice control circuit>
FIG. 48 is a diagram showing a configuration of a sound control circuit according to the present embodiment.
The sound control circuit 300 shown in FIG. 48 includes a sound source ROM 400 in which various sound data (effect sound, system sound) are stored as compressed data, and various control commands related to sound output, such as effect sound output command and error sound output. It is connected to the host CPU 151 and the like of the image control circuit 150 for inputting commands to the sound control circuit 300.

The host CPU 151 included in the image control board 150 outputs an effect sound output command including sound necessary for the change effect based on the change effect pattern specified by the effect pattern specification command input from the sub CPU 121 to the sound control circuit 300 (sound Input to the control unit 301).
Further, the host CPU 151 sends an error sound output command to the voice control circuit based on various switch detection information (door opening information, dish full information, ball clogging information, illegal radio wave detection information) transmitted from the main control board 110. 300 (voice control unit 301).
The sound control circuit 300 performs processing on sound data stored in the sound source ROM 400 in accordance with a control command input from the host CPU 151, and performs processing of inputting to at least one sound output device (speaker) 34 and outputting as sound. .

  The audio control circuit 300 includes a plurality of (for example, 40) audio channels (ch0 to ch39) each including a decoding unit 310 and a channel volume control unit 311, and audio data and volume corresponding to a control command input from the host CPU 151. An audio control unit 301 that inputs control commands (decoding unit control command, volume control command) to the audio channel, a mixer 302 that mixes and outputs audio signals output from each of the audio channels 0ch to 39ch, and a mixer 302 An audio signal processing unit 303 that performs predetermined audio processing (equalization, effect processing, panning, looping, etc.) on the signal output from the signal, an operational amplifier 304 as an amplification device, and an audio signal that is a digital signal as an analog signal Convert audio output device (speaker A D / A converter unit 305 to be output to 34, and a.

In the sound source ROM 400, a plurality of (eg, 4096 types) audio data (phrase data) including system sounds such as background sounds (BGM) used in gaming machines, effect sounds for sound effects, and error sounds are compressed digitally. Stored as data.
As a method for compressing audio data, for example, a modified discrete cosine transform or the like can be used.

Among a plurality of audio channels (for example, 0ch to 39ch) provided in the audio control circuit, for example, 6 audio channels of 0ch to 5ch are reserved for system sounds (error sounds) and can be used for effect sounds. I can't.
The audio control unit 301 selects a free audio channel from the remaining 6ch to 39ch audio channels, and uses it to reproduce audio data instructed by the host CPU 151.

When an error such as opening of a door occurs in a gaming machine, the volume of all effect sounds is reduced or stopped, and an error sound as a system sound is preferentially generated.
By clearly distinguishing the plurality of audio channels included in the audio control circuit 300 for system sound and effect sound as described above, it is not necessary to consider which sound channel is outputting the effect sound. Since it suffices to perform control to reduce the volume of the audio channel that can be used for sound or to stop the output, the processing can be simplified and the audio channel can be used efficiently.

The audio channel will be described in detail.
The decoding units 310-0 to 310 to 39 included in each of the audio channels 0ch to 39ch read (compressed) audio data from the sound source ROM 400 in accordance with the decoding unit control command input from the audio control unit 301 and perform decoding processing.
The channel volume control unit 311 included in each of the audio channels 0ch to 39ch, based on the volume control command input from the audio control unit 301, the output volume for the expanded audio data input from the decoding unit 310, and (specified Control fade-in / fade-out, etc.)
Fade-in designates the values of the initial volume and the target volume and the time from the initial volume to the target volume to the channel volume control unit 311.
In the fade-out, the start timing and the target volume are designated to the channel volume control unit 311.

The host CPU 151 and the audio control unit 301 regularly acquire information from the audio channels 0ch to 39ch, and always grasp the processing status in these audio channels.
More specifically, the host CPU 151 and the audio control unit 301 periodically acquire and hold status information of the decoding unit 310 and the channel volume control unit 311 included in each audio channel.
Since the host CPU 151 designates the audio channel to the audio control unit 301 and outputs the audio, which audio channel outputs which effect sound and system sound, the volume of each audio channel, the remaining playback time, Naturally knows the status of fade-in and fade-out.

The status information of the decoding unit 310 in each audio channel includes, for example, “playback status”, “priority”, and “sound number”.
“Reproduction status” is information indicating whether or not audio is being reproduced on the audio channel, and includes “reproducing” or “standby”.

The “priority” is the priority of audio reproduced on the audio channel, and is set in advance as “high”, “medium”, and “low” in an audio management table (FIG. 52) described later. .
Basically, the priority of background sounds with little information suggesting a game result or game state is low for the player, and the priority of operation sound of the effect button, notice effect sound, sound effect, etc. is set high.

The “sound number” is a number for specifying the sound reproduced / reproduced in each audio channel.
In an audio management table (FIG. 52), which will be described later, each audio data is managed in association with this “sound number”, and the host CPU 151 instructs the audio control unit 301 to specify the audio number to be reproduced. . As a result, the sound to be reproduced from the sound source ROM 400 is also identified by the “sound number” from the sound control unit 301 to the decoding unit 310 of each sound channel.

The status information of the channel volume control unit 311 for each audio channel includes, for example, “volume” and “fade status”.
“Volume” is the volume of the audio currently being played on the audio channel (eg, a percentage of the maximum volume (master volume)).
In addition, the “fade status” indicates whether or not fade-in (FI) / fade-out (FO) is set for the audio currently being played back on the audio channel, and whether or not these are completed. Contains information.

For example, “fade timer 5” indicates that the FI / FO performed using 5 seconds is incomplete.
“Fade timer 0” indicates that FI / FO is not designated or has been completed.

The status information of all audio channels 0ch to 39ch includes information on “reproduction status”, “priority”, “sound number”, “volume”, and “fade status” for each audio channel.
The status information of all audio channels is as shown below, for example.

Audio channel ch6: Standby audio channel ch7: Playing, priority “high”, note number 11, current volume 90%, fade timer 0
Audio channel ch8: During playback, priority “high”, note number 11, current volume 90%, fade timer 0
Audio channel ch9: During playback, priority “low”, note number 33, current volume 70%, fade timer 0
Audio channel ch10: During playback, priority “medium”, note number 72, current volume 80%, fade timer 0
...
Audio channel ch39: Waiting

[Host CPU]
In the following, the audio control process performed by the image control board provided in the gaming machine of the present embodiment using the audio control circuit will be described in detail.

FIG. 49 is a flowchart for explaining sound control processing by the image control board.
The image control board 150 performs not only audio output processing but also processing of image data to be output to the image display device 31. Here, the audio control processing for outputting the production sound and the system sound to the audio output device 34 will be particularly described. .
The processing shown in FIG. 49 is main processing (related to audio processing) by the host CPU 151 provided in the image control board 150, and is control processing for the audio control circuit 300.

First, the host CPU 151 performs a master volume setting process in step S1001.
This master volume setting process is a process for setting the master volume value of the gaming machine in accordance with the operation of the volume switching SW 280 or the cross key 40 (left / right key) by the player or game shop staff.

Here, the volume setting process in the gaming machine will be outlined.
In the pachinko machine 1 of the present embodiment, the initial value of the “master volume value” is set by the volume switching SW 280. This is basically an operation that can be performed only by game shop staff, and the volume switching SW 280 is often installed at a position where the player cannot operate, such as the back of the gaming machine. The volume switching SW 280 is often configured by a dip switch.
Further, the player adjusts (changes) the “master volume value” from the set initial value by using the left key and the right key of the cross key 40 (FIG. 2) according to his / her convenience and preference. I can do it. This operation can be performed when the gaming machine is in a waiting state for customers.

The master volume adjustment operation using the cross key 40 may be performed while the special symbol is changing.
However, the adjustment work cannot be performed within 15 frames of the fluctuation start and when the fluctuation is stopped (when the symbol confirmation command is received).

The “master volume value” is a comprehensive volume setting value given to all of the plurality of audio channels included in the audio control circuit 300. In the audio control circuit 300 according to the present embodiment, the “master volume value” is included in each audio channel. The above-described channel volume control unit 311 can be given a sub-volume value with volume adjustment for the master volume value (a different volume value is input only for a specific audio channel).
Therefore, it is possible to adjust the relative volume difference (volume ratio) between the respective audio channels, and to emphasize and emphasize important sounds with a louder sound than other sounds.

  The “master volume value” can be switched from “1” to “10” step by step using the volume switching SW 280 or the left and right keys. Depending on the volume switching SW 280 (FIG. 4), “high”, Four levels of volume, “medium”, “small”, and “eco” can be set as the initial master volume value.

When the volume switching SW 280 is switched to “high”, the master volume value is “10”, and when switched to “medium”, the master volume value is “7”, “small”, and “eco”. Is set to the master volume value “4”.
When the “master volume value” is set to “eco”, the lighting device 33 is turned off during the period when the gaming machine is in the customer waiting state, and the image display device 31 when not operated is displayed. Set the brightness low.
The “master volume value” set using the volume switching SW 280 is referred to as a “hard volume value” in the present embodiment.
When the volume switching SW 280 is operated while the gaming machine is not energized, the host CPU 151 sets the hard volume value according to the output value of the volume switching SW 280 when the gaming machine is started up. The hard volume value is stored in the host RAM 152 of the image control board 150.

When waiting for a customer or when the special symbol changes, the master volume value (initial value) set by the volume switching SW 280 is changed from “1” to “ Adjust between 10 ".
This adjusted master volume value is referred to as a “soft volume value” in the present embodiment.
When the initial value by the volume switching SW 280 is “eco”, adjustment by the player using the cross key 40 cannot be performed.
The master volume value adjusted using the left and right keys is stored in the host RAM 152 of the image control board 150.

Returning to the flowchart of FIG. 49, the host CPU 151 performs a system sound setting process in step S1002.
This is a setting / output process of an error sound (system sound) according to an instruction from a higher-order board (main control board 110, effect control board 120). Details will be described later with reference to FIG.
Next, the host CPU 151 performs effect sound setting processing in step S1003.
This is an effect sound setting / output process in response to an instruction from the higher-order board (effect control board 120). Details will be described later with reference to FIG.

Next, in step S1004, the host CPU 151 performs processing for the sound currently being output.
This is a control process for the sound currently output by the sound control circuit 300. Details will be described later with reference to FIG.
Next, the host CPU 151 performs a command output process for outputting a control command to the voice control circuit 300.

FIG. 50 is a flowchart for explaining master volume setting processing by the image control board.
In step S1101, the host CPU 151 determines whether or not a hard volume has been changed using the volume switching SW 280.
If it is determined that the hard volume value has been changed (Yes in step S1101), the host CPU 151 sets the changed hard volume value as the master volume value in step S1102.

If it is determined that there is no change in the hard volume value (No in step S1101), the host CPU 151 determines whether or not the soft volume value is changed using the cross key (left / right key) 40 in step S1103. .
If it is determined that the soft volume value has been changed (Yes in step S1103), the host CPU 151 sets the changed soft volume value as the master volume value in step S1102.
If the soft volume value has not been changed (No in step S1103), the host CPU 151 ends the current volume setting process.

Next, system sound (error sound) and effect sound setting processing by the image control board in the gaming machine of this embodiment will be described.
As described above, in the gaming machine according to the present embodiment, the host CPU 151 of the image control board 150 is necessary based on the fluctuation effect pattern specified by the effect pattern specification command supplied from the effect control board 120 that is the upper circuit board. The voice is selected from the voice management table, and the voice control circuit 300 is instructed to output it.
As for the error sound, the necessary sound is obtained based on various sensor detection results (dish full detection result, door open detection result, ball clogging detection result, illegal radio wave detection result) supplied from the main control board 110. It selects from the voice management table and instructs the voice control circuit 300 to output it.

The sound used in the gaming machine of this embodiment will be described.
51 and 52 are diagrams illustrating an example of a sound management table provided in the image control board.
In the voice management table shown in FIG. 51, each system sound is managed in association with a sound number.
Also, in the sound management table shown in FIG. 52, the sound number, its priority, and the stereo / monaural type are managed in association with the sound number.
Usually, the priority is not particularly conscious. However, as described later, when the audio channel of the audio control circuit 300 is exhausted, the priority is a level for determining audio to be preferentially reproduced. .

  In the table of FIG. 51, sound number 1 is an error sound that is emitted when the door is opened, and sound number 2 is sounded when an unauthorized radio wave is detected by the magnetic sensor 50 installed on the game board. Error sound. The sound number 3 is an error sound that is generated when a ball is clogged, and the sound number 4 is an error sound that is generated when the storage ball of the game ball is full.

When the occurrence of these events is detected by various sensors connected to the main control board 110, a detection signal is input from the main control board 110 to the image control board 150 via the effect control board 120.
As a result, the host CPU 151 selects a sound number according to various events occurring in the gaming machine, and transmits an output command to the voice control board 300.

Note that these error sounds have priorities set according to the importance of the error, and the priority is set to “High” for door opening and fraud detection that lead to or result from fraud. Has been.
Although “ball clogging” is an important error, the priority is set to “medium” because it is less important than fraudulent acts.
The notification when the storage ball of the game ball is full is clearly lower in importance than the above, and therefore the priority is “low”.

The error notification is controlled so that only one highly important error sound can be heard.
For example, when the door full is notified when the dish number full notification of the sound number 4 (importance “low”) is generated, an error sound of the sound number 1 is generated and the error sound of the sound number 4 is generated. Mute Then, when the door open state is resolved, the error sound of the sound number 1 is stopped and the volume of the error sound of the sound number 4 is restored.
When a note number with a high priority is generated, even if an event with a lower priority occurs, a new error sound for that event does not occur.
If events of the same priority occur in parallel, an error sound is output for the event that occurred later.

In the table of FIG. 52, note numbers 11 to 20 are, for example, stereo sound background sounds (BGM) output during a period in which special symbols are variably displayed (during variability).
In particular, the sound number 11 is a BGM of stereo sound that is reproduced before the start of the reach effect in the change effect corresponding to the change effect patterns 1 and 2.

The sound number 12 is a BGM of stereo sound that is reproduced after the start of the reach effect in the change effect corresponding to the change effect patterns 1 and 2.
In gaming machines, BGM is often different before and after the start of reach. Of course, the same BGM may be used before and after the start of reach.
Since such BGM basically does not strongly suggest a game result or a game state to the player, the priority is set low.

The sound number 13 is BGM that is reproduced before the start of the reach effect in the change effect corresponding to the change effect patterns 3 and 4.
The sound number 14 is BGM that is reproduced after the start of the reach effect in the change effect corresponding to the change effect patterns 3 and 4.

