JP2016189896A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine capable of improving interest of a game.SOLUTION: During variable display of a special pattern corresponding to a lottery of one-time bonanza, a pseudo continuation performance can be executed, for performing a plurality of times of 'pseudo variation display' for varying again a performance pattern after stopping it once temporarily. Further, when the number of times of pseudo continuation is twice or more, and an abetment performance is executed in a plurality of times, respective abetment rows in an abetment performance of the first time and in an abetment performance of the second time and after are the same.SELECTED DRAWING: Figure 49

Description

  The present invention relates to a gaming machine that determines whether or not to execute a special game advantageous to a player based on establishment of a predetermined condition, and executes a special game when it is determined that the special game is to be executed by the determination. .

  In a conventional gaming machine, there is a gaming machine that can execute an effect display in which a pseudo effect symbol variation display is performed a plurality of times in the effect symbol variation display for one winning. For example, the gaming machine described in Patent Document 1 determines a notice effect to be executed corresponding to the change pattern from a plurality of notice effects based on the determined change pattern. When the pseudo continuous variation pattern is determined, the notice effect is determined for each of the plurality of pseudo variation displays included in the pseudo continuous variation pattern. As in the gaming machine described in Patent Document 1, when performing an effect (pseudo-continuous effect) in which an effect symbol is displayed in a quasi-continuous manner in a single effect symbol change display, a so-called roaring effect is generally used. Often done. For example, during the fluctuating production before the execution of the pseudo-continuous effect, an effect is given to ask whether or not the pseudo-continuous effect is executed at the next variable effect, or whether the pseudo-continuous effect continues during the pseudo-continuous effect. Doing productions that sing.

JP 2014-155792 A

  In recent years, in order to improve the production effect, there is a tendency that various effects of the production are performed. However, when such a roaring effect becomes complicated, it may be difficult for a player to grasp whether it is a roaring effect or whether a pseudo-continuous effect is continued. May fall.

  In view of the above background, an object of the present invention is to provide a gaming machine capable of improving the fun of gaming.

  The gaming machine according to the first invention variably displays special game determination means for determining whether or not to control a special game advantageous to the player and a plurality of types of effect symbols when the starting condition is satisfied. When the determination is made by the variable display means having a plurality of variable display parts and the special game determination means, the variable display means controls the variable display of the effect symbols on the variable display parts of the variable display means, and If the determination result indicates that the control is to be performed, an effect symbol display control means for stopping and displaying a predetermined combination of effect symbols is provided, and the effect symbol display control means is in a single variation display. In the above, a pseudo continuous effect control means capable of executing a pseudo continuous effect for performing a pseudo variable display which is a variable display of a pseudo effect design a plurality of times, and the pseudo variation table by the pseudo continuous effect control means Inside, there is a turning effect control means capable of executing a turning effect that determines whether pseudo-variable display is performed again using at least one variable display portion of the plurality of variable display portions, and In the pseudo-variable display after the turn effect is executed before the reach state that constitutes a part of the combination of the specific effect symbols in at least a part of the plurality of variable display units. When the turn effect is executed again, the turn effect is executed using the same variable display unit.

  According to the gaming machine according to the present invention, it is possible to provide a gaming machine capable of improving the interest of the game.

It is a front view of a gaming machine. It is a fragmentary perspective view of a gaming machine. It is a block diagram of a control means. (A-1) is a diagram representing a jackpot determination table for the first special symbol, (a-2) is a diagram representing a jackpot determination table for the second special symbol, and (b) is a diagram representing a reach determination table. . (A) is a figure showing the special symbol determination table for jackpot winning, (b) is a figure showing the special symbol determination table for losers. It is a figure showing a jackpot game control table. It is a figure showing the big winning prize opening / closing control table for jackpot games. It is a figure showing a game state setting table. It is a figure showing the variation pattern determination table of the special symbol for lose. It is a figure showing the variation pattern determination table of the special jackpot symbol. It is a figure showing the variation pattern determination table of the special symbol for lose. It is a figure showing the variation pattern determination table of the special jackpot symbol. It is a figure showing the prior determination table of jackpot lottery. It is a figure showing the prior determination table of jackpot lottery. (A) is a diagram representing a normal symbol hit determination table, (b) is a diagram representing a normal symbol determination table, (c) is a regular variation pattern determination table, (d) is an auxiliary game reference data determination table. (E) is a figure showing an auxiliary game control table, (f) is a figure showing a 2nd starting opening-and-closing control table. (A) is a diagram showing the configuration of the special symbol reserve storage area of the main RAM 101c, (b) is a diagram showing the configuration of each storage unit of the special symbol reserve storage area, (c) is a diagram of the normal symbol reserve storage area of the main RAM 101c The figure showing a structure is a figure showing the structure of each memory | storage part of a normal symbol holding | maintenance storage area. It is a flowchart which shows the main process in a main control board. It is a flowchart which shows the timer interruption process in a main control board. It is a flowchart which shows the input control process in a main control board. It is a flowchart which shows the big winning opening detection signal input process in a main control board. It is a flowchart which shows the 1st starting port detection signal input process in a main control board. It is a flowchart which shows the 2nd start port detection signal input process in a main control board. It is a flowchart which shows the winning gate detection signal input process in a main control board. It is a flowchart which shows the special figure special electric power control process in a main control board. It is a flowchart which shows the special symbol memory | storage determination processing in a main control board. It is a flowchart which shows the jackpot determination process in a main control board. It is a flowchart which shows the special symbol determination process in a main control board. It is a flowchart which shows the special figure fluctuation pattern determination process in a main control board. It is a flowchart which shows the special symbol fluctuation | variation process in a main control board. It is a flowchart which shows the special symbol stop process in a main control board. It is a flowchart which shows the jackpot game process in a main control board. It is a flowchart which shows the jackpot game end process in a main control board. It is a flowchart which shows the common figure normal power control process in a main control board. It is a flowchart which shows the normal symbol memory | storage determination process in a main control board. It is a flowchart which shows the normal symbol fluctuation | variation process in a main control board. It is a flowchart which shows the normal symbol stop process in a main control board. It is a flowchart which shows the auxiliary | assistant game process in a main control board. It is a flowchart which shows the main process in an effect control board. It is a flowchart which shows the timer interruption process in an effect control board. It is a flowchart which shows to the middle of the command analysis process in an effect control board. FIG. 41 is a flowchart showing a continuation of the command analysis process of FIG. 40. FIG. It is a flowchart which shows the special figure reservation icon display process in an effect control board. It is a flowchart which shows the change production | presentation determination process in an effect control board. It is a flowchart which shows the change effect pattern determination process in an effect control board. It is a flowchart which shows the game state setting process in an effect control board. (A) is a flowchart which shows the big winning opening winning process in an effect control board, (b) is a modification of the flowchart which shows the big winning opening winning process in an effect control board. (A) is a figure showing the structure of the production | presentation information storage area | region of sub RAM102c, (b) is a figure showing the structure of each memory | storage part of an production | presentation information storage area. It is a figure showing an example of the table for reach production type determination. It is a figure showing an example of the table for a roaring effect determination. It is a figure showing an example of the table for title aspect determination. It is a figure showing an example of the table for jackpot expectation degree determination. It is a figure showing an example of the variation production pattern determination table. It is a figure showing an example of the variation production pattern determination table. It is a figure showing an example of transition of reach production. It is a figure showing an example of transition of reach production. It is a figure showing an example of transition of reach production. It is a figure showing an example of transition of reach production. It is a figure showing an example of the display part in a jackpot game. It is a figure showing an example of transition of reach production in a modification.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.

  As shown in FIG. 1, the gaming machine Y is formed with a gaming board mounting frame Y1, a glass door Y2 supported so as to be rotatable with respect to the gaming board mounting frame Y1, and a gaming area 2A in which gaming balls flow down. And a game board 2.

  The game board mounting frame Y1 is rotatably supported by an outer frame (not shown) fixed to the island facility of the game store, and is detachably mounted.

  The glass door Y2 is detachably connected to the game board mounting frame Y1 via a hinge mechanism portion H at one end side in the horizontal direction, and is supported rotatably about the hinge mechanism portion H as a fulcrum. Therefore, by rotating the glass door Y2 like a door around the hinge mechanism H as a fulcrum, the game area 2A and the front portion of the game board mounting frame Y1 can be opened and closed. The glass door Y2 covers the game area 2A in a state where the game board 2 is closed so as to be visible.

  A lock mechanism R that fixes the glass door Y2 to the game board mounting frame Y1 is provided on the other end side of the glass door Y2. The fixing by the lock mechanism R can be released by a dedicated key.

  The glass door Y <b> 2 is provided with a receiving tray 50 that stores a plurality of game balls and a firing operation device 3 that can perform an operation for firing the game balls. The launch operation device 3 is connected to a game ball launch device (not shown) that can launch a game ball toward the game area 2A. The game ball launcher is provided on the front surface of the game board mounting frame Y1. The game balls stored in the tray 50 are supplied to the game ball launcher.

  The firing operation device 3 includes a base 31 fixed to the glass door Y2, and a launch handle 32 that is rotatably provided on the base 31. The game ball launcher launches a game ball with a strength (hereinafter referred to as “game ball launch strength”) according to the rotation angle of the launch handle 32.

  In the game area 2A of the game board 2, a frame-shaped decorative frame 29A, an inner rail member 29B having a curved shape, an outer rail member 29C, and a special winning opening 8, which will be described later, are arranged and a game ball is placed. A guidance member 29 </ b> D having a guidance path that can be guided to the second starting port 7 formed on the upper surface is provided.

  The decorative frame 29 </ b> A is fitted into the approximate center of the game board 2. An image display device 14 including a liquid crystal display is fitted inside the decorative frame 29A. Further, an effect accessory device 17 is provided at the inner end of the decorative frame 29A.

  The inner rail member 29B is disposed outside the decorative frame 29A, and the outer rail member 29C is disposed outside the inner rail member 29B. A game ball fired with a predetermined game ball launch strength rises between the inner rail member 29B and the outer rail member 29C and enters the game area 2A. In the game area 2A, a plurality of nails and windmills are provided. A game ball that has entered the game area 2A can flow down in various directions by a plurality of nails and windmills.

  In the game area 2A, a plurality of (four in the present embodiment) general winning awards 11 are provided. Each general winning opening 11 is provided with a general winning opening detecting sensor 11a. When the general winning opening detecting sensor 11a detects a gaming ball, a predetermined number (for example, ten) of gaming balls are paid out as winning balls. .

  A first winning gate 9 through which game balls can pass is provided on the left side of the decorative frame 29A in the game area 2A. In addition, a second winning gate 10 through which a game ball can pass is provided on the lower right side of the decorative frame 29A in the game area 2A. The winning gates 9 and 10 are provided with winning gate detection sensors 9a and 10a for detecting game balls. A normal symbol lottery is performed on condition that the winning gate detection sensors 9a and 10a detect a game ball. The normal symbol lottery will be described later.