In addition, the sound number 15 is a BGM that is reproduced during the variation effect in the variation effect corresponding to the variation effect pattern 9 (normal fluctuation not including reach).
The sound numbers 16 to 18 are BGM reproduced in a specific effect, and the priority is set high. These effect sounds will be described in detail later.

The sound numbers 21 to 23 are BGM of stereo sound reproduced during the jackpot game.
The jackpot BGM is basically not a voice that provides special information to the player, so the priority as a voice is set low.
The jackpot BGM is divided into three parts, the sound number 21 is the A melody portion of the jackpot medium BGM, the sound number 22 is the B melody portion, and the sound number 23 is the rust portion.

The sound number 31 is an effect sound that is reproduced when the player operates (presses once) the effect button 8 in a winning branch effect (described later) performed during a specific reach effect.
This is basically a single sound and has a very short reproduction time, so that the sound does not need to be so thick, so monaural sound is sufficient.
However, the winning branch effect using the effect button 8 is a rare opportunity that the player can directly participate in the effect, and since the effect of the effect is great, the voice priority is set high.

The sound number 32 is an effect sound that is reproduced when the player operates (repeatedly) the effect button 8 in a winning branch effect (described later) performed during a specific reach effect.
This is basically a single sound, has a very short playback time, and does not require so much thickness, so monaural sound is sufficient.
However, the winning branch effect using the effect button 8 is a rare opportunity that the player can directly participate in the effect, and since the effect of the effect is great, the voice priority is set high.

The sound number 41 is a sound effect that is used to dynamically add an effect to the BGM and improve the rendering performance during the fluctuating performance, particularly during the reach. It is desirable to set a higher priority.
The sound number 42 is, for example, a sound effect that is generated at the time of the mode transition effect after the small hit.
The sound number 51 is an effect design change start sound (monaural) for notifying the player of the start of change of the effect design 35 in the change effect, and the sound number 52 is a change stop sound (monaural) of the effect design 35. is there. These priorities are medium.

  The sound numbers 61 to 69 are voices such as voices of characters used in a notice effect described later, particularly a group notice. Although the sounds are related to each other, since they are voices produced by different characters, they are different voices.

The sound numbers 71 to 80 are operation sounds generated when the volume is adjusted using the cross key 40.
As will be described later, in the gaming machine of the present embodiment, when the volume is adjusted using the cross key 40, the scale increases when the right key (volume up) is pressed, and the scale decreases when the left key (volume down) is pressed. A sound is emitted.
Therefore, different operation sounds corresponding to the above-described volume “1” to volume “10” are prepared.

The sound numbers 91 to 100 are winning sounds that are emitted when a game ball enters the big winning opening or the starting opening.
When winning a prize continuously such as during a big hit, a plurality of types of voices are prepared so that a scale such as Doremi ... is obtained.

The sound number 110 is an “over winning notification sound” for notifying the player as an over-winning when there is a winning over a predetermined number (9) per round during the big winning game. is there.
The sound number 120 is BGM (being non-reach) -A1 for the start of the reach effect, which is used when the specific effect pattern and the effect mode is the first effect mode (described later).
In the gaming machine of the present embodiment, different effect motifs are used for each effect mode, and BGM is also different for each effect mode.

The sound number 121 is a BGM (not reaching) BGM (not reaching) different from AGM used when the specified effect pattern and the effect mode is the second effect mode (described later)- A2.
The sound number 122 is BGM (being non-reach) -A3 for the start of the reach effect, which is used when the specific effect pattern and the effect mode is the third effect mode (described later).
The sound number 123 is common BGM (during reach) -A used in all the first to third effect modes in the specific effect pattern.

The sound number 130 is the reach notification effect sound 1 used in the first effect mode.
The reach notification effect sound is an effect sound for notifying the player of the start of the reach effect as will be described later, and this also differs for each effect mode.
The sound number 131 is the reach notification effect sound 2 used in the second effect mode.
The sound number 132 is the reach notification effect sound 3 used in the third effect mode.
Note that the BGM with sound numbers 120 to 122 and the reach notification effect sounds 1 to 3 with sound numbers 130 to 132 shown in FIG. Needless to say, it can be used at 11 or the like.

FIG. 53 is a flowchart showing system sound setting processing by the image control board.
In step S1201, the host CPU 151 determines whether various error detection signals have been input from the main control board 110 (main CPU 111) (whether an error has occurred).
If it is determined that an error detection signal has been input (Yes in step S1201), the host CPU 151 sets 1 in the error detection flag in the host RAM 152 in step S1202, and in step S1203, whether there is an effect sound currently being output. Determine whether or not.

If there is an effect sound currently being output (Yes in step S1203), the host CPU 151 saves the current master volume value in the host RAM 152 and sets a new master volume value with a predetermined amount lowered in step S1204. (A volume value reset command for lowering the volume of the production sound is set in the transmission buffer).
That is, in the gaming machine of this embodiment, when outputting an error sound, the volume of the effect sound is reduced so that the error sound can be heard more easily.

Next, in step S1205, the host CPU 151 sets an error sound output command in the transmission buffer and ends the system sound setting process.
If it is determined in step S1203 that there is no effect sound being output (No in step S1203), the host CPU 151 proceeds to step S1205 as it is and sets an “error sound output command” in the transmission buffer.
If it is determined in step S1201 that no error detection signal has been input (No in step S1201), the host CPU 151 sets an error detection flag to 0 in step S1206, and an error that has occurred in the gaming machine in step S1207. Is resolved (whether or not a state change has occurred in which the error detection flag changes from 1 to 0).

If it is determined that the error that has occurred in the gaming machine has been resolved (Yes in step S1207), the host CPU 151 restores the master volume value to the master volume value stored in step S1204 (the volume of the effect sound). In step S1209, an “error sound stop command” is set in the transmission buffer, and the current system sound setting process is terminated.
If it is determined that the error has not been resolved (no error has occurred) (No in step S1207), the host CPU 151 ends the current system sound setting process.

FIG. 54 is a flowchart showing effect sound setting processing by the image control board.
In step S1301, the host CPU 151 determines whether or not an effect sound output instruction (transmission of the effect pattern designation command shown in FIGS. 36 and 37) has been received from the sub CPU 121.
When it is determined that there is an effect sound output instruction (Yes in step S1301), the host CPU 151 analyzes the effect pattern designation command in step S1302.

Next, in step S1303, the host CPU 151 determines a sound number to be designated for the sound control circuit 300 based on the variation effect pattern designated by the effect pattern designation command.
A sound number may be designated in the production pattern designation command itself.

Next, the host CPU 151 checks the master volume value stored in the host RAM 152 in step S1304.
Next, in step S1305, the host CPU 151 performs channel selection processing described later.
The master volume value stored in the host RAM 152 is confirmed.
Further, in step S1306, the host CPU 151 sets, in the transmission buffer, an “effect sound output command” including the sound number determined in step S1303, the audio channel selected in step S1306, and the volume based on the master volume value confirmed in step S1304. Then, the sound control circuit 300 reproduces the effect sound.

FIG. 55 is a flowchart for explaining the audio output processing by the image control board.
In step S1401, the host CPU 151 determines whether there is an effect sound that is currently being output by the audio control circuit 300.
If it is determined that there is a sound being output (Yes in step 1401), the host CPU 151 determines in step S1402 whether or not the master volume value has been changed by the volume setting process (FIG. 49: step S1001).

If the master volume value has been changed (Yes in step S1402), the host CPU 151 sets a volume value reset command based on the changed master volume value in the transmission buffer in step S1403, and sends it to the audio control circuit 300. Send.
If there is no sound being output (No in step S1401), or if there is no change in the master volume value (No in step S1402), the host CPU 151 ends the current output process.
The soft volume value confirmed in step S1103 can be changed only when waiting for a customer.

If it is determined in step S1402 that there is no change in the master volume value (No in step S1402), the host CPU 151 needs to perform volume adjustment, fade-in, and fade-out later in the effect sound currently being output in step 1404. It is determined whether there is anything.
If there is such an effect sound (Yes in step S1404), the host CPU 151 sets a volume value reset command for the necessary audio channel in step S1405, and ends the current output process.

<Auto channel processing>
FIG. 56 is a diagram for explaining audio channel selection processing by the image control board.
As described above, in the gaming machine according to the present embodiment, the voice control circuit 300 includes 40 voice channels and can simultaneously play up to 40 voices.

When the host CPU 151 reproduces and outputs the production sound, the channel is empty (no audio is output) from 34 channels excluding the six audio channels reserved for the system sound (error sound). And an effect sound output command including information on the selected sound channel, sound number, and volume is input to the sound control circuit 300.
The voice control unit 301 that controls the voice control circuit 300 inputs the voice data instructed by the host CPU 151 to the decoding unit of the designated voice channel and starts reproduction.

As for the audio channels provided in the audio control circuit 300, adjacent audio channels are used as one audio channel pair.
For example, as shown in FIG. 56, audio channel ch0 and audio channel ch1 are used as audio channel pair 1, audio channel ch2 and audio channel ch3 are used as audio channel 2, and audio channel ch4 and audio channel ch5 are audio channels. Used as pair 3.
One “audio channel” is used to reproduce one monaural data, and one “audio channel pair” is used to reproduce a set of stereo data.

  Stereo data is divided into a sound channel for the right speaker and a sound channel for the left speaker, and by playing each sound channel from each speaker at the same time, the player recognizes it as a wide stereo sound. The

  Stereo data is sound information for outputting one sound by a plurality of sound data, and monaural data is sound information for outputting one sound by a single sound data.

Furthermore, it is also possible to output surround sound using an “audio channel group” composed of three or more audio channels. In that case, in addition to the left speaker and the right speaker, it is necessary to separately provide speakers according to the number of audio channels.
The surround sound is sound data divided according to the number of speakers.
That is, an audio channel group (pair) in which a plurality of audio channels are associated in advance is set as the audio channel, and the audio control circuit 300 outputs stereo sound using the associated audio channel group (pair). Monaural audio is output using one audio channel of the audio channel group (pair).
That is, the host CPU 151 sets stereo sound for the audio channel pair (group), and sets monaural audio for one audio channel of the audio channel pair (group).

In the audio control circuit 300 of this embodiment, stereo data cannot be output across audio channel pairs.
For example, as shown in FIG. 56, stereo sound (L) and stereo sound (R) can be reproduced and output using the audio channel ch16 and the audio channel ch17 constituting the audio channel pair 9, but the audio channel pair 5 Cannot be reproduced and output using the audio channel ch 9 included in the audio channel 10 and the audio channel 10 included in the audio channel pair 6.

Therefore, in the case of newly outputting stereo sound in the case of FIG. 56, the host CPU 151 is not limited to the audio channel pair 6 (audio channel ch10, audio channel ch11) in which stereo audio has already been output. The channel pair 4 or the channel pair 5 from which monaural sound is output is not selected.
Channel pair 7 or channel pair 9 is selected in which all audio channels are vacant.

In the case of FIG. 56, when a new monaural sound is output, the host CPU 151 outputs the other channel in the channel pair outputting the monaural sound in one of the channel pairs. For example, the audio channel ch7 and the audio channel ch8 correspond to this.
This is due to the fact that stereo audio can be reproduced and output only with one channel pair as described above.

Since it is impossible to output stereo audio in a channel pair in which monaural audio has already been reproduced and output in one audio channel, for example, if monaural audio is input to the audio channel ch14 of the currently available channel pair 8, In addition, one channel pair capable of outputting stereo sound is reduced.
In the gaming machine of this embodiment, by inputting new monaural sound to the other channel pair of the channel pair outputting mono sound on the one hand, the sound channel can be efficiently used without wasting the sound channel. I am trying to use it.

The case where all the audio channels are filled will be described.
When there is a request for a new audio output when all the audio channels that can be used for the production sound are filled, the host CPU 151 outputs the audio with the lowest priority among the audios being reproduced. Input new audio to the audio channel.
Since only one audio can be output in one audio channel, the audio with low priority that has been output previously is stopped, and the newly requested audio is output from that audio channel.
Even if the newly requested voice priority is lower than the currently output voice, the new voice output is given priority. However, if the newly requested voice has the lowest priority, the request may be discarded without outputting.

  When a plurality of low priority sounds are output, the host CPU 151 inputs a new sound from among them to a sound channel outputting a sound having a short remaining reproduction time.

In the case of the present embodiment, in the case where the sound with the same sound number is continuously reproduced, the host CPU 151 inputs the sound to the same sound channel.
The case where the sound having the same sound number is continuously played back is, for example, a case where the player repeatedly strikes the effect button 8 in the button effect during reach.
In the button hitting effect, when the effect button 8 is hit repeatedly, an effect button repeated sound (sound number 32) shown in the management table of FIG. 52 is generated.
When the production button 8 is repeatedly hit, it is necessary to continuously generate the production button repeated sound (sound number 32). However, if all voices are input to different empty audio channels, the empty channels are quickly exhausted. become.

Further, in this embodiment, when there is no empty channel, the newly input sound is basically preferentially pronounced, so the sound (effect sound) output on other sound channels is also available. , It is overwritten by the newly input effect button press sound.
In other words, since only one sound can be output in one audio channel, the previously output sound is stopped, and the newly requested (input) sound (production button press sound) is output from the sound channel. Is done.
As a result, other production sounds other than the production button pressing sound are not output, and the production becomes unnatural.

Therefore, in the gaming machine of the present embodiment, the same sound number is assigned to the sound having the same content, and when the same sound number is continuously input, the same sound channel is continuously input. .
As a result, a limited number of audio channels included in the audio control circuit 300 can be used efficiently.
In addition, if the same sound (the direct sound of the effect button) is input to different audio channels and played back, the sounds overlap and are heard by the player, but they are input to the same audio channel and overwritten. Such an inconvenience can be solved by outputting (while stopping the output of the effect button pressing sound input earlier).

In the gaming machine of the present embodiment, in the production in which the level gauge 39 is extended every time the production button 8 is repeatedly hit, until the level gauge 39 becomes MAX, the production button continuous hit sound (sound number 32) is generated. After the level gauge 39 becomes MAX, a different production button repeated sound (sound number 33) is generated.
Thereby, it is possible to effectively notify the player that the level gauge 39 has become MAX.
Also in this case, the sound channel can be used more efficiently if the effect button consecutive hit sound of the sound number 32 and the effect button consecutive hit sound of the sound number 33 are input to the same audio channel.

In addition to this, the process of inputting the same type of sound to the same audio channel is also performed for a winning sound (FIG. 52: sound numbers 91 to 100) to be output when the game ball wins a start opening or a big winning opening. obtain.
That is, in the gaming machine of the present embodiment, sounds from the sound number 91 “do” to the sound number 97 “shi” are prepared as winning sounds, and the winning sounds with different sound numbers are generated in the winning order. It has become.