  A first start port 6 is provided below the image display device 14 at the lower part of the game area 2A and is invariable and can always enter the ball. The first start port 6 is provided with a first start port detection sensor 6a for detecting a game ball. A first special symbol lottery is performed on condition that the first start port detection sensor 6 detects a game ball. The first special symbol lottery will be described later. When the first start port detection sensor 6a detects a game ball, a predetermined number (for example, three) of game balls are paid out as prize balls.

  A variable second start port 7 is provided immediately below the first start port 6. The second start port 7 is controlled by the second start port control device 70 to either a basic mode (closed mode) incapable of winning a prize or a special mode (open mode) of winning. The second start port 7 is also provided with a second start port detection sensor 7a for detecting a game ball. A second special symbol lottery is performed on condition that the second start port detection sensor 7a detects a game ball. The second special symbol lottery will be described later. When the second start port detection sensor 7a detects a game ball, a predetermined number (for example, three) of game balls are paid out as a prize ball.

  The second start port control device 70 includes a rotatable normal movable piece 70A and a second start port opening / closing solenoid 70B as a drive unit for rotating the normal movable piece 70A.

  The normal movable piece 70A is composed of a rectangular door member. Normally, the movable piece 70A stops in a state where the surface is flush with the game area 2A (except when a predetermined condition is satisfied), and the second start port 7 is opened. It is closed. The closing of the second starting port 7 by the ordinary movable piece 70 </ b> A constitutes a basic mode of the second starting port 7.

  On the other hand, when the predetermined condition is satisfied, the normal movable piece 70A is rotated forward about the rotation shaft formed at the lower end portion to open the second start port 7. The second start port 7 is controlled to a special mode that allows the ball to enter. The opening of the second starting port 7 by the ordinary movable piece 70 </ b> A constitutes a special mode of the second starting port 7. When the second starting port 7 is opened, the normal movable piece 70A protrudes from the game area 2A, and can receive the flowing game ball and guide it to the second starting port 7.

  Note that the predetermined condition for the second start-up port control device 70 is that the normal symbol lottery described above is determined as the winning normal symbol.

  On the downstream side of the second winning gate 10, a variable large winning opening 8 is provided. The special winning opening 8 is controlled by the special winning opening control device 80 to either a basic mode in which no winning is possible or a special mode in which a winning is possible. The big winning opening 8 is provided with a big winning opening detecting sensor 8a for detecting a game ball. When the big prize opening detection sensor 8a detects a game ball, a predetermined number (for example, 15) of game balls are paid out as a prize ball.

  The special prize opening control device 80 includes a rotatable special movable piece 80A and a special prize opening opening / closing solenoid 80B as a drive unit for rotating the special movable piece 80A.

  The special movable piece 80A is composed of a rectangular door member. Normally, the special movable piece 80A stops in a state where the surface is flush with the game area 2A (except when a predetermined condition is satisfied), and the special winning opening 8 is closed. doing. The closing of the special prize opening 8 by the special movable piece 80 </ b> A constitutes the basic mode of the special prize opening 8.

  On the other hand, when the predetermined condition is satisfied, the special movable piece 80A is rotated forward about the rotation shaft formed at the lower end portion to open the special winning opening 8. The special winning opening 8 is controlled to a special mode in which a ball can be entered. Opening of the special winning opening 8 by the special movable piece 80A constitutes a special mode of the special winning opening 8. When the special winning piece 80A is opened, the special movable piece 80A protrudes from the game area 2A and can receive the flowing game ball and guide it to the special winning opening 8.

  The predetermined condition for the special winning opening control device 80 is the above-described first special symbol lottery or second special symbol lottery (hereinafter, the first special symbol lottery and the second special symbol lottery are collectively referred to as “special symbol lottery”). ”) And the jackpot special symbol.

  On the surface of the game board 2 and below the game area 2A, a symbol display device comprising a first special symbol display device 20, a second special symbol display device 21 and a normal symbol display device 22, and a first special symbol hold A hold display device including a display device 23, a second special symbol hold display device 24, and a normal symbol hold display device 25 is provided.

  The first special symbol display device 20 is a variable display device that displays the result of the first special symbol lottery performed on condition that a game ball enters the first start port 6, and the second special symbol display device 21 is This is a variable display device that displays the result of the second special symbol lottery performed on condition that a game ball enters the second starting port 7.

  In the first special symbol lottery, a big hit determination random number value is acquired when a game ball enters the first start port 6, and the acquired big hit determination random number value is a random value corresponding to “big hit” Determining whether or not. In the second special symbol lottery, whether a big hit determination random number value is acquired when a game ball enters the second starting port 7, and the acquired big hit determination random number value is a random value corresponding to “big hit” Determining whether or not.

  When the first special symbol lottery is performed, the first special symbol display device 20 displays a variation of the special symbol based on the lottery result, and displays the first special symbol lottery representing the result of the first special symbol lottery. Stop display is performed. That is, the stop display of the first special symbol in the first special symbol display device 20 is a notification of the lottery result. The same applies to the second special symbol lottery and the second special symbol display device 21.

  For example, the first special symbol display device 20 and the second special symbol display device 21 each include a plurality of LEDs. In the variation display of each special symbol, for example, a predetermined LED of the corresponding first special symbol display device 20 or second special symbol display device 21 blinks at a predetermined interval. In the special symbol stop display, a specific LED indicating the result of each special symbol lottery is lit.

  The normal symbol display device 22 is a variable display device that displays the result of the normal symbol lottery performed on condition that the game ball passes the winning gates 9 and 10. In the normal symbol lottery, a winning random number value is acquired when the game ball passes the winning gates 9 and 10, and it is determined whether or not the acquired winning random number value is a random value corresponding to “win”. This is the process to do.

  When the normal symbol lottery is performed, the normal symbol display device 22 displays the variation of the normal symbol based on the lottery result, and the stop display of the normal symbol representing the result of the normal symbol lottery is performed. That is, the normal symbol stop display on the normal symbol display device 22 is a notification of the lottery result.

  For example, each of the normal symbol display devices 22 includes a plurality of LEDs. In the normal symbol variation display, for example, a predetermined LED of the normal symbol display device 22 blinks at a predetermined interval. And in the stop display of a normal symbol, specific LED showing the result of a normal symbol lottery lights.

  By the way, even if a game ball enters the start openings 6 and 7 during the special symbol variation display or during the big hit game in which the big prize control device 80 is activated, the special symbol variation display is immediately performed and the special symbol variation display is performed. The result of the symbol lottery is not notified. That is, the special symbol variation display may be suspended under certain conditions. In the present embodiment, as a fixed condition, an upper limit is provided for the number of special symbols that can be suspended. In the present embodiment, the upper limit value is set to “4” for each of the start ports 6 and 7. That is, it is possible to hold up to four rights to execute the special symbol variation display for each of the start ports 6 and 7.

  The first special symbol hold display device 23 displays the hold number (U1: hereinafter referred to as “first special figure hold number”) of the fluctuation display of the first special symbol (hereinafter referred to as “first special figure change display”). To do. The second special symbol hold display device 24 displays the hold number (U2: hereinafter referred to as “second special figure hold number”) of the fluctuation display of the second special symbol (hereinafter referred to as “second special figure change display”). To do. The first special symbol hold display device 23 and the second special symbol hold display device 24 include, for example, a plurality of LEDs, and turn on a predetermined LED according to the number of holds.

  Similarly, for the variable symbol display (hereinafter referred to as “general variable display”), the upper limit reserved number is set to four, and the reserved number (G: hereinafter referred to as “general map reserved number”). ) Is displayed on the normal symbol hold display device 25. The normal symbol hold display device 25 includes, for example, a plurality of LEDs, and lights a predetermined LED according to the number of hold of the normal symbols.

  In addition, the gaming machine Y is provided with an effect device for executing various effects. In the present embodiment, the effect device includes an image display device 14, an audio output device 15, an effect lighting device 16, and an effect accessory device 17. An image display device 14 and an effect accessory device 17 are provided on the game board 2, and an audio output device 15 and an effect lighting device 16 are provided on the glass door Y2.

  The image display device 14 performs various effects by displaying various still images and moving images. In this embodiment, a liquid crystal display is used as the image display device 14, but other types of display devices such as a plasma display and an organic EL display can also be used.

  The effect accessory device 17 includes a movable part 17A, and operates the movable part 17A to perform an effect by operation. The audio output device 15 produces a sound effect by outputting BGM (background music), SE (sound effect), and the like. The effect lighting device 16 performs an effect by illumination by changing the light irradiation direction and emission color of each lamp.

  The saucer 50 is provided with an effect button device 18 and a selection button device 19 that function as input devices for performing operations related to various effects described later.

  The effect button device 18 includes an effect button 18A that can be operated and an effect button detection switch 18a that is connected to the effect button 18A and detects an operation on the effect button 18A (see FIG. 2).

  The selection button device 19 is connected to an operable selection button 19A and a selection button 19A, and includes a selection button detection switch 19a that detects an operation on the selection button 19A (see FIG. 2).

  The selection button 19A includes an upper button 191A, a left button 192A, a lower button 193A, and a right button 194A. Each button 191 </ b> A to 194 </ b> A is provided so as to be pressed in a state of protruding from the tray 50.

  The effect device performs various effects according to the progress (state) of the game. As an effect, for example, there is a special drawing lottery effect that is performed in response to the first special symbol lottery and the second special symbol lottery. The special drawing lottery effect is performed in the image display device 14. In the special drawing lottery effect, a change display of the effect symbol and a stop display of the effect symbol are performed.

  The variation display of the effect symbol is performed corresponding to the variation display of the special symbol, and the effect symbol varies for a predetermined time in a predetermined manner. The stop display of the effect symbol is performed corresponding to the stop display of the special symbol (hereinafter referred to as “effect symbol display” when the change display and stop display of the effect symbol are collectively referred to). In the stop display of the effect symbol, the effect symbol is stopped for a predetermined time in a predetermined manner representing the result of the special symbol lottery.

  The effect symbols are, for example, three rows of effect symbols (for example, numbers from “1” to “9” arranged in the left area, the center area, and the right area of the display unit 140 such as the image display device 14, “A "B", "C", etc.). In the variation display of the effect symbols, the effect symbols in each column move from the top to the bottom (variable display) as if the reels are rotating. Note that the variation display mode of the effect symbol is not limited to this. Further, during the effect symbol variation display, various effect images such as background images and object images of various characters, movies, and the like are displayed according to the result of the special symbol lottery.