In this case, for example, when a large number of game balls have won a big prize opening in a very short time, such as during a jackpot game, if all the winning sounds related to these are output from different audio channels, the number is limited. An audio channel with saturates.
Therefore, especially during a jackpot game, consecutively generated winning sounds with different contents are regarded as the same type of sound and input to the same audio channel to prevent saturation of the audio channel.

FIG. 57 is a flowchart for explaining audio channel selection processing by the image control board according to the present embodiment.
The audio channel selection process may be performed on the audio control circuit 300 side (by the audio control unit 301).

In step S1501, the host CPU 151 determines whether or not the sound having the same sound number as the effect sound specified by the variation effect pattern is output.
For example, this is a case where the effect button pressing sound (sound number 31) as described above is continuously generated.
If the sound having the same sound number is output (Yes in step S1501), the host CPU 151 sets the sound channel (in monaural) or channel pair (in stereo) to the sound of the designated sound number in step S1502. Select as output destination.
The host CPU 151 outputs the same sound (sound based on the first sound information) as the currently output sound (sound based on the first sound information) or similar sound (sound based on the second sound information). In the case of output, output is performed using an audio channel that outputs audio based on the first audio information (new first audio information and second audio information are converted to the first audio information at present). Set to the audio channel that is outputting the audio based on.)

If the same sound number is not output (No in step S1501), the host CPU 151 determines in step S1503 whether the sound having the specified sound number is stereo sound or monaural sound.
If it is stereo audio (Yes in step S1503), the host CPU 151 determines whether there is an empty audio channel pair in step S1504.
If it is determined that there is an empty audio channel pair (Yes in step S1504), the host CPU 151 selects any audio channel pair selected from the empty audio channel pairs in step S1505 as the stereo audio of the designated sound number. Set as output destination.
The host CPU 151 outputs a sound using a sound channel that does not output sound among a plurality of sound channels (a new sound is set for a sound channel that does not output sound among the plurality of sound channels). To do).

  If it is determined in step S1504 that there is no free audio channel pair (no audio is set for all audio channel pairs among the configurable audio (variable) channel pairs) (No in step S1504), the host CPU 151 In step S1506, a specific audio channel, for example, the audio channel pair that is outputting the audio with lower priority than the newest effect sound with a short remaining playback time is selected (set) as the output destination, and the newest effect Output sound (always).

At this time, the production sound of the specific audio channel pair (the audio channel pair that is outputting the audio with lower priority than the newest production sound with a short remaining playback time) was stopped and the stopped sound was output. Using the audio channel pair (used for output control), the new audio is output (set as the output destination).
New audio may be output using any audio channel pair (set as an output destination) instead of a specific audio channel pair.
At this time, the production sound of one of the audio channel pairs is stopped, and the new audio is output using the audio channel pair that was outputting the stopped audio (used for output control) (set as the output destination). Is output.

In particular,
(1) Stop the sound that is being played back and output the low-priority performance sound.
For example, when the priority is “high”, “medium”, or “low” as in the voice management table of FIG. 52, the sound effects having the priority “high” in a state where all the variable channels are filled (for example, For the group announcement sounds 61 to 69 of the announcement effect and the effect button continuous hit sounds 32 and 33), the sound of the low priority (low) reach BGM 14 or the like is stopped.
(2) Rather than simply stopping the output of the low-priority production sound, if there are a plurality of production sounds with lower priority than the production sound to be newly reproduced (want to be preferentially reproduced) The output of the effect sound with the shortest remaining playback time or the effect sound being reproduced from the earliest is stopped from the effect sounds straddling the priority order.

Note that the priority order may be set between stereo sound and monaural sound, instead of simply following the priority level set in the sound management table of FIG.
For example, priority is given to stereo sound over monaural sound.
In this case, if there is no empty channel pair for outputting new stereo sound, the host CPU 151 determines in step S1506 whether there is a channel pair occupied by monaural sound.
Then, among the channel pairs that are playing these monaural audio, the remaining short playback time or the low priority audio is paired with the channel pair that is playing (there is stereo audio with a lower priority than those monaural audio). Input new stereo sound.

  On the other hand, if monaural audio is prioritized over stereo audio, select the channel pair that is playing back low-priority audio with the shortest remaining playback time from the channel pairs that are playing back stereo audio. Input new stereo sound.

If it is determined in step S1503 that the specified audio is not stereo audio (No in step S1503), the host CPU 151 determines in step S1507 whether there is an audio channel pair that is playing back monaural audio. To do.
If there is such an audio channel pair (Yes in step S1507), the host CPU 151 inputs the monaural audio of the designated sound number and the volume value in the empty channel of the audio channel pair in step S1508.
The host CPU 151 causes the audio to be output using an audio channel that does not output audio (set as an output destination).

If it is determined in step S1507 that there is no audio channel pair that is playing back monaural audio (No in step S1507), the host CPU 151 determines in step S1509 whether there is an empty audio channel pair.
If it is determined that there is a free audio channel pair (Yes in step S1509), the host CPU 151 determines in step S1510 that one of the free audio channels of the empty channel pair has the monaural audio of the designated specified sound number. Enter the volume value.
The host CPU 151 causes the audio to be output using an audio channel that does not output audio (set as an output destination).

  If it is determined that there is no free audio channel pair (no audio is output on all audio channels among the configurable audio (variable) channels) (No in step S1509), the host CPU 151 determines in step S1511. One of the audio channels, for example, an audio channel that is outputting low-priority audio with a short remaining reproduction time, is selected (set) as a monaural audio output destination with a designated sound number.

At this time, the production sound of the specific audio channel (the audio channel pair outputting the audio with lower priority than the newest production sound with a short remaining playback time) was stopped, and the stopped sound was output ( Using the audio channel (used for output control) (set as the output destination), a new audio is output.
New audio may be output using any audio channel (set as an output destination) instead of a specific audio channel.
At this time, the production sound of one of the audio channels is stopped, and the new audio is output using the audio channel that has been output (used for output control). To do.
As described above, the priority order may be set between stereo sound and monaural sound, instead of simply following the priority level set in the sound management table of FIG.
For example, it is assumed that stereo sound is given priority over monaural sound.
If there is no empty channel pair for outputting new monaural audio, in step S1511, the remaining playback time or low priority audio in the channel in which the monaural audio is being played is assigned to the channel being played (from the monaural audio). (Even if there is stereo audio with a lower priority), input new monaural audio.

On the other hand, if monaural audio is prioritized over stereo audio, select the channel pair that is playing back low-priority audio with the shortest remaining playback time from the channel pairs that are playing back stereo audio. , A new monaural sound is output to one channel of the channel pair.
In this case, one channel of the channel pair is an empty channel.

<Soft volume adjustment processing>
The above-described adjustment of the soft volume value can be performed using the cross key when waiting for a customer.
It should be noted that the adjustment of the soft volume value using the cross key 40 can be performed not only when waiting for a customer but also during the change of a special symbol. However, it cannot be performed after the symbol is confirmed (after the symbol confirmation command is received).
Hereinafter, the adjustment process of the soft volume value in the image control board will be described.
In the gaming machine of the present embodiment, when adjusting the volume using the cross key 40 (left / right key) while waiting for a customer, the scale increases when the volume up button (right key) is pressed, and the volume down button (left key). ), A sound that lowers the scale is generated.

The sounds constituting the scale correspond to the respective volume values from “1” to “10” as shown in the sound management table (FIG. 52).
That is, the volume value “1” is a “do” sound, the volume value “2” is a “le” sound, the volume value “3” is a “mi” sound, the volume value “4” is a “fa” sound, Volume value “5” is “So” sound, Volume value “6” is “La” sound, Volume value is “7” is “Shi” sound, Volume value “8” is 1 octave higher “Do” , The volume value “9” corresponds to the “re” sound one octave above, and the volume value “10” corresponds to the “mi” sound one octave above.

58 and 59 are diagrams for explaining a confirmation sound emitted from the sound output device (speaker) when the cross key is operated while waiting for a customer in the gaming machine of the present embodiment.
For example, when the master volume value (hard volume) is 7, it is assumed that the customer wait state shown in FIG. 58 (a) is reached and volume adjustment (change of soft volume) using the cross key 40 becomes possible.
In FIG. 58 (a) and FIG. 59 (o), “waiting for customers” is displayed on the screen for the sake of convenience, but it is not necessarily displayed.
When waiting for a customer, as shown in FIG. 58 and FIG. 59, an effect design 35 (stop design) of a stop mode is displayed, and this is superimposed on a volume gauge 37 displayed at the time of volume adjustment. .

  Here, as shown in FIG. 58B, when the right key (volume up button) is pressed, the master volume value becomes “8”, and the audio control circuit 300 makes an audio of “do” corresponding to the volume “8”. Is sounded from the audio output device 34 at the volume “8”. At the same time, the volume gauge 37 shown in the image display device 31 is in a state indicating “8”.

Next, as shown in FIG. 58 (c), when the right key is further pressed, the master volume value becomes “9”, and the host CPU 151 outputs the sound “re” corresponding to the volume “9” to the volume “9”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is incremented by one to indicate “9”.
Next, as shown in FIG. 58 (d), when the right key is further pressed, the master volume value becomes “10”, and the host CPU 151 outputs the sound of “Mi ↑” corresponding to the volume “10” to the volume “10”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is increased by one to indicate “10”.

Next, as shown in FIG. 58 (e), when the left key is pressed, the master volume value becomes “9”, and the host CPU 151 outputs the sound “R ↑” corresponding to the volume “9” to the volume “9”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and shows “9”.
Even if the right key is pressed here, the volume has reached the upper limit, and no change occurs.

As shown in FIG. 58 (f), when the left key is further pressed, the master volume value becomes “8”, and the host CPU 151 plays the sound of “do” corresponding to the volume “8” at the volume “9”. The control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is increased by one to indicate “9”.
Next, as shown in FIG. 58 (g), when the left key is further pressed, the master volume value becomes “7”, and the host CPU 151 outputs the sound of “shi” corresponding to the volume “7” to the volume “7”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is increased by one to indicate “7”.

  Next, as shown in FIG. 58 (h), when the left key is pressed, the master volume value becomes “6”, and the host CPU 151 outputs the sound “ra” corresponding to the volume “6” at the volume “9”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and shows “9”.

Next, as shown in FIG. 59 (i), when the left key is pressed, the master volume value becomes “5”, and the sound control circuit 300 outputs the sound of “So” corresponding to the sound volume “5” to the sound volume “5”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and becomes “5”.
Next, as shown in FIG. 59 (j), when the left key is pressed, the master volume value becomes “4”, and the host CPU 151 causes the voice of “F” corresponding to the volume “4” to be heard at the volume “4”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one to indicate “4”.

Next, as shown in FIG. 59 (k), when the left key is pressed, the master volume value becomes “3”, and the host CPU 151 causes the sound “mi” corresponding to the volume “3” to be heard at the volume “3”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and becomes “3”.
Next, as shown in FIG. 59 (l), when the left key is pressed, the master volume value becomes “2”, and the host CPU 151 causes the sound “re” corresponding to the volume “2” to be heard at the volume “2”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and becomes “2”.

  Next, as shown in FIG. 59 (m), when the left key is pressed, the master volume value becomes “2”, and the host CPU 151 outputs the sound of “do” corresponding to the volume “1” at the volume “1”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and becomes “1”.

Next, as shown in FIG. 59 (n), when the right key is pressed, the master volume value becomes “2”, and the host CPU 151 causes the sound “R” corresponding to the volume “2” to be heard at the volume “2”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is decreased by one and becomes “2”.
When the effect button 8 is operated in this state, the volume gauge 37 is not displayed as shown in FIG.
That is, in the gaming machine of the present embodiment, the master volume value is changed (confirmed) by operating the cross key 40 (left / right key), and the display of the volume gauge 37 is deleted by operating the effect button 8.
When operating the soft volume with the four-way controller, it is possible to increase the volume of the confirmation sound without increasing the scale. In that case, of course, only one confirmation sound needs to be prepared.
Further, the volume gauge 37 is not displayed when a predetermined time has elapsed without operating the effect button 8.

  For example, when the gaming machine is not operated for 120 seconds after receiving the customer waiting command, the master volume value is reset to the initial volume value (hard volume) set by the DIP switch (volume switching SW 280).

  In the example of FIG. 58, the volume adjustment using the cross key 40 while waiting for a customer has been described. However, as described above, the volume (soft volume) adjustment using the cross key 40 is performed while the design is changing. (Except when the symbol is fixed) (FIG. 60).

FIG. 60 is a diagram for explaining a confirmation sound emitted from the sound output device (speaker) when the cross key is operated during a change in the gaming machine of the present embodiment.
When the operation of the cross key 40 is performed while the effect symbol 35 is changing, the volume gauge 37 is displayed so as to overlap the effect symbol 35.
However, as will be described below, the volume gauge 37 is not displayed during the final display of the effect symbol 35 even when the cross key 40 is being operated.
However, if the effect design 35 is still in the temporary stop state before the confirmation display, the volume gauge 37 is displayed and the volume can be adjusted.

The effect symbol 35 that is confirmed to be displayed after the change is stopped is important information for notifying the player of the game result (whether it is a win or a loss, or if the win is a normal symbol).
Therefore, when the effect symbol 35 is confirmed and displayed, the volume gauge 37 displayed so as to be superimposed on the effect symbol 35 is hidden, so that the player can surely see the effect symbol 35.

For example, in FIG. 60A, it is assumed that the production symbol 35 is in a stop mode and the master volume value (hard volume) at that time is 8.
At this time, volume adjustment (change of soft volume) using the cross key 40 is impossible.
In FIG. 60 (b), when a predetermined period (15 frames) elapses after the dynamic display of the effect symbol 35 is started, volume adjustment using the cross key 40 becomes possible.
When the right key (volume up button) is pressed as shown in FIG. 60 (c), the master volume value increases by one to “9”, and the volume gauge 37 indicating “9” is displayed.
At the same time, the host CPU 151 causes the sound control circuit 300 to output (sound) the sound of “L” corresponding to the sound volume “9” at the sound volume “9”.
Next, as shown in FIG. 60D, the effect design 35 is still changing, and when the right key is further pressed, the master volume value becomes “10”.
The host CPU 151 causes the sound control circuit 300 to output (sound) the sound of “mi ↑” corresponding to the sound volume “10” at the sound volume “10”. At the same time, the volume gauge 37 is increased by one to indicate “10”.

Next, as shown in FIG. 60 (e), after the left and right symbols of the effect symbol 35 are stopped and displayed in a reach manner (temporary stop), the middle symbol is still changing, so the cross key 40 is used. It is still possible to adjust the volume.
Therefore, for example, when the left key is pressed, the master volume value becomes “9”, and the host CPU 151 outputs (sounds) the voice of “R” corresponding to the volume “9” from the voice control circuit 300 at the volume “9”. Let At the same time, the volume gauge 37 is decreased by one and shows “9”.
Even if the right key is pressed here, the volume has reached the upper limit, and no change occurs.