  On the other hand, in the stop display of the effect symbols, the above three rows of effect symbols are stopped and displayed in the left area, the center area, and the right area of the display unit 140 such as the image display device 14. The arrangement of effect symbols on a predetermined effective line (for example, the central horizontal line in the display unit 140) when the effect symbols are stopped and displayed represents the result of the special symbol lottery.

  In addition to the special drawing lottery effect, the roulette effect constituting the specific effect of the present invention, the jackpot game effect performed when the jackpot game is executed, and the special symbol variation display or jackpot game are not performed for a predetermined period. Various effects such as a demonstration effect performed in an internal standby state (so-called customer waiting state) are performed.

  On the back of the game board 2 and the glass door Y2, there are a main control board 101 for performing various controls relating to the game, an effect control board 102, a payout control board 103, a lamp control board 104, an image control board 105, a power supply board 107, a game An information output terminal board 108 is provided.

(Internal configuration of gaming machine Y)
Next, the internal configuration of the gaming machine Y will be described with reference to FIG.

  The power supply board 107 is provided with a backup power supply composed of a capacitor, supplies a power supply voltage to the gaming machine Y, monitors a power supply voltage supplied to the gaming machine Y, and when the power supply voltage becomes a predetermined value or less, An interruption detection signal is output to the main control board 101. When the power interruption detection signal becomes high level, the main CPU 101a becomes operable, and when the power interruption detection signal becomes low level, the main CPU 101a becomes inactive 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 101 controls the basic operation of the game. The main control board 101 includes a main CPU 101a, a main ROM 101b, and a main RAM 101c. The main CPU 101a reads out a program stored in the main ROM 101b based on input signals from various detection sensors, timers (quartz crystal units) and the like, performs arithmetic processing related to the game, and directly controls various control devices and display devices. Then, a predetermined command or the like based on the result of the arithmetic processing is transmitted to the effect control board 102, the payout control board 103, and the like. The main RAM 101c functions as a data work area during the arithmetic processing of the main CPU 101a.

  On the input side of the main control board 101, a first starting port detection sensor 6a, a second starting port detection sensor 7a, a big winning port detection sensor 8a, and a first winning gate detection are detected via an input port (not shown). The sensor 9a, the second winning gate detection sensor 10a, and the general winning opening detection sensor 11a are connected. Each detection sensor outputs a detection signal to the main control board 101 when detecting a game ball.

  On the output side of the main control board 101, via an output port (not shown), a second start port opening / closing solenoid 70B for operating the normal movable piece 70A of the second start port control device 70, and a prize winning port control. A special prize opening / closing solenoid 80B for operating the special movable piece 80A of the device 80 is connected. The main control board 101 outputs a control signal for controlling each solenoid to the second start opening / closing solenoid 70B and the special winning opening opening / closing solenoid 80B.

  Further, on the output side of the main control board 101, a first special symbol display device 20, a second special symbol display device 21, a normal symbol display device 22, and a first special symbol hold are provided via an output port (not shown). A display device 23, a second special symbol hold display device 24, and a normal symbol hold display device 25 are connected. The main control board 101 outputs a display control signal for controlling each display device to each display device 20-25.

  Furthermore, a game information output terminal board 108 is connected to the output side of the main control board 101 via an output port (not shown). The main control board 101 outputs information relating to a predetermined game (hereinafter referred to as game information) to the game information output terminal board 108 as an external signal.

  A game information display device is connected to the game information output terminal board 108. The game information output terminal board 108 outputs an external signal to the game information display device and the hall computer. The game information display device is provided on the gaming machine Y, and can display predetermined game information based on the predetermined game information (external signal).

  The effect control board 102 includes a sub CPU 102a, a sub ROM 102b, and a sub RAM 102c. The effect control board 102 is connected to the main control board 101 so as to be able to communicate in one direction from the main control board 101 to the effect control board 102. The main control board 101 transmits a predetermined command to the effect control board 102 based on the processing related to the game, and the effect control board 102 receives the predetermined command.

  An effect button detection switch 18 a and a selection button detection switch 19 a are connected to the input side of the effect control board 102 via the lamp control board 104.

  When the effect button 18A is operated, the effect button detection switch 18a outputs an effect button detection signal indicating that the operation of the effect button 18A has been performed to the lamp control board 104 to the effect control board 102. When the effect button detection signal is input, the lamp control board 104 outputs the effect control board 102 to the effect control board 102.

  When the selection button 19A is operated, the selection button detection switch 19a outputs a selection button detection signal indicating that the selection button 19A has been operated to the lamp control board 104 to the effect control board 102. When the selection button detection signal is input, the lamp control board 104 outputs it to the effect control board 102.

  The selection button detection switch 19a is connected to the upper button 191A to detect the operation of the upper button 191A, and the left button detection switch 192a is connected to the left button 192A to detect the operation of the left button 192A. The lower button 193A is connected to the lower button 193A to detect the operation of the lower button 193A, and the right button detection switch 194a is connected to the right button 194A to detect the operation of the right button 194A.

  When each button detection switch 191a, 192a, 193a, 194a detects an operation, the upper button detection signal, the left button detection signal, the lower button detection signal, and the right button detection signal are respectively transmitted via the lamp control board 104. To the effect control board 102. The upper button detection signal, the left button detection signal, the lower button detection signal, and the right button detection signal are collectively referred to as a “selection button detection signal”.

  The sub CPU 102a outputs a command output from the main control board 101, an effect button detection signal output from the effect button device 18, a selection button detection signal output from the selection button device 19, and an input signal from a timer (crystal oscillator). Based on the above, the program stored in the sub ROM 102b is read out to perform arithmetic processing, and a command for controlling the effect is transmitted to the lamp control board 104 and the image control board 105 based on the processing. The sub RAM 102c functions as a data work area when the sub CPU 102a performs arithmetic processing.

  The payout control board 103 performs launch control for launching the game ball and payout control for paying out the game ball to the player. The payout control board 103 includes a payout CPU 103a, a payout ROM 103b, and a payout RAM 103c. The payout control board 103 is connected to the main control board 101 and the power supply board 107 so as to be capable of bidirectional communication.

  A touch sensor 32a and a firing volume knob 32b are connected to the input side of the payout CPU 103a. The touch sensor 32 a is mounted in the firing handle 32. When a player, a store clerk, or the like touches the launch handle 32, the touch sensor 32 a detects that a person has touched the launch handle 32 and transmits a launch handle detection signal to the launch control board 106. The firing volume knob 32 b is connected to the firing handle 32. The firing volume knob 32b rotates in conjunction with the firing handle 32 and detects the rotation angle.

  The payout control board 103 is connected to the firing solenoid 41 via the power supply board 107 on the output side. The payout control board 103 permits energization of the firing solenoid 41 when receiving the firing handle detection signal from the touch sensor 32a.

  When the firing handle 32 is operated to change the rotation angle of the firing handle 32, the gear connected to the firing handle 32 rotates and the knob 32b of the firing volume connected to the gear rotates. A voltage corresponding to the rotation angle of the firing handle 32 detected by the firing volume knob 32 b is applied to the firing solenoid 41.

  When a voltage is applied to the firing solenoid 41, the firing solenoid 41 operates according to the applied voltage. In this manner, the payout control board 103 controls the energization of the launch solenoid 41 based on the information contained in the launch handle detection signal from the touch sensor 32a and the input signal from the launch volume knob 32b, and launches the game ball.

  In the present embodiment, the reciprocating speed of the firing solenoid 41 is set to about 99.9 (times / minute) from the frequency based on the output period of the crystal oscillator provided on the firing control board 106. Since one game ball is fired every time the firing solenoid 41 makes one reciprocation, the number of game balls fired in one minute is about 99.9 (pieces / minute).

  Further, a payout drive unit 51 of the payout device 5 for paying out a predetermined number of game balls from a storage tank (not shown) to the player is connected to the output side of the payout control board 103. The payout CPU 103a reads out a predetermined program from the payout ROM 103b based on the prize ball request signal transmitted from the main control board 101, performs arithmetic processing, and controls the payout device 5 to give a predetermined game ball to the player. Pay out. At this time, the payout RAM 103c functions as a data work area during the calculation process of the payout CPU 103a.

  The lamp control board 104 includes a lamp CPU 104a, a lamp ROM 104b, and a lamp RAM 104c, similarly to the above boards. On the output side of the lamp control board 104, an effect lighting device 16 and an effect accessory device 17 are connected.

  The lamp CPU 104a performs light emission control of the effect lighting device 16 and irradiation of light from the effect lighting device 16 based on a command related to effect control transmitted from the effect control board 102 (hereinafter referred to as “effect control command”). Drive control for the motor for changing the direction is performed. Further, the lamp CPU 104a performs drive control on a solenoid or a motor that operates the effect accessory device 17 based on the effect control command.

  Further, on the input side of the lamp control board 104, an effect button detection switch 18 a of the effect button device 18 and a selection button detection switch 19 a of the selection button device 19 are connected. When the effect button detection signal or the selection button detection signal is input, the lamp control board 104 outputs each to the effect control board 102. That is, the lamp control board 104 relays the effect button detection signal and the selection button detection signal between the effect control board 102, the effect button device 18, and the selection button device 19.

  The image control board 105 generates at least a video signal related to an image such as a moving image or a still image to be displayed on the display unit 140 of the image display device 14, and outputs the image signal to the image display device 14. A sound generation unit 105C that generates a sound signal related to the sound to be output to the sound output unit 15 and outputs the sound signal to the sound output device 15, and a control unit 105A that controls and controls the image generation unit 105B and the sound generation unit 105C.

  The overall control unit 105 </ b> A of the image control board 105 includes an overall CPU 105 </ b> Aa, an overall ROM 105 </ b> Ab, and an overall RAM 105 </ b> Ac for performing image display control by the image display device 14.

  The overall CPU 105Aa is connected to an overall ROM 105Ab in which a control program and the like are stored, and a control program necessary for the operation of the overall CPU 105Aa is read out. Upon receiving a command related to effect control transmitted from the effect control board 102, the general CPU 105Aa issues an instruction for an image to be displayed on the image display device 14 on the image generation unit 105B based on the command, and also transmits to the sound generation unit 105C. A voice instruction to be output from the voice output device 15 is issued.

  The general RAM 105Ac functions as a data work area during the arithmetic processing of the general CPU 105Aa, and temporarily stores data read from the general ROM 105Ab.

  The general ROM 105Ab is composed of a mask ROM, a control processing program for the general ROM 105Ab, a display list generation program for generating a display list, an animation pattern for displaying a production pattern animation, animation scene information, and the like. Is remembered.

  This animation pattern is referred to when displaying an animation that constitutes the specific content of the effect by the image, and the animation pattern is associated with the animation scene information, the display order of each animation scene, and the like. The animation scene information includes weight frame (display time), target data (sprite identification number, transfer source address, etc.), drawing parameters (sprite display position, display magnification, transmittance, etc.), drawing method. Various information such as a duty ratio that is a parameter of the luminance of the image display device 14 is included.