As shown in FIG. 60 (f), when the left key is further pressed, the master volume value becomes “8”, and the host CPU 151 plays the sound of “DO” corresponding to the volume “8” at the volume “9”. The control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is increased by one to indicate “9”.
Next, as shown in FIG. 60 (g), when the left key is further pressed, the master volume value becomes “7”, and the host CPU 151 outputs the sound of “shi” corresponding to the volume “7” to the volume “7”. The voice control circuit 300 outputs (sounds). At the same time, the volume gauge 37 is increased by one to indicate “7”.

As shown in FIG. 60 (h), the volume adjustment using the cross key 40 is still possible even if the middle symbol 35b is temporarily stopped and the effect symbol 35 is temporarily stopped.
Therefore, for example, when the left key is pressed, the master volume value becomes “6”, and the host CPU 151 causes the sound control circuit 300 to output (sound) the sound “ra” corresponding to the sound volume “6” at the sound volume “6”. . At the same time, the volume gauge 37 is increased by one to indicate “6”.
Further, as shown in FIG. 60 (i), when the effect symbol 35 is confirmed and stopped (by receiving the symbol confirmation command), the volume gauge 37 is not displayed, and the cross key 40 is displayed until the next waiting for the customer or when the change starts. Volume adjustment using is impossible.
However, if the effect button 8 is operated (pressed) before the change of the effect symbol is stopped, the display of the volume gauge is deleted.

FIG. 61 is a flowchart for explaining the soft volume adjustment processing (using the left and right keys) by the image control board described in FIGS. 58, 59, and 60.
In the gaming machine of the present embodiment, since the player can adjust the volume of the gaming machine only when the gaming machine is in the waiting state for the customer, the host CPU 151 determines that the current gaming machine state is waiting for the customer in step S1600. It is determined whether or not it is in a state.

The host CPU 151 can determine that the gaming machine is in a customer waiting state from the fact that the effect symbol is not variably displayed and the jackpot effect image is not displayed.
If it is determined that the state of the gaming machine is not waiting for customers (during symbol change or big hit) (No in step S1600), the host CPU 151 determines in step S1601 whether the symbol is currently changing.
If it is determined that the symbol is not changing (No in step S1601), the host CPU 151 ends the soft volume adjustment process without performing anything.

When it is determined that the state of the gaming machine is waiting for customers (Yes in step S1600), or when it is determined that the symbol is changing (Yes in step S1601), the host CPU 151 determines that the right key or It is determined whether or not the left key has been operated.
This is determined by determining whether an input signal of the right key and the left key is transmitted from the effect control board 120.
If the left key and right key detection switches of the cross key 40 are connected to the image control board 150, the image control board 150 can independently detect the operation of the left and right keys.

If it is determined that neither the right key nor the left key is operated (No in step S1602), the host CPU 151 ends the soft volume adjustment process without performing anything.
If it is determined that the left / right key has been operated (Yes in step S1602), the host CPU 151 determines in step S1603 whether the current setting of the volume switch SW280 is “eco”.
If it is “eco” (Yes in step S1603), the adjustment of the master volume value itself is not permitted, and the soft volume adjustment process is terminated without doing anything.
If it is not “eco” (No in step S1603), the host CPU 151 determines which one of the right key and the left key has been operated (which key input signal has been transmitted from the effect control board 120).
If it is determined that the right key has been operated (Yes in step S1604), the host CPU 151 determines whether or not the current master volume value is the upper limit value “10” in step S1605.

When determining that the current volume value is not the maximum value (No in step S1605), the host CPU 151 increases the master volume value by one in step S1606, and in step S1607, corresponds to the master volume value after the increase. An output command for sounding the confirmation sound at the volume is transmitted to the sound control circuit 300, and the master volume adjustment process is terminated.
In this case, the VDP 200 may be controlled to display a volume bar on the image display device 31 in accordance with the adjusted master volume value.
If the current volume value is the maximum value (Yes in step S1605), no further volume up is possible and the soft volume adjustment process is terminated.

If it is determined in step S1604 that the right key is not operated (No in step S1604), it is determined that the left key is operated.
In this case, in step S1608, the host CPU 151 determines whether or not the current volume value is the lower limit value, that is, the minimum volume value “1”.

When the current volume value is the lower limit value of the hard volume (minimum volume value “1”) (Yes in step S1608), it is determined that further volume down is impossible, and the soft volume adjustment process is terminated.
On the other hand, if the current volume value is not the lower limit value of the adjustable volume value (No in step S1608), the host CPU 151 decreases the master volume value by one point in step S1609, and in step S1610, the master after the increase. An output command for generating a confirmation sound corresponding to the volume value at the volume is transmitted to the voice control circuit 300, and the soft volume adjustment process is terminated.

[Voice control circuit]
<Audio output processing by the audio control circuit>
Next, audio output processing by the audio control circuit 300 based on control by the host CPU 151 will be described.

As described above, the audio control circuit 300 includes a fixed channel used for outputting an error sound (system sound) and a variable channel used for outputting a production sound.
That is, of the audio information, audio (system sound / effect sound) based on specific audio information is output using a specific audio channel (fixed channel / variable channel) among a plurality of audio channels.
If the command input from the host CPU 151 is “effect sound output command”, the sound control unit 301 inputs the effect sound data specified by the “effect sound output command” to the specified variable channel.
Then, the audio control unit 301 gives a decoding unit control command and a volume control command to the decoding unit 310 and the channel volume control unit 311 in the designated audio channel, respectively.
If the input command is an “error sound output command”, control is performed so that error sound data according to the error content is input to the sound channel designated there.

Upon receiving the decoding unit control command, the decoding unit 310 performs processing corresponding to the command, for example, reproduction start processing, reproduction pause processing, and reproduction end processing.
In the reproduction start process, audio data corresponding to the sound number included in the decoding unit control command is read from the sound source ROM 400 and decompressed.
The decompressed audio data is sent to the channel volume control unit 311. If the audio data stored in the sound source ROM 400 is not compressed, the decompression process is not performed.

The channel volume control unit 311 that has received the volume control command performs processing according to the command.
For example, when playback is started, control is performed to output at a specified volume (%), and when a fade-in timer is specified, the specified volume is reached at that time. Control.
When playback is stopped, the volume is set to 0. Further, when a fade-out timer is defined, control is performed so that the volume reaches 0 at that time.

  For example, when the production sound output command input from the host CPU 151 to the sound control unit 301 is “Start playback of BGM (stereo) with sound number 11 at a final volume of 90% and a fade timer of 0.1 second”. Will be described.

  The audio control unit 301 refers to the production sound output command (refers to the current status indicated by the all audio channel status information), and is not currently used (standby) audio channel specified by the production sound output command. In the channels 6 and 7, the decoding units 310-6 and 310-7 and the channel volume control units 311-6 and 311-7 of the respective audio channels ch 6 and 7 are started so as to start the reproduction of the designated audio (sound number 11). Give a command.

The decoding units 310-6 and 310-7 that have received the control command for the decoding unit read out the audio data of the sound number 11 from the sound source ROM 400 and decompress the audio data, while expanding the channel volume control units 311-6 and 311-7 in the subsequent stage. Send to.
In addition, the voice control unit 301 sends a volume control command including a volume instruction to the volume of 90% in the fade-in timer of 0.1 second to the channel volume control unit 310.
The channel volume control unit 311 that has received the volume control command receives the audio data input from the decoding units 311-6 and 311-7 as an audio signal that can be 90% volume over 0.1 second. To 320.

When the “effect sound stop command” is received from the host CPU 151, the sound control unit 301 refers to the status information of all sound channels and identifies the sound channel outputting the sound of the sound number.
Then, a decoding unit control command including a reproduction stop instruction is sent to the decoding unit 310 in order to stop the sound being reproduced in the audio channel.
The audio channel decoding unit 310 that has received such a decoding unit control command stops the decompression process of the compressed data and stops supplying the audio data to the channel volume control unit 311.
The audio channel that is outputting the sound number to be stopped may be specified in the “production sound stop command” output by the host CPU 151.

FIG. 62 is a flowchart for explaining in detail audio output processing by the audio control circuit according to the present embodiment.
As described above, the sound output process in the sound control circuit 300 is controlled by the sound control unit 301 included in the sound control circuit 300.
The voice output processing by the voice control circuit will be described in the form of a flowchart, but is actually realized by hardware logic.

In step S2001, the voice control unit 301 determines whether an error sound output command has been received from the host CPU 151.
In the error sound output command, the sound number of the error sound to be output, the sound channel to be output, and the volume value (maximum) are specified.
If it is determined that the error sound output command has been received (Yes in step S2001), the voice control unit 301 reads the system sound data of the sound number specified by the error sound output command from the sound source ROM 400 in step S2002, and step S2003. , The read system sound data and the volume value (maximum) are input to the audio channel designated by the error sound output command.
Specifically, the system sound data is input to the audio channel decoding unit 310 and the volume value is input to the channel volume control unit 311.
For error sounds with low priority, such as dish full notification, a volume value corresponding to the current master volume value may be input to the audio channel instead of the maximum volume value.

If it is determined that the error sound output command has not been received (No in step S2001), the voice control unit 301 determines in step S2004 whether or not an effect sound output command has been received.
The effect sound output command includes the sound number of the effect sound to be output, the volume, the audio channel, and the presence / absence of fade (fade in, fade out).

  If it is determined that the effect sound output command has been received (Yes in step S2004), the voice control unit 301 reads the effect sound data of the designated sound number from the sound source ROM 400 in step S2005.

Next, in step S2006, the audio control unit 301 inputs the read effect sound data and the volume value to the audio channel specified by the effect sound output command.
Specifically, the effect sound data specified by the effect sound output command is input to the audio channel decoding 310 unit, and the volume value specified by the effect sound output command is input to the channel sound volume control unit 311.
As described above, the volume value specified by the effect sound output command is a value based on the master volume value confirmed in step S1304 of FIG.

If it is determined in step S2004 that an effect sound output command has not been received (No in step S2004), the voice control unit 301 determines in step S2007 whether an error sound stop command has been received.
The error sound stop command includes the sound number of the error sound to be stopped and the audio channel.
If it is determined that an error sound stop command has been received (Yes in step S2007), the voice control unit 301 stops the error sound being output in the designated channel in step S2008.

If it is determined in step S2007 that an error sound stop command has not been received (No in step S2007), the sound control unit 301 determines in step S2009 whether or not an effect sound stop command has been received.
The production sound stop command includes the sound number to be stopped.
If it is determined that the production sound stop command has been received (Yes in step S2009), in step S2010, the audio channel that is reproducing the sound of the designated sound number is controlled to stop the production sound output.

If it is determined in step S2009 that the production sound stop command has not been received, the voice control unit 301 has received a volume value reset command (output in steps S1403 and S1405 in FIG. 55) in step S2011. Determine whether or not. As described with reference to FIG. 55, the reception of the volume value reset command means that the master volume value has been changed, or that there is a need for subsequent volume adjustment, FI, and FO on the currently produced effect sound. It is.
If it is determined that the volume value reset command has been received (Yes in step S2011), the voice control unit 301 is designated by the volume value reset command in step S2012 for the voice channel designated by the volume value reset command. Enter a new volume value and change the volume.

When it is determined that the volume value reset command has not been received (No in step S2011), the voice control unit 301 determines in step S2013 whether or not an effect sound pause command has been received.
The effect sound pause command includes the sound number of the effect sound whose playback should be paused.
If it is determined that the effect sound pause command has been received (Yes in step S2013), in step S2014, the audio control unit 301 controls the audio channel playing the designated sound number to output the effect sound. Pause.
In the “effect sound pause command”, an audio channel that outputs an effect sound to be paused may be specified.

Based on the voice control by the voice control circuit described above, the voice processing during production in the gaming machine of the present embodiment will be described below.
As a basic flow, when a game ball is won at the start opening, a winning sound 1 (sound number 91) is output by the voice control circuit 300, and a variation effect symbol variation start sound (sound number 51) and a variation effect are output. BGM (non-reach) corresponding to the pattern is output.

In the case of losing, the production symbol variation stop sound (sound number 52) corresponding to the three production symbols 35 is output, and the BGM (during non-reach) is terminated along with the suspension of the variation time.
In the case of a big hit or reach loss, a stop sound (sound number 52) of the left and right effect symbols among the three effect symbols 35 is output, and the BGM during reach (sound number 12) at the timing of the reach effect start. , 14) is output.

At the time of the big hit effect, the winning sound (91 to 97) is outputted every time the big winning opening is won, while outputting the big hit BGM (sound numbers 21 to 23).
<Sound playback during direct branching>
An output mode of effect sound performed during the winning branch effect of the present embodiment will be described.
This output mode is performed in the winning and branching effect according to the player's effect button operation during the reach effect.
In the winning branch effect, the player operates the effect button, and an effect suggesting a jackpot or a loss is performed according to the jackpot determination result.

First, the winning branch effect will be briefly described.
FIG. 63 is a diagram (part 1) illustrating a winning / branching effect performed in the gaming machine according to the present embodiment.
Here, for example, a case will be described in which the change is won by jackpot with reach B (reach B1 or B2) shown in the change effect pattern determination tables of FIGS.
In reach A (reach A1, A2), it is assumed that the winning branch effect is not performed.
The effect symbol 35 in the stop mode (a) in the image display device 31 is variably displayed (b) with the start of variation of the special symbol.
After the predetermined time has elapsed, the effect symbol 35 is in a reach state (c) where the left and right symbols are stopped and the middle symbol continues to fluctuate.
Thereafter, a reach effect (d) is performed, and a winning branch effect using the effect button 8 is performed.

In the winning branch effect, an effect button image for instructing the player to operate the effect button 8 and a time indicator 38 are displayed, and the time indicator 38 decreases as time passes ((e) → (f)).
If the player operates the effect button 8 before the time expires, a cut-in image or the like suggesting a jackpot determination result is displayed (g), and finally the effect symbol 35 is stopped and displayed in a jackpot mode or a lost mode. (H).

Cut-in images are easy to display high expectation when the jackpot determination result is “Big Win”, and conversely, when the jackpot determination result is “Lost”, the one with low expectation is displayed. Easy to be.
In this description, since a case where the jackpot is won is described, a cut-in image with high expectation is easily displayed.
FIG. 64 is a diagram (part 2) for explaining the winning branch effect performed in the gaming machine according to the present embodiment.
Only the difference from FIG. 63 will be described. In FIG. 64 (e), when the winning branch effect starts, the time indicator 38 decreases and the level gauge 39 increases every time the player repeatedly presses the button 8.
Then, when the level gauge 39 becomes MAX in FIG. 64 (f), a cut-in image or the like suggesting the jackpot determination result is displayed (g), and finally the effect symbol 35 is stopped and displayed in the jackpot mode or the lost mode. (H).