  The image generation unit 105B includes a VDP (Video Display Processor) 105Ba that is an image processor, a CGROM 105Bb that stores image data, and a VRAM 105Bc that temporarily stores drawing data generated from the image data. I have.

  The VDP 105Ba is connected to the CGROM 105Bb in which image data is stored, and generates drawing data as a source of a video signal (RGB signal or the like) based on the image data based on an instruction from the overall CPU 105Aa. The image data is an image (frame) to be displayed on the image display device 14, for example, a material image representing an individual image such as a background image such as a scene, a character, and a dialogue that constitutes the background of the effect symbol image or the effect symbol. It is data. On the other hand, the drawing data is synthetic data representing an image of the entire frame formed by combining (superimposing) individual images.

  The CGROM 105Bb includes a flash memory, an EEPROM, an EPROM, a mask ROM, and the like, and compresses and stores image data (sprites, movies), etc., consisting of 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 specifying a color number for each pixel and an α value indicating the transparency of the image.

  Further, the CGROM 105Bb stores the palette data in which the color number information for designating the color number and the display color information for actually displaying the color are associated with each other without being compressed. The CGROM 105Bb 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 image generation unit 105B has a crystal oscillator. The crystal oscillator outputs a pulse signal to the VDP 105Ba. The VDP 105Ba divides the pulse signal to generate a synchronization signal (horizontal synchronization signal / vertical synchronization signal) for synchronizing with the image display device 14, and outputs the synchronization signal to the image display device 14.

  Next, details of various tables stored in the main ROM 101b will be described with reference to FIGS.

  FIGS. 4A-1 and 4A-2 are diagrams illustrating an example of the jackpot determination table. The jackpot determination constitutes a special symbol lottery and is to determine whether or not to execute a jackpot game advantageous to the player.

  FIG. 4A-1 is a table (hereinafter referred to as “first jackpot determination table”) that is referred to in the jackpot determination performed when the game ball enters the first starting port 6 as a trigger. On the other hand, FIG. 4A-2 is a table (hereinafter referred to as “second jackpot determination table”) that is referred to in the jackpot determination performed when the game ball enters the second start port 7 as a trigger.

  In any jackpot determination table, a jackpot determination table (hereinafter referred to as “low probability jackpot determination table”) referred to when the jackpot winning probability described later is relatively low (set to a standard value). And a jackpot determination table (hereinafter referred to as “high probability jackpot determination table”) that is referred to when the state is relatively high (set higher than the standard value).

  In each jackpot determination table, a jackpot determination value and a determination result are uniquely associated and stored. As will be described later, by matching the jackpot determination random number acquired when the game ball enters the first start port 6 or the second start port 7 with the jackpot determination table, "Is determined.

  If the result of the jackpot determination is “big jackpot”, the jackpot game with the opening of the jackpot 8 is executed after the special symbol indicating the result is stopped and displayed. If the result of the jackpot determination is “losing”, the jackpot game is not executed.

  When the result of the big hit determination is “losing”, the reach determination is further performed based on the reach determination table of FIG. In the reach determination table, the random number value for reach determination and the presence / absence of execution of reach production are uniquely associated and stored. As described later, whether or not the reach effect is executed by collating the reach determination random number obtained when the game ball enters the first start port 6 or the second start port 7 with the reach determination table Is determined.

  If the result of the reach determination is “execution of reach production”, the reach production is performed to increase the player's expectation of winning the big hit in the special drawing lottery production. Detailed contents of the reach production will be described later.

  FIG. 5A and FIG. 5B are diagrams illustrating an example of the special symbol determination table. The special symbol determination constitutes a special symbol lottery, and is to determine the type of stop special symbol (special symbol stop display mode) in the special symbol display devices 20 and 21 based on the result of the jackpot determination. .

  The special symbol determination table is roughly divided according to the result of the jackpot determination (the jackpot or loss). That is, FIG. 5A is a table that is referred to in the special symbol determination when the result of the jackpot determination is “Large”, and FIG. 5B is a special case when the result of the jackpot determination is “Lost”. It is a table referred in symbol determination.

  Each of these tables is further divided according to the type of start port (first start port 6 or second start port 7) where a game ball was entered as a trigger for the special symbol determination. In each special symbol determination table, the special symbol determination value and the special symbol to be stopped and displayed are uniquely associated and stored. As will be described later, the special symbol determination random number acquired when the game ball enters the first start port 6 or the second start port 7 is collated with the special symbol determination table, so that the stop special symbol is It is determined. As special symbol identification information to be stopped and displayed, special symbol stop symbol data and effect symbol designation command are set.

  The special figure stop symbol data is used in the process on the main control board 101, and the effect symbol designation command is transmitted to the effect control board 102 and used in the process on the effect control board 102. The effect symbol designation command is generated and transmitted to the effect control board 102 at the time of starting the variation display of the special symbol (at the time of the special symbol memory determination process in step S300).

  The effect designating command includes 1-byte MODE data for identifying the special symbol display device (the first special symbol display device 20 or the second special symbol display device 21) on which the special symbol related to the special symbol determination is stopped and displayed. And 1-byte DATA data for identifying the special symbol to be stopped and displayed.

  As for the effect designating command, if the upper byte data is “E3H”, it means that the special symbol is stopped on the first special symbol display device 20, and if the upper byte data is “E4H”, 2 This means that special symbols are stopped on the special symbol display device 21. An effect symbol designating command whose upper byte data is “E3H” is called a “first effect symbol designating command”, and an effect symbol designating command whose upper byte data is “E4H” is called a “second effect symbol designating command”. . The lower byte data represents the type of special stop symbol. As a result, depending on the combination of the upper byte data and the lower byte data, it is a big hit or a loss, the opening time of the jackpot game, the ending time, the number of rounds, the opening / closing mode of the big prize opening, and the game after the jackpot game ends The type of state is represented.

  FIG. 6 is a diagram illustrating an example of the jackpot game control table used when controlling the jackpot game.

  The jackpot game control table stores conditions for controlling the jackpot game. As conditions for controlling the jackpot game, the opening time, which is the period from the start of the jackpot game until the first opening of the big prize opening 8, and the opening to be transmitted to the effect control board 102 at the start of the opening Ending time, which is the period from the end of the last opening of the big winning opening 8 to the end of the jackpot game, and the ending An ending designation command to be transmitted to the effect control board 102 at the start is set. The conditions for controlling these jackpot games are related to the type of jackpot, that is, the type of special symbol (special symbol stop symbol data). That is, which control condition is used in the jackpot game is selected based on the type of special symbol.

  FIG. 7 is a diagram showing an example of a jackpot opening / closing control table for jackpot games used when controlling the opening / closing of the jackpot 8 in the jackpot game.

  The big winning opening / closing control table for the big hit game stores conditions for controlling the opening / closing of the big winning opening 8 in the big win game. As conditions for controlling the opening / closing of the big prize opening 8, a special number is a round number (R) which is the number of the round game, and an opening number of the big prize opening 8 (operation of the big prize opening control device 80) in each round game. The operation number (K) and the opening time / closing time (operation time / non-operation time) of the special winning opening 8 are set.

For example, when the special figure stop symbol data is “10” or “12”, the big winning opening opening / closing control table “01” shown in FIG. 7 is selected based on the jackpot game control table shown in FIG.
In the jackpot game based on the winning prize opening / closing control table “01”, the round game is performed 8 times, and the maximum opening time of the winning prize opening 8 is 29.5 seconds. The closing time is 2.0 seconds. As described above, when the special winning opening opening / closing control table “01” is selected, eight round games are performed, and in all round games, a round game in which a game ball can easily enter the big winning opening 8 is performed. Done. Such a jackpot is called “8R / 8R jackpot”.

When the special figure stop symbol data is “11”, the big prize opening opening / closing control table “02” shown in FIG. 7 is selected based on the jackpot game control table shown in FIG.
In the jackpot game based on the big prize opening / closing control table “02”, the round game is played eight times. In all rounds, the maximum opening time of the big winning opening 8 is 0.18 seconds, and the closing time of the big winning opening 8 until the start of the next round is 7.32 seconds. As described above, when the winning game opening / closing control table “02” is selected, a round game in which it is difficult to enter a game ball into the winning game port 8 in all round games although 8 round games are performed. Is done. Such a jackpot is called “0R / 8R jackpot”.

When the special figure stop symbol data is “20”, the big winning opening opening / closing control table “03” shown in FIG. 7 is selected based on the jackpot game control table shown in FIG.
In the jackpot game based on the big prize opening / closing control table “03”, the round game is played 15 times. In all the rounds, the maximum opening time of the big prize opening 8 is 29.5 seconds, and the closing time of the big prize opening 8 is 2.0 seconds. As described above, when the special winning opening opening / closing control table “03” is selected, 15 round games are performed, and in all round games, a round game in which a game ball can easily enter the big winning opening 8 is performed. Done. Such a jackpot is called “15R / 15R jackpot game”.

  FIG. 8 is a diagram showing an example of a game state setting table for determining the game state after the end of the jackpot game. Based on the special figure stop symbol data (see FIG. 5) indicating the type of the special symbol, the setting of the high probability gaming flag, the setting of the remaining number of fluctuations (X) of the high probability gaming state by the gaming state setting table shown in FIG. A time-short game flag is set, and the remaining fluctuation count (J) of the time-short game state is set.

  When the special figure stop symbol data is “10”, “11”, “20”, the high probability game flag is set after the jackpot ends, and the remaining fluctuation count (X) of the high probability game state is set to 10,000 times. The short-time game flag is also set, and the remaining fluctuation count (J) of the short-time game state is also set to 10,000 times. Thereby, the high-probability gaming state and the short-time gaming state are substantially continued until the next jackpot. On the other hand, when the special figure stop symbol data is “12” or “21”, the short-time game flag is set and the remaining fluctuation count (J) of the short-time game state is also set to 100, but the high-probability game flag is set. The remaining number of fluctuations (X) in the high probability gaming state is also set to zero. As a result, the low-probability gaming state and the short-time gaming state are continued until 100 fluctuations are made after the jackpot game ends. In this way, the gaming state setting table stores the special symbol type (special symbol stop symbol data) and the gaming state that are uniquely associated with each other.

  9 to 12 are diagrams showing a variation pattern determination table for determining a variation pattern of a special symbol as will be described later. As shown in FIG. 9 to FIG. 12, the variation pattern determination table includes a lottery lottery result, a special symbol (special symbol stop symbol data), a reach determination random value, and the number of reserved balls (U1) for the special symbol. Or, U2), a special figure variation random value, a special symbol variation pattern, and a special symbol variation time are associated with each other.

  Therefore, it can be said that the “special symbol variation pattern” defines at least the jackpot determination result and the special symbol variation