In the reach effect with the winning branch effect as shown in FIGS. 63 and 64, in the gaming machine of the present embodiment, a specific effect sound (for example, BGM) should not be played during the winning branch effect (e, f). Yes.
The button effect (win-branch effect) suggests the result of the fluctuation result, which is a major concern for the player, by a cut-in image etc. following the button operation. By making the BGM in the meantime silent, It can give people a sense of tension and enhance the fun of the game.

FIG. 65 is a timing chart (No. 1) showing an audio output mode in the winning branch effect of the present embodiment.
The numbers in parentheses indicate the sound numbers of the production sounds.
As the fluctuation starts at the timing t1, the host CPU 151 controls the audio control circuit 300 to start the output of the non-reach BGM (13), and uses the audio channel different from the BGM (13) for the effect design 35. The fluctuating sound, stop sound (52), etc. are superimposed and reproduced.
At the timing t2 when the reach production starts, the host CPU 151 controls the audio control circuit 300 (production sound stop command), stops the non-reach BGM (13), and selects the same audio channel or another audio channel. Used to reproduce and output the in-reach BGM (14).
At the timing t3 when the button effect (win / branch effect) is performed after the lapse of the predetermined period, the host CPU 151 controls the audio control circuit 300 (effect sound pause command) to temporarily stop the BGM during reach (14).

Since it is difficult to reproduce the audio data from the middle, the audio channel that has output the BGM (14) during the reach to resume the BGM during the reach later will be used for the BGM (14) during the current branching production. Will remain occupied.
After that, when the player operates the effect button 8 at the timing t4 within the operation effective period of the effect button 8 (timing t3 to timing t5), the host CPU 151 controls another audio channel (effect sound output). Command), the button pressing sound (31) is reproduced and output, and the audio control circuit 300 is controlled so that the stopped BGM output is resumed on the same audio channel (effect sound output command).
The operation of the effect button 8 is a return condition for the paused BGM.
It may be considered that the reach BGM is stopped until the return condition is satisfied by the operation of the effect button 8.
When a specific sound (BGM during reach) is output as the game progresses, the output of the BGM during reach is stopped until a predetermined return condition (button operation) is satisfied.
During the winning branch effect, the reach BGM (14) is muted instead of being paused (volume value reset command), and the volume value is returned again when the button is pressed (volume value reset command). The reach BGM (14) may be restarted. In this case, the player cannot listen to the BGM until the effect button 8 is operated, but an effect different from the case of temporarily stopping can be obtained.

Note that the same reach BGM (14) is used regardless of whether the jackpot determination result is a big hit or a loss, but in the case of a big win after pressing the effect button 8, Reach BGM for losing (both not shown in the table of FIG. 52) may be reproduced and output.
When the effect button 8 is not operated within the operation valid period, the host CPU 151 controls the audio control circuit 300 to resume the reproduction output of the reaching BGM (14) from the timing t5 (effect sound output). command).

Note that in the gaming machine of the present embodiment, at the end of one game (the elapse of the symbol determination time), the BGM is stopped (production sound stop command), and the next game based on hold or next winning (next variation) BGM is started again with the start of (effect sound output command).
That is, the background sound (BGM) is stopped during the period between changes from the determination of the symbol to the start of the next change.
In this case, the start of the next fluctuation is the return condition for the stopped BGM (by symbol confirmation).

FIG. 66 is a timing diagram (part 2) illustrating the sound output mode in the winning branch effect of the present embodiment.
As a modification in the case shown in FIG. 65, the fluctuating effect is started at timing t <b> 11, the reach effect is started at timing t <b> 12, and then the BGM during reach is paused during the winning branch effect started at timing t <b> 13. In addition, as shown in FIG. 66, the delay sound (41) is output using a sound channel different from the sound channel for which the BGM (14) being reached was played (production sound output command).

Then, at the timing (t14) when the player operates the effect button 8, the button pressing sound (31) is reproduced and output, and the delay sound (41) is controlled by controlling the audio channel that has output the delay sound. finish.
At the same time, the audio channel in which the in-reach BGM (14) is stopped is controlled (effect sound output command), and the reproduction of the in-reach BGM (14) is resumed.
By doing in this way, the player can operate the production button 8 with more tension.

If the effect button 8 is not operated by the timing t15 which is the end timing of the operation effective period of the effect button 8, the host CPU 151 plays the delay sound (41) until the timing t15 and reaches from the timing t15. The audio control circuit 300 is controlled to resume the reproduction of the middle BGM (14).
When a specific sound (BGM) is output as the game progresses, if the condition for stopping this is satisfied (start of winning branch effect), the output of BGM is stopped while (effect sound stop command) , BGM outputs a sound with a specific effect (production sound output command).

FIG. 67 is a timing diagram (part 3) illustrating the sound output mode in the winning branch effect of the present embodiment.
As a modified example in the case shown in FIG. 65, after the fluctuating effect is started at timing t21, the reach effect is started at timing t22, and then the BGM during reach is paused during the winning branch effect started at timing t23. In addition, as shown in FIG. 67, a delay sound is output using the audio channel that was playing the BGM during reach.
That is, the reach BGM (16) in which the delay sound is previously incorporated is used as the reach BGM.
Specifically, the reach BGM (16) in which the delay sound is incorporated in advance is BGM data that has been adjusted so that the sound is delayed at the timing of the start of the button effect.
Further, a delay may be applied to the in-reach BGM (14) by sound processing from the timing of starting the button effect.

Then, at the timing (t24) when the player operates the effect button 8, the button press sound (31) is reproduced and output, and the audio channel that has output the delay sound is controlled (effect sound stop command). End BGM (16) during reach with delay.
At the same time, the audio channel in which the in-reach BGM (14) is stopped is controlled (effect sound output command), and the reproduction of the in-reach BGM (14) is resumed.

If the effect button 8 is not operated by timing t25, which is the end timing of the operation effective period of the effect button 8, the host CPU 151 reproduces the reaching BGM (16) until timing t25, and from the timing t25. The voice control circuit 300 is controlled to resume the reproduction of the BGM (14) during reach.
When a specific sound (BGM) is output as the game progresses, a sound having a specific effect is output to the BGM at a predetermined timing.

FIG. 68 is a timing diagram (part 4) illustrating the sound output mode in the winning branch effect of the present embodiment.
As a modification of the case shown in FIG. 65, when the effect button 8 is operated during the winning branch effect started at the timing t33 after the change effect is started at the timing t31 and the reach effect is started at the timing t32. From the start of the reach effect to the start of the hit branch effect, the part other than the rust part is played and the start of the win effect is performed so that a specific part (for example, the most exciting rust part) in the reach BGM is played. To the button operation timing.

That is, from the start of the reach effect, playback of the non-corresponding BGM (18) is started (effect sound output command).
Reached BGM non-rust (18) is audio data in which a specific part (for example, rust) of music is deleted.
For example, in the case of music composed of intro → A melody → B melody → rust, at least the rust portion is deleted.
However, in order to prevent an unnatural performance, it is necessary to adjust the playback time to an appropriate playback time, such as using only the B melody, in accordance with the time from the start of the reach production to the button production (winning production). There is.
Then, at the timing t33 when the branch BGM non-rust (18) is being reproduced and output while the reach BGM non-rust (18) is being reproduced and output, the audio channel that is playing the reach-less BGM non-rust (18) is controlled (production sound stop). Command) Stop BGM (14) during reach.
The reaching BGM non-rust (18) may be repeatedly reproduced and output until the time t33 at which the winning branch effect is started.
In the voice control circuit of the present embodiment, it is possible to issue an instruction to make a reservation so that a plurality of the same voices are reproduced continuously.

Then (when the jackpot determination result is a jackpot), at the timing (t34) when the player operates the effect button 8, the playback output of the in-reach BGM rust (17) including only the rust portion is started (effect). Sound output command).
By doing in this way, in the branching production, the climax performance of the climax is started at the time of the big hit, so the player can feel a very strong uplifting feeling.
When the big hit determination result is a loss, a BGM for loss that is not shown in FIG. 52 may be reproduced.
Reaching BGM (17) and Reaching BGM non-rust (18) are not prepared, but Reaching BGM (14) is reproduced and output, and it is temporarily stopped from the start of the winning branch effect until the button operation. Good.
In the period from the start timing t33 of the button effect to the button operation timing t34, the reach-less BGM non-rust (18) is not stopped, and the reach BGM chorus (17) is switched at the operation timing of the effect button 8. good.
If the effect button 8 is not operated by timing t35, which is the end timing of the operation effective period of the effect button 8, the host CPU 151 is silent until timing t35, and the BGM during reach including only the rust portion from timing t35. The audio control circuit 300 is controlled to start the reproduction of (17).
As described above, the host CPU 151 (voice control unit 301) determines the BGM (specific voice output as the game progresses) with the establishment of the specific condition (the operation of the effect button 8 and the end of the operation valid period). Output from a specific part (rust).

<Voice control during jackpot games>
FIG. 69 is a diagram for explaining the output mode of the effect sound during the jackpot game in the present embodiment.
(A) shows a case where the number of rounds is long, for example, 16R jackpot, and (b) shows a case where the number of rounds is short, for example, 5R jackpot.

  When the same background sound consisting of “A melody”, “B melody”, and “rust” is reproduced and output in the long hit of (a), in the long jackpot of 16 rounds, it is the part that the player wants to hear most. It is thought that there is, and can be played through to “rust”. Depending on the song, the “rust” portion may be repeated twice.

On the other hand, in the case of short hit (5R big hit), as is clear from (b), the music is not reproduced up to the “rust” portion, and the player cannot listen to the most desired portion.
Therefore, in the gaming machine of this embodiment, as shown in (c), in the case of 5R jackpot, only the rust portion (specific portion) of the jackpot effect sound (predetermined sound) is repeatedly reproduced and output. To.

As a method, as shown in the voice management table of FIG. 52, BGM for A melody (sound number 21), BGM for B melody (sound number 22), BGM for rust (sound number 23) ), And in the short hit (5R big hit), the BGM for rust (sound number 23) is continuously input to the audio channel.
Further, in the case of long hit (16R big hit), the effect sound data is input to the audio channel in the order of sound number 21 → sound number 22 → sound number 23.

In the voice control circuit according to the present embodiment, it is possible to instruct the voice control unit 301 to make a reservation so that different sound data are continuously reproduced.
By doing in this way, even if the reproducible time of the effect sound is short and the hit is short, it is possible to reliably reproduce and output the part that the player wants to listen to most (the player wants to listen) in the effect sound. Of course, the A melody and the B melody may be used as one audio data, or full chorus audio data including all the background sounds of the jackpot and rust audio data may be prepared.
That is, data for one song including all of A melody, B melody, and chorus may be prepared and played for 16 rounds.
This is because, as long as it is a long hit, even such data can be reproduced up to “rust” at least once.
The jackpot game includes an opening (OP), a round, an interval (not shown) between rounds, and an ending (ED).
The jackpot BGM is reproduced and output during the round and during the interval.
During the ending, a sound effect such as “See you again!” And a notification sound (sound effect) related to the next game are output.
For example, when shifting to the probability change mode after the big hit this time, a sound effect such as “probability change mode entered!” As described below is output.

<Background sound volume control during SE playback>
FIG. 70 is a diagram illustrating the timing of the background sound and the sound effect (SE) when the effect mode is switched.
In the gaming machine according to the present embodiment, a sound effect for notifying the player of the effect mode is reproduced when the effect mode is changed (for example, after a small hit) or when the probability change mode is entered after a big hit.
The sound effect referred to here is a sound for clearly indicating a mode change (such as transition to probability change mode) such as “XX mode entry!”.
Therefore, this sound effect is an important voice for the player when shifting to the probability change mode after the jackpot, and the player needs to be able to hear as much as possible.
Note that the sound to be clearly notified to the player is not limited to the sound effect indicating the transition to the probability change mode, but also when the game state transitions, or the zone entry sound with high jackpot reliability.
However, since the sound effect is played over the background sound that is being played while the special symbol is changing, the sound effect may be difficult for the player to hear when the volume of the background sound is high.
Therefore, in the gaming machine of this embodiment, when the background sound and the sound effect overlap, the sound effect is emphasized by lowering the volume of the BGM.

FIG. 71 is a diagram (part 1) illustrating the volume control of the BGM when the background sound and the sound effect overlap.
As is clear from FIG. 71, the background sound that has been played at a constant volume from the start of the fluctuation is reduced in volume during the mode transition effect, and the mode entry SE occurs almost simultaneously, and the mode entry SE ends after the mode transition effect. At the same time, the volume of the background sound is restored.
Thereby, the sound effect is emphasized, and the player can clearly recognize that the effect mode has been switched.

FIG. 72 is a diagram (part 2) illustrating the volume control of the BGM when the background sound and the sound effect overlap.
If the volume of the background sound is changed suddenly (suddenly) as shown in FIG. 71, the music will inevitably have a “cut-out interval”, giving the player a sense of incongruity.
Therefore, in order to suppress such a sense of incongruity, when the volume of the sound effect is changed, the feeling of cuts is avoided by fading in or fading out over several frames before and after the start and end timing.

  In order to realize the volume control as shown in FIGS. 71 and 72, as described in steps S1404 and S1405 in the flowchart of FIG. A volume value reset command for instructing adjustment may be input to the voice control circuit 300.

In addition, when BGM changes at the time of transition to probability variation mode or rushing into a zone with high jackpot reliability (transition), the volume of BGM (11) played at a constant volume from the start of variation can be reduced at the time of mode transition production. The mode entry SE occurs almost simultaneously, the mode entry SE ends after the mode transition effect, and the output of BGM (11 ′) after the mode transition, for example, is started at the volume before the mode transition effect.
Thereby, the sound effect is emphasized, and the player can clearly recognize that the effect mode has been switched.

  Further, the volume and timing of the effect sound (background sound in this case) may be specified in advance in the effect sound output command, or the sound data of the effect sound may be specified in advance at a predetermined timing ( It may be created in advance as sound data to be faded in and out before and after SE.

<Notice effect (example of inputting the same type of sound to the same audio channel)
In the production of the game machine, a large number of voices are often generated simultaneously during the notice production that suggests the possibility of jackpot (expectation) during the reach production. In that case, it is strongly required to efficiently use a limited number of audio channels of the audio control circuit 300.

First, an outline of the notice effect executed in the gaming machine of this embodiment will be outlined.
In the gaming machine of the present embodiment, the sub CPU 121 of the effect control board 120 selects the change effect pattern based on the change pattern command transmitted from the main control board 110, but on the other hand, the advance notice is provided separately from the change effect pattern. The presence / absence of execution of the effect and the type of the notice effect to be executed are selected.
The notice effect is an effect that informs the player that the jackpot has been confirmed and the expectation level is high during reach, etc. The selection of the notice effect including the presence or absence of the execution is a random number for the effect to select the variable effect pattern. This is done using a random number value (notice random number value) different from.

FIG. 73 is a diagram showing a notice effect determination table used when the CPU of the effect control board in the present embodiment selects a notice effect.
In FIG. 73, the variation effect pattern 1 is a variation effect pattern that shifts from normal variation to normal reach A1, C1 (winning), as shown in FIGS. The normal fluctuation is an effect accompanied by a normal fluctuation that is not accompanied by a pseudo-ream described later, a blackout effect, or the like.
The normal reach is a variation mode in which the central symbol continues to fluctuate while stopping in a state where the left and right effect symbols (decoration symbols) are aligned, and as a result, the variation stops in a big hit or lost manner.

When variation effect pattern 1 is selected from the variation effect pattern selection table of FIG. 36 and FIG. 37, if the obtained preliminary announcement random number value is between 0 and 100, the jackpot is confirmed during reach effect or at the start of reach effect. “Confirmed production” is performed. This finalized effect is an effect that can be selected only when a jackpot is won in the jackpot lottery.
In the case of the following variation effect pattern 10 (losing), it is not selected.
It is often performed using a specific full-screen cut-in image, and may be performed using the light emission of an accessory and the accompanying loud sound of a warning sound.

Further, if the acquired random number for the preliminary announcement is any of 101 to 150, a highly anticipated “group advance” is performed during the reach presentation or at the start of the reach presentation. This is a flashy production where a large group of small characters run through the screen, but it does not mean that the jackpot is confirmed.
However, in the case of the variation effect pattern 1 (winning), since the probability that this group notice is selected is much higher than that in the case of the variation effect pattern 10 (losing) shown below, this effect is displayed. At that time, it can be said that the expectation to the jackpot is high.

Also, if the acquired notice random number value is any one of 151 to 200, a highly anticipated “character notice” is performed during reach production. In this case, it is a relatively sober production in which a specific character is simply displayed on the screen, and does not mean that the jackpot is confirmed.
However, since the probability of selecting this “character notice” is higher in the case of the variation effect pattern 1 (win) than in the case of the change effect pattern 10 (losing) shown below, it is not as much as the above group notice. However, it can be said that the expectation to the jackpot is high when this effect is displayed.

  If the acquired notice random number value is any of 201 to 255, no notice effect is performed.

As shown in FIGS. 36 and 37, the variation effect pattern 10 is a variation effect pattern that shifts from normal variation to normal reach A1, C1 (loss).
When the variation effect pattern 10 is selected, if the acquired notice random number value is 0 to 20, a high expectation group notice is performed during the reach effect or at the start of the reach effect.
If the acquired random number for the notice is 21 to 50, the character expectation with high expectation is performed during the reach production.
If the acquired random number value is any one of 51 to 255, no notice effect is performed.
Since the variation effect pattern 10 is selected when the jackpot determination result is lost, a definite effect (full screen cut-in or the like) cannot be performed.

In FIG. 73, the variation effect pattern 3 is a variation effect pattern that shifts from pseudo continuous variation (pseudo-continuous) to reach B <b> 1 and D <b> 1 (winning), as shown in FIGS. 36 and 37.
Reach B1 and D1 (hits) are the reach that continues from the pseudo continuous fluctuation.
The pseudo-ream is an effect in which a pseudo-variation that changes again after two to three decorative symbols are temporarily stopped is performed twice during one change. Such pseudo-variation can gradually increase the jackpot expectation felt by the player.

When Fluctuation Effect Pattern 3 is selected, if the acquired notice random number is between 0 and 100, a full-screen cut-in that means a big hit is confirmed during reach effect or when transitioning from pseudo-ream to reach effect, etc. The finalized production is performed.
Moreover, if the acquired notice random number value is any of 101 to 200, a group notice with high expectation is performed during reach production or at the start of reach production. This is a flashy production where a large group of small characters run through the screen, but it does not mean that the jackpot is confirmed.
However, in the case of the variation effect pattern 1 (winning), since the probability that this group notice is selected is much higher than that in the case of the variation effect pattern 10 (losing) shown below, this effect is displayed. At that time, it can be said that the expectation to the jackpot is high.
Further, if the acquired notice random number value is any of 201 to 255, the notice effect is not performed.

In FIG. 73, the variation effect pattern 12 is a variation effect pattern that shifts from pseudo continuous variation (pseudo-continuous) to reach B <b> 1 and D <b> 1 (loss), as shown in FIGS. 36 and 37.
Reach B1 and D1 (losing) is a reach that continues from pseudo-continuous fluctuation.
When the variation effect pattern 6 is selected from the variation effect pattern determination table of FIG. 36 and FIG. 37, if the acquired notice random number value is any one of 0 to 100, a highly anticipated character notice is given during the reach effect. Although it will be done, eventually it will be lost.

In FIG. 73, as shown in FIG. 36 and FIG. 37, the reach A1 that performs normal reach variation, the C1 (hit, lose) effect, and the reach B1 that performs pseudo-ream, as the variation effect pattern that may perform the notice effect. D1 (winning / losing) is illustrated.
This is merely an example, and a notice effect may be performed in the case of the reach A2 or C2 that performs normal reach fluctuation, or the reach B2 or D2 that performs pseudo-ream.
However, the design effect without the reach effect (variation effect pattern 5), the chance effect (variation effect patterns 6, 7, 8), the normal change effect (variation effect pattern 9), and the shortened change effect (variation effect patterns 14, 15). ), It is difficult to generate a notice effect such as a confirmed notice effect, a group notice, or a character notice, so it is excluded from the table of FIG.

74 and 75 are diagrams showing examples of effects selected and executed using the variable effect determination table shown in FIGS. 36 and 37 and the notice effect determination table shown in FIG. 48 in the gaming machine of the present invention. .
74 shows a case where the variation effect pattern 1 is selected in the variation effect pattern table of FIGS. 36 and 37 (the jackpot determination result is a jackpot), and the notice effect No. The transition of effect display when one confirmed effect is selected is shown.

Along with the start of the special symbol variation, the image display device 31 starts the variation display (b) of the effect symbol 35 in the stop mode (a).
Thereafter, for example, a full-screen cut-in (for example, a rainbow pattern) indicating the jackpot decision is displayed at the timing (c) at the time of reach transition.
After that, the effect design 35 becomes the reach mode (d), and after the reach effect (e) is performed, the effect design 35 stops in the jackpot mode (f) and becomes a jackpot.

  FIG. 75 shows that the variation effect pattern 1 (the jackpot determination result is a jackpot) or the variation effect pattern 10 (the jackpot determination result is lost) is selected in the variation effect pattern table of FIGS. 36 and 37, and the notice effect No. . The transition of the effect display when the second group notice effect is selected is shown.

With the start of variation of the special symbol, the effect symbol 35 in the stop mode (a) starts the variation display (b) in the image display device 31.
Thereafter, for example, when the production symbol 35 is in the reach mode (c), a group notice (d) with a high expectation degree of jackpot is generated.
As described above, since the group notice can be selected in both cases of jackpot and loss, the jackpot is not fixed at this point although the probability (expectedness) is high.
Thereafter, after the reach effect (e) is performed, the effect symbol 35 stops in the jackpot mode (f) or the lost mode (g), and the jackpot or the lost game is determined.

  Depending on the content (type) of the jackpot decision or high expectation notice effect that is performed during such a variation effect, the player can predict whether the current variation effect will be a jackpot, It has become one of the fun of games.

In particular, in the notice effect called group notice, many voices of characters constituting the group are generated.
The voices of the characters are different from each other, and are managed as sound numbers 52 to 69 as the sound for the notice effect in the sound management table (FIG. 52).
When the group notice characters running through the screen utter a voice with a time difference, when the notice effect sound is input to the sound channel, the sound channel included in the sound control circuit 300 is quickly exhausted.

Unlike the case where the effect button 8 is repeatedly hit, the sounds produced by the group notice characters are different, but in the gaming machine of the present embodiment, the effect sounds of the sound numbers 61 to 69 are related (similar to each other). Yes) It is treated as a group of voices (groups) and is input continuously to the same voice channel as virtually the same sound.
The host CPU 151 outputs the same sound (sound based on the first sound information) as the currently output sound (sound based on the first sound information) or similar sound (sound based on the second sound information). In the case of output, output is performed using an audio channel that outputs audio based on the first audio information (new first audio information and second audio information are converted to the first audio information at present). Set to the audio channel that is outputting the audio based on.)

In one audio channel, only one audio can be input at the same time, and it is overwritten by the audio input later, but when a large amount of audio is input continuously with a time difference, the player feels so uncomfortable. There is nothing.
Rather, by assigning the same sound number to sound data of different contents, it is possible to input to the same sound channel, and a limited number of sound channels can be used very efficiently.
Also, since only one sound can be output at a time on one sound channel, sound data having different contents do not overlap each other.

In order to handle effect sounds having different sound numbers as one group, the sound numbers may be configured by two pieces of information, that is, information for specifying a group and information for specifying a sound.
In this way, the audio control unit 301 of the audio control circuit 300 can easily determine whether the input audio belongs to a group (which should be input to the same audio channel) or not. I can do it.
On the other hand, even if the sound has the same content, it is possible to achieve an unparalleled sound effect by assigning different sound numbers to input to multiple sound channels simultaneously or with a time difference. It is.

<Winning sound during round game>
FIG. 76 is a diagram for explaining a winning sound generated during a round game in the gaming machine according to the present embodiment.
Note that. FIG. 76 shows winning sounds generated during an unspecified round game in the jackpot game excluding the 2R jackpot (short win).
The prescribed number of winnings per round is nine (see FIG. 11). That is, when 10 or more prizes are won in one round, it becomes “over prize”.

As shown in FIG. 76, in the jackpot game, when the opening period or the interval period (a) from the previous round ends, the round game is started (b).
During a round game, when one game ball wins in the big winning openings 16 and 17, a notification sound “do” is generated to notify the player.
As shown in FIG. 52, in the voice management table, a different notification sound is set for each winning number, and if winning continues during a round game, “De les mi fa so la la de do”・ ”Is a musical scale.

For example, if the winning number is the first, the winning sound 1 (pronounced “do”) with the sound number 91 is pronounced, and if the winning number is the second, the winning sound 2 (sounding is “le”) with the sound number 92 is pronounced. If the number is 3rd, the winning sound 3 (pronounced “Mi”) with the sound number 93 is sounded, and if the number is 4th, the winning sound 4 (pronounced “Fah”) with the sound number 94 is sounded. Is done.
Of course, there may be only one winning sound, and the same winning sound may be generated for each winning.

When the second game ball wins, a notification sound 2 of “L” is generated (d), and after that, when a winning is generated one after another and the ninth winning is generated, one octave higher than in the case of (d) A notification sound 9 of “Le” is generated (e).
At this point, the specified number of winnings for the round game has been reached.

  After this, when the game ball further wins the grand prize opening, the notification sound 10 “mi” for notifying the tenth winning is not generated, and the player is informed that the over-winning exceeds the prescribed number (9). Over-notification sound (Fig. 52: Sound number 110) is pronounced to inform and congratulate (the player will be more than happy to win more prizes and get more prize balls. (F).

Thereafter, when a prize is further entered into the big prize opening, this is also an over-winning (g) because it is naturally more than the prescribed number (11).
However, in this case, no over winning notification sound is generated. The over-winning notification sound is generated only for the first one that is over-winning. Although it is a joy to the players, it may be possible that some players will feel annoyed when the notification sound is repeated many times.
Further, the notification sound 11 “Fa” for notifying the eleventh prize is not generated.

The round game ends with the arrival of the prescribed number of winnings, and shifts to the interval period (h).
In the next round game or the next jackpot game, a winning notification sound is similarly generated, but the winning count is naturally reset for each round.

FIG. 77 is a flowchart for describing a winning notification process during a round game by the image control board.
In step S2101, the host CPU 151 determines whether or not the jackpot game is currently being played.

If it is determined that the round game has not yet started (in the first place, it is not a big hit game, or even during the big hit game, during the opening or during the interval) (No in step S2101), the winning notification process is ended as it is. .
If it is determined that the round game has started (Yes in step S2101), the host CPU 151 initializes the winning number count value N (substitutes 0) in step S2102.

The host CPU 151 waits for the occurrence of a winning game ball to the big winning opening and the end of the opening time.
In step S <b> 2103, the host CPU 151 determines whether or not a game ball has been won at the big winning opening.

If it is determined that a winning has occurred (Yes in step S2103), the host CPU 151 adds 1 to the winning count value N (N ← N + 1) in step S2104.
If it is determined that no winning occurs (No in step S2103), the host CPU 151 ends the current jackpot winning notification process.

  In step S2105, the host CPU 151 determines whether or not the winning number count value N is equal to or greater than a specified number (for example, 9).

When it is determined that the winning number count value N is less than the prescribed number (9) (No in step S2105), the host CPU 151 reproduces and outputs the winning sound corresponding to the Nth in the voice management table in step S2108. An effect sound output command is transmitted to the sound control circuit 300. For example, when the value of the winning number count value N is 1 (when the winning number of the round game is 1), the winning sound 1 of the sound number 91 (the pronunciation is “do”) is designated.
If the value of the winning number count value N is 2 (when the winning number of the round is 2), the winning sound 2 (pronounced “re”) of the sound number 92 is designated.

In this way, in the gaming machine of the present embodiment, when game balls win one after another in a single round game, the number of winnings (the value of the winning number count value N) increases, and at the same time, “Doremifaso ・・ It is configured to be a melody.
Of course, it is needless to say that such a production is only an example. That is, only one winning sound may be prepared and the number of winnings may be counted, but the same winning sound may be generated for each winning without changing the sound according to the number.

Note that the host CPU 151 instructs the sound control circuit 300 to input different sound effects for each winning number to the sound channel as a series of related sounds.
As a result, exhaustion of a limited number of audio channels can be prevented, and a problem in which the notification sounds are overlapped due to the input of the winning notification sounds to different audio channels with a time difference and can be suppressed from being heard from each other.

If it is determined that the winning number count value is greater than or equal to the specified number (Yes in step S2105), it is determined whether or not the winning number count value N is a value that is one more than the specified number (for example, 9).
When the winning number count value N is one more than a predetermined number (for example, 9) (Yes in step S2106), the host CPU 151 notifies the over winning prize having the content such as “Yes!” In step S2107. An effect sound output command for reproducing and outputting the sound (FIG. 52: sound number 110) is transmitted to the sound control circuit 300.
The winning sound corresponding to the winning number count value N is not reproduced and output.

In step S2106, the host CPU 151 determines that the winning number count value N is not a value that is one more than the specified number (for example, 9) (the count value N is two or more than the specified number) (No in step S2106). The over-winning notification sound and the winning sound corresponding to the count value N are not generated, and the jackpot winning notification process is terminated.

<Notification process at the start of reach production>
By the way, in the gaming machine of this embodiment, in a specific production mode, at the start of the reach production, for example, a production sound such as “reach!” Is output (reach notification production sound), and the player has shifted to reach. Is informed.
However, if the “reach notification effect sound” is reproduced and output at the timing when the BGM switches from the pre-reach BGM to the in-reach BGM at the start of the reach effect, the “reach notification effect sound” is covered by the “reach BGM” and heard. It becomes difficult.
Therefore, in the gaming machine of this embodiment, the “reach notification effect sound” is reproduced and output in the following manner so that the reach notification effect sound is not covered by the BGM during reach.

FIG. 78 is a diagram showing a transition of the effect display accompanied with the reach notification effect in the present embodiment.
With the start of variation of the special symbol, the effect symbol 35 in the stop mode (a) in the image display device 31 starts variation display (b). In addition, the non-reach (before reach) BGM is reproduced and output.
Thereafter, when the production symbol 35 is in the reach mode (c), the non-reach BGM is stopped, and a reach notification production sound of “reach!” For informing the player that the reach has been reached is reproduced and output.

In the present embodiment, after the reproduction of the reach notification effect sound is completed, the in-reach BGM is reproduced and output at a timing when a predetermined period has elapsed from the start of the reach effect.
Thereafter, after reaching the reach effect (e), if the jackpot determination result is “hit”, the effect symbol 35 is stopped and displayed in the jackpot mode (f), and if the jackpot determination result is “lost”, the effect symbol 35 is The display is stopped in the lost mode (g).
By doing in this way, since the reach notification effect sound does not cover the reach BGM, the player can surely hear the reach notification effect sound.

By the way, the gaming machine of this embodiment has a plurality of production modes even for the same variation pattern, and the characters that are the motifs of the production differ in each production mode, and accordingly, BGM (especially BGM before reach). And background images are different.
The “effect mode” is, for example, a mode in which background images, BGM, variation effect options, and the like are different, and can be appropriately shifted in order to eliminate the monotony of the game during the game.

  The “reach notification effect sound” is also different for each effect mode, and is typically a sound using the voice of the character that is the motif of each effect mode.

Because the playback time of the “reach notification effect sound” varies depending on the effect mode due to the difference in the voice of the character and the BGM during reach is constant regardless of the effect mode, the reach is immediately after the output of the “reach notification effect sound”. When the BGM is reproduced and output, the “reach notification effect sound” and the BGM during reach are not incurred, but the end time of the BGM during reach within a certain fluctuation time varies, which is unnatural.
If different lengths of “BGM during reach” are prepared for each production mode in order to prevent this, the data capacity increases and the processing becomes complicated.

  Therefore, in the present embodiment, after outputting the “reach notification effect sound”, such a problem is solved by making the start timing of “BGM during reach” constant in all effect modes.

In the gaming machine of the present embodiment, it is assumed that first to third effect modes are prepared.
For example, in the case of the variation patterns 1 and 8 (per reach A, reach A lose) designated by the variation pattern designation command, the reach before reach BGM using three different characters as the motif or reach according to each production mode An effect using the notification effect sound (“reach!”) Is performed.

  Of course, in the present embodiment, not only the variation patterns 1 and 8, but also the variation patterns 2 and 9 and the variation patterns 21, 22, 28, and 29 such as the probability variation gaming state are included in the effect mode. It is possible to produce similar productions.

Further, the variation effect pattern determination table for determining the effect pattern is one in which, for example, one of a plurality of variation effect pattern determination tables is referred to according to the gaming state and the effect mode. Therefore, the variation effect pattern determination tables shown in FIGS. 36 and 37 are also tables based on one effect mode.
Therefore, the effects by the variation effect patterns (1, 2, 10, 11) of FIGS. 36 and 37 corresponding to the change patterns 1 and 8 are also included in any of the effects by the first to third effect modes. However, in the following, the effects in the first to third effect modes will be described as effect patterns different from the variation effect patterns in FIGS.

  In the case of the fluctuation pattern 1 (8), the production contents in the first production mode are the reach A1 ′ production, the production content in the second production mode is the reach A1 ″ production, and the production content in the third production mode is the reach A1 ′ ″. Think of it as a production.

  In the first effect mode (reach A1 ′ effect), BGM (during non-reach) -A1 (FIG. 52: sound number 120) is used before the reach effect starts, and reach notification effect sound 1 (FIG. 52: sound) at the start of the reach effect. No. 130) is reproduced, and the common BGM (during reach) -A (FIG. 52: note number 123) common to each effect mode is output.

In the second effect mode (reach A1 ″ effect), BGM (during non-reach) −A2 (FIG. 52: sound number 121) is used before the start of reach effect, and reach notification effect sound 2 (FIG. 52: FIG. 52: start of reach effect). After reproducing the sound number 131), the common BGM (during reach) -A (FIG. 52: sound number 123) common to each effect mode is output.
In the third effect mode (reach A1 ′ ″ effect), BGM (during non-reach) −A3 (FIG. 52: sound number 122) is used before the start of reach effect, and reach notification effect sound 1 (FIG. 52) at the start of reach effect. : Sound number 132) is reproduced, and common BGM (during reach) -A (FIG. 52: sound number 123) common to each effect mode is output.

FIG. 79 is a timing diagram showing an audio output mode in a specific performance mode in the gaming machine of the present embodiment. The numbers in parentheses indicate the sound numbers of the production sounds.
Along with the start of change (timing t41), the host CPU 151 controls the audio control circuit 300 to start outputting BGM (120, 121, 122) (change effect pattern specified by the effect pattern specification command based on the effect mode). In addition, using the audio channel different from the BGM (120, 121, 122), the fluctuating sound of the effect design 35, the stop sound (52), and the like are reproduced and output.

  At the timing t42 when the reach production starts, the host CPU 151 controls the audio control circuit 300 (production sound stop command) to stop the BGM (120, 121, 122), and the same audio channel or another audio channel. Are used to reproduce and output reach notification effect sounds 1, 2, 3 (130, 131, 132).

  As described above, the non-reach BGM and reach notification effect sound are different for each effect mode. In the case of the first effect mode, BGM-A1 (120), reach notification effect sound 1 (130), and second In the case of the effect mode, BGM-A2 (121) and reach notification effect sound 2 (131) are used, and in the case of the third effect mode, BGM-A3 (122) and reach notification effect sound 3 (132) are used.

When time elapses and the reach BGM start timing t43 starts from the start point of reach production (this timing is common to all production modes), the host CPU 151 controls the audio control circuit 300 (production sound output). Command) and BGM (123) during common reach are reproduced and output.
The length of the sound source of the reach notification effect sound is created in advance so that the reproduction of the reach notification effect sound (130, 131, 132) is completed by this timing.
It can be said that while the reach notification effect sound (first sound) is output, the output of the BGM (second sound) during the common reach is limited.

In this way, the reach notification effect (130, 131, 132) does not overlap with the reaching BGM (123) in any effect mode.
In addition, since the common reach BGM (123) is not reproduced and output following the reach notification effect sound having a different length for each production mode, the end timing of the common reach BGM (123) is different for each production mode. Nor.

As described above, in the gaming machine of the present embodiment, the reach notification effect sound (130, 131, 132) is reproduced and output so as not to overlap with the reaching BGM (123), so that it is important information for the player. A player can be effectively notified of a certain reach shift by voice.
In addition, since the sound (BGM during reach, reach notification effect sound) reproduced and output at the same time is reduced, it is possible to efficiently use a limited number of audio channels.

Furthermore, even if the length of the reach notification effect sound is different for each effect mode, the processing can be simplified by uniquely setting the timing for starting the BGM during reach to a predetermined timing after the start of the reach effect. .
Moreover, in the production including the reach production, the reach notification production sound and the production by the BGM before and after that can be made natural, and the interest of the game can be enhanced.

  In addition, as described above, in the gaming machine of the present embodiment, the fluctuation stop sound is output at the time of temporary stop of the fluctuation display of the effect symbol 35. This is a sound effect for notifying the player that the change in the production symbol (and thus the special symbol) has been temporarily stopped.

FIG. 80 is a diagram showing a stop mode of the effect symbol in the gaming machine of the present embodiment.
Basically, the production symbols 35 (the left symbol 35a, the central symbol 35b, and the right symbol 35c) are temporarily stopped at different timings, and the fluctuation stop sound for each of the production symbols starts to be output at different timings. .
For example, as shown in FIG. 80 (A), in the normal fluctuation (fluctuation pattern 7) without the reach effect in the normal gaming state, the effect symbol 35 is the left symbol 35a (c), the right symbol 35c (d), the center. Temporarily stop in the order of symbol 35c (e).

However, as shown in FIG. 80 (B), at the time of normal fluctuation (fluctuation pattern 27) without a reach effect in the probability variation game state, three effect symbols 35 (left symbol 35a, central symbol 35b, right symbol 35c) are simultaneously displayed. Temporarily stop (c).
Further, at the time of a specific reach production, the left and right symbols 35a and 35c are temporarily stopped simultaneously when the reach is established.

In the gaming machine of the present embodiment, when the variable stop sound (52) is output in accordance with the temporary stop of the left symbol 35a, the left side of the left and right speakers (sound output devices) 34 toward the player. The volume of the speaker is controlled to be larger than the volume of the right speaker.
When the variable stop sound (52) is output in accordance with the temporary stop of the right pattern 35c, the volume of the right speaker toward the player, the volume of the left speaker toward the player, and the volume of the right speaker toward the player Control to be larger than
When the variable stop sound (52) is output in accordance with the temporary stop of the central symbol 35b, the volume of the left and right speakers is controlled to be the same.
As a result, when the effect symbol 35 temporarily stops in the order of left → right → center, the player can enjoy a three-dimensional sound with respect to the change stop sound of the effect symbol.

  Hereinafter, in the gaming machine of the present embodiment, an audio output process and an output mode in the case where a plurality of change stop sounds are generated simultaneously by temporarily stopping a plurality of effect symbols 35 under specific conditions will be described.

FIG. 81 is a timing diagram showing an example of an output mode of a change stop sound when a plurality of effect symbols temporarily stop changing at the same time during normal change in the probability variation gaming state. The numbers in parentheses indicate the sound numbers of the production sounds.
When the change starts, the host CPU 151 controls the audio control circuit 300 (effect sound output command) to output the change start sound, and uses the audio channel different from the change start sound for the normal change BGM (15). Start output. Further, the host CPU 151 reproduces and outputs the fluctuating sound or the like of the effect design 35 using another audio channel.

When the fluctuation stop timing comes, the host CPU 151 controls the voice control circuit 300 (effect sound output command) to generate different (different data) fluctuation stop sounds for the left symbol 35a, the central symbol 35b, and the right symbol 35c. Let
In this case, since the three variable channels are used for the fluctuation stop sound of the three symbols of the left symbol 35a, the central symbol 35b, and the right symbol 35c, it can be said that the voice channel can be used efficiently. Absent.

This is because even if the fluctuation stop sound has the same content, if the voice is different (different data), the fluctuation start sound having the same content is input to a different audio channel.
Even when the variable stop sound of each effect design is the same data (unlike this embodiment described below), when the control is made to input the variable stop sound to a different audio channel for each effect design. A similar problem occurs.

  Therefore, in the present embodiment, a plurality of fluctuation stop sounds are generated using the audio channel more efficiently.

FIG. 82 is a timing diagram showing an output mode of a change stop sound when a plurality of effect symbols temporarily stop changing at the same time in the gaming machine of the present embodiment. The numbers in parentheses indicate the sound numbers of the production sounds.
During normal variation (variation pattern 9) in the probability variation gaming state, the three effect symbols 35 (left symbol 35a, central symbol 35b, right symbol 35c) are temporarily stopped simultaneously.

  When the change starts, the host CPU 151 controls the sound control circuit 300 (effect sound output command) to output the change start sound (51), and uses the normal change BGM (using a sound channel different from the change start sound). The output of 15) is started. Further, the host CPU 151 reproduces and outputs the fluctuating sound or the like of the effect design 35 using another audio channel.

When the fluctuation stop timing is reached, the host CPU 151 controls the voice control circuit 300 (effect sound output command) to continuously input the change stop sound (52) for the three effect symbols in one audio channel.
As described above with respect to the direct sound of the effect button, in the gaming machine of the present embodiment, the same sound number is assigned to the same sound, and the sound having the same sound number is continuously reproduced and output. The same audio channel is continuously input.
As a result, a limited number of audio channels included in the audio control circuit 300 can be used efficiently.

  The same applies to the variable stop sound (52). The three stop patterns 35 (35a, 35b, 35c) have the same variable stop sound, and the same variable stop sound (52) is set for each.

  As a result, the variable stop sound (52) for the three effect symbols 35 is input to the same variable channel with a slight time difference, and as a result, a variable stop sound that can be heard as one sound is output.

That is, a plurality of variable stop sounds (52) based on the same data are input to the same audio channel and overwritten (while the output of the previously input variable stop sounds is stopped).
By inputting the same variable stop sound (52) to the same variable channel, only one audio channel is required compared to the case where the three variable stop sounds (52) are output using different audio channels. The audio channel can be used more efficiently.
Only the variable stop sound related to one effect symbol (the last input middle symbol 35b) may be output by continuously inputting the variable stop sounds for the three effect symbols.

As described above, even if the change start sound has the same content, if the sound is different (different data), the change start sound having the same content is input to different audio channels as in FIG.
As a result, it is conceivable that the player can hear the sound muffled, but such inconvenience can be solved by doing as described above.

  As described above, in the present embodiment, when the variable stop sound (52) is output in accordance with the temporary stop of the left symbol 35a, the volume of the left speaker toward the player is When controlling to be higher than the volume of the speaker and outputting the variable stop sound (52) in accordance with the temporary stop of the right pattern 35c, the volume of the right speaker toward the player is When the volume of the speaker is controlled to be larger than the volume of the speaker on the right side, and the variable stop sound (52) is output in accordance with the temporary stop of the central symbol 35b, the volume of the left and right speakers is Control each to be the same.

As shown in FIG. 82, when the variable stop sound (52) for the three effect symbols 35 is input to the same variable channel with a slight time difference, the variable stop sound (52) for the left symbol 35a and the right symbol 35c. The change stop sound (52) for the center and the change stop sound (52) for the central symbol 35c are input in this order.
As a result, what is left in the player's ear is the fluctuation stop sound (52) for the central symbol 35b input last.
Fluctuation stop sound (52) for the middle symbol for the central symbol 35 (b), that is, a fluctuation stop sound controlled so that the volume of the left and right speakers is the same. Can be heard.

Instead of outputting the same three variable stop sounds (52) from the same variable channel (continuously), only one variable stop sound (52) is reproduced and output using one variable channel. You may do it.
This is not a variable stop sound that can be heard as one sound, but literally a single variable stop sound.

In the case of outputting only one change stop sound, a change stop sound for the middle symbol (52), that is, a change stop sound controlled so that the left and right speakers have the same volume is output.
The player can listen to the fluctuation stop sound output in this way in a natural manner.

FIG. 83 is a timing diagram showing an example of an output mode of the fluctuation stop sound when the left and right production symbols are fluctuated and stopped simultaneously during a specific reach production.
The numbers in parentheses indicate the sound numbers of the production sounds.

Along with the start of fluctuation at timing t71, the host CPU 151 controls the voice control circuit 300 (effect sound output command) to output the fluctuation start sound, and uses a non-reaching BGM (using a voice channel different from the fluctuation start sound). The output of 11) or (13) is started.
Further, the host CPU 151 reproduces and outputs the fluctuating sound or the like of the effect design 35 using another audio channel.

When the reach production start timing t72 is reached, the host CPU 151 controls the audio control circuit 300 (production sound stop command) to stop the non-reach BGM (11) or (13), and the left design 35a and the right design. Different variable stop sounds (different audio data) for 35c are output using two different audio channels.
Since the central symbol 35b is continuously displayed with fluctuations, no fluctuation stop sound is output.

After the start of the reach effect, the host CPU 151 controls the sound control circuit 300 (effect sound output command) and outputs the BGM during reach.
In this case, two variable channels are occupied by the fluctuation stop sound for the left symbol 35a and the right symbol 35c, and it cannot be said that the voice channel can be used efficiently.

This is because even if the fluctuation stop sound has the same content, if the voice is different (different data), the fluctuation start sound having the same content is input to a different audio channel.
Even when the variation stop sound of each effect design is the same data, the same problem occurs when the control is performed to input the change stop sound to a different audio channel for each effect design.
Therefore, in the present embodiment, a plurality of fluctuation stop sounds are generated using the audio channel more efficiently.

  FIG. 84 is a timing chart showing a change stop sound output mode when the left and right effect symbols temporarily stop changing at the same time during the reach effect in the gaming machine of the present embodiment. The numbers in parentheses indicate the sound numbers of the production sounds.

  Along with the start of fluctuation at timing t81, the host CPU 151 controls the voice control circuit 300 (effect sound output command) to output the fluctuation start sound (51), and non-reach using a voice channel different from the fluctuation start sound. Starts output of middle BGM. Further, the host CPU 151 reproduces and outputs the fluctuating sound or the like of the effect design 35 using another audio channel.

When the reach production start timing t82 is reached, the host CPU 151 controls the audio control circuit 300 (production sound stop command) to stop the non-reach BGM and generate a variable stop sound (52) for the two production symbols. Input one audio channel continuously.
In the gaming machine of the present embodiment, the same sound number is assigned to the sound having the same content, and when the same sound number is continuously input, the sound is continuously input to the same sound channel. As a result, a limited number of audio channels included in the audio control circuit 300 can be used efficiently.

The same applies to the variable stop sound (52). The variable stop sounds for the two effect symbols 35 (35a, 35c) have the same contents, and the same variable stop sound (52) is set for each of them.
As a result, the fluctuation stop sound (52) for the two effect symbols 35 is input to the same variable channel with a slight time difference, and as a result, the fluctuation stop sound (52) heard as one sound is output.

That is, a plurality of variable stop sounds (52) based on the same data are input to the same audio channel and overwritten (while stopping the output of the previously input variable stop sound).
Since the same variable stop sound (52) is input to the same variable channel, only one audio channel is used compared to the case where two variable stop sounds (52) are output using different audio channels. The audio channel can be used more efficiently.
By continuously inputting the fluctuation stop sound for the two effect symbols, only the change stop sound for one effect symbol (the right symbol 35c input last) may be output.

As described above, even if the change start sound has the same content, if the sound is different (different data), the change start sound having the same content is input to different audio channels as in FIG.
As a result, the player can hear the sound muffled, but such inconvenience can be solved by doing as described above.
Instead of outputting two identical fluctuation stop sounds, only one variable stop sound (53) may be reproduced and output using one variable channel.

The fluctuation stop sound (52) of the effect symbol 35 described above is reproduced and output when the effect symbol 35 is temporarily stopped, and is not output when the effect symbol 35 is confirmed and stopped.
That is, the change stop sound (52) is a change stop sound of the effect design 35, and is not a change stop sound of the special design.

In the above description, the fluctuation stop sound output at the time of temporary stop of the fluctuation of the effect symbol 35 has been described. The same applies to the fluctuation start sound (51) generated at the start of the fluctuation of the effect symbol 35.
Naturally, this variation start sound (51) is merely the variation start sound of the effect symbol 35, and not the variation symbol start sound of the special symbol.

  Further, as described above, when the variable stop sound (52) is output in accordance with the temporary stop of the left symbol 35a, the volume of the left speaker toward the player is larger than the volume of the right speaker toward the player. When controlling to increase and outputting the variable stop sound (52) in accordance with the temporary stop of the right pattern 35c, the volume of the right speaker toward the player, the volume of the left speaker toward the player, When the variable stop sound (52) is output in synchronization with the temporary stop of the central symbol 35b, the volume of the left and right speakers is set to be the same. To control.

  However, when the reach is established, if the left and right symbols stop simultaneously, or if the left symbol 35a → the right symbol 35b temporarily stops with a time lag, the fluctuation stop sound for the middle symbol (52), that is, the volume of the left and right speakers is A variable stop sound controlled to be the same is output.

FIG. 85 is a diagram showing aspects from the stop pattern of the effect symbol to the state immediately after the start of change in the gaming machine of the present embodiment.
Basically, the production symbols 35 (the left symbol 35a, the central symbol 35b, and the right symbol 35c) start to fluctuate at different timings, so that the fluctuation start sound for each effect symbol starts to be output at a different timing. Is done.
For example, as shown in FIG. 85 (A), the production symbol 35 starts to change in the order of the left symbol 35a (b), the right symbol 35c (c), and the central symbol 35c (d).
However, as shown in FIG. 85 (B), at the time of starting the variation of the special symbol, the three effect symbols 35 (the left symbol 35a, the central symbol 35b, and the right symbol 35c) may start varying at the same time.

In the gaming machine of the present embodiment, when the production symbol 35 outputs the variation start sound (51) in synchronization with the variation start of the left symbol 35a, the left and right speakers (sound output devices) 34 Control is performed so that the volume of the left speaker is larger than the volume of the right speaker toward the player.
When the fluctuation start sound (51) is output in synchronization with the fluctuation start of the right pattern 35c, the volume of the right speaker toward the player, the volume of the left speaker toward the player, and the volume of the right speaker toward the player Control to be larger than
When the fluctuation start sound (51) is output in synchronization with the fluctuation start of the central symbol 35b, the volume of the left and right speakers is controlled to be the same.
Thereby, when the variation starts in the order of left → right → center, the player can enjoy a three-dimensional sound with respect to the variation start sound of the effect design.

  Hereinafter, in the gaming machine of the present embodiment, an audio output process and an output mode in the case where a plurality of variation start sounds are generated simultaneously when a plurality of performance symbols 35 start varying under specific conditions will be described.

FIG. 86 is a timing diagram showing an example of a variation start sound output mode when three effect symbols start to vary simultaneously.
The numbers in parentheses indicate the sound numbers of the production sounds.

Along with the start of fluctuation, the host CPU 151 controls the voice control circuit 300 (effect sound output command) to output the fluctuation start sound (51).
In this example, since the left symbol 35a, the central symbol 35b, and the right symbol 35c start to change at the same time, three different change start sounds for each effect symbol 35 are reproduced and output using different variable channels.
At the same time, the output of BGM is started using an audio channel different from these fluctuation start sounds.

Furthermore, the host CPU 151 reproduces and outputs the fluctuating sound of the effect design 35 using another audio channel.
In this case, for the reasons explained below, three variable channels are occupied by different variation start sounds (different audio data) for the left symbol 35a and the right symbol 35c, and the audio channel can be used efficiently. I can't say.

This is because, even if the change start sound having the same content is used as another sound (different data), the change start sound having the same content is input to a different sound channel.
Even when the variation start sound of each effect symbol is the same data, the same problem occurs when the control is performed to input the variation start sound to a different audio channel for each effect symbol.
Therefore, in the present embodiment, a plurality of fluctuation stop sounds are generated using the audio channel more efficiently.

FIG. 87 is a timing diagram showing an example of a variation start sound output mode when three effect symbols start to vary simultaneously in the gaming machine of the present embodiment.
The numbers in parentheses indicate the sound numbers of the production sounds.

Along with the start of fluctuation, the host CPU 151 controls the voice control circuit 300 (effect sound output command) to output the fluctuation start sound (51).
Furthermore, the host CPU 151 reproduces and outputs the fluctuating sound of the effect design 35 using another audio channel.
In the gaming machine of this embodiment, when the left symbol 35a, the central symbol 35b, and the right symbol 35c start to vary simultaneously, the same variation start sound (51) for the three effect symbols is continuously applied to one audio channel. To enter.

In the gaming machine of the present embodiment, the same sound number is assigned to the sound having the same content, and when the same sound number is continuously input, the sound is continuously input to the same sound channel.
As a result, a limited number of audio channels included in the audio control circuit 300 can be used efficiently.

  The same applies to the variation start sound (51). The variation start sounds of the three effect symbols 35 (35a, 35b, 35c) are the same, and the same variation start sound (51) is set for each.

As a result, the fluctuation start sound (51) for the three effect symbols 35 is input to the same variable channel with a slight time difference, and as a result, the fluctuation start sound (51) heard as one sound is output. That is, a plurality of variation start sounds (51) based on the same data are input to the same audio channel and overwritten (while the output of the previously input variation stop sound is stopped).
Since the same variation start sound (51) is input to the same channel, only one audio channel is used as compared to the case where the three variation start sounds (51) are output using different audio channels. The audio channel can be used more efficiently.
By continuously inputting the fluctuation start sound for the three effect symbols, only the change stop sound relating to one effect symbol (the middle symbol 35c input last) may be output.

Even when the fluctuation start sound has the same content, if the voice is different (different data), the fluctuation start sound having the same content is input to a different audio channel as in the case of FIG.
As a result, it is conceivable that the player can hear the sound muffled, but such inconvenience can be solved by doing as described above.

  As described above, in the gaming machine of the present embodiment, when the fluctuation start sound (51) is output in synchronization with the fluctuation start of the left pattern 35a, the left and right speakers (sound output devices) 34 When controlling the volume of the left speaker toward the player to be larger than the volume of the right speaker toward the player and outputting the variation start sound (51) in accordance with the variation start of the right pattern 35c, The volume of the right speaker toward the player is controlled so that the volume of the left speaker is larger than the volume of the right speaker toward the player, and the fluctuation start sound ( 51), the left and right speakers are controlled to have the same volume.

When the variation start sound (51) for the three effect symbols 35 is input to the same variable channel with a slight time difference as in FIG. 84, the variation start sound (51) for the left symbol 35a and the right symbol 35c. The change start sound (51) for use and the change start sound (51) for the central symbol 35c are input in this order.
As a result, what is left in the player's ear is the last input variation start sound (51) for the central symbol 35b.
The variation start sound (51) for the middle symbol for the central symbol 35 (b), that is, the variation start sound controlled so that the left and right speakers have the same volume, and the player naturally changes the variation start sound. Can be heard.

Instead of outputting three identical fluctuation stop sounds, only one variable start sound (51) may be reproduced and output using one variable channel.
This is not a change start sound that can be heard as one sound, but literally a change stop sound of only one sound.
In the case of outputting only one change stop sound, a change stop sound for the middle symbol (52), that is, a change stop sound controlled so that the left and right speakers have the same volume is output.
The player can listen to the fluctuation stop sound output in this way in a natural manner.

  In the case of simultaneously starting to produce effect sounds related to two or more effect symbols (variation start sound, variation stop sound), the effect sound related to one effect symbol is output.

<Other embodiments>
The host CPU 151 treats a plurality of effect sounds being reproduced and output on a plurality of audio channels of the audio control circuit 300 as a group, and collectively controls (changes volume, stops output, etc.) the effect sound designated by these groups. It is possible.
The group of effect sounds is performed using the sound numbers, and the sound control unit 301 refers to the above-described status information for the sound channel that is outputting the effect sounds of the sound numbers included in the group specified by the effect sound specifying command. To identify and control.

As the image display device of the gaming machine 1, a liquid crystal display device, a rear projector, and other arbitrary display devices can be adopted.
The display mode of the image display device of the present invention can be applied not only to pachinko machines, but also to slot machines, other gaming machines having display devices, and game machines in general.

DESCRIPTION OF SYMBOLS 1 Game machine, 10 Game board, 13 1st starting port, 14 2nd starting port, 31 Image display apparatus, 35 Decoration design, 110 Main control board, 111 Main CPU, 112 Main ROM, 113 Main RAM, 120 Production control board , 121 Sub CPU, 122 Sub ROM, 123 Sub RAM, 140 Lamp control board, 150 Image control board, 151 Host CPU, 152 Host RAM, 153 Host ROM

Claims (1)

Determining means for determining whether or not to execute a predetermined special game when the start condition is satisfied;
Based on the determination result by the determination means, an effect control means for determining a variation effect for notifying the determination result and performing control for executing the variation effect;
Storage means for storing voice information;
Voice control means for performing control to output a production sound from the voice output means as the variation effect based on the voice information;
The effect sound is the first effect effect that is continuously output before becoming the specific effect mode during the change effect, and the specific effect mode when the specific effect mode is reached. And a second variation effect sound that is output during the specific effect mode,
The variation effect includes a plurality of different effect modes that can be executed for one variation effect,
The production control means selects one production mode from the plurality of production modes for one variation production with the establishment of a predetermined condition,
In accordance with the selected effect mode, a first variation effect sound determining means for determining a first variation effect sound to be output from the plurality of first variation effect sounds is further provided,
The voice control means is
Until the specific effect mode, the first variation effect sound determined by the first variation effect sound determination means is continuously output,
When the specific effect mode is reached, the second variation effect sound is output and output at the same timing regardless of which first variation effect sound is determined by the first variation effect sound determination means. Limiting the output of the first variation effect sound,
A gaming machine, wherein the third variation effect sound is output after a predetermined period of time has elapsed since the second variation effect sound was output.

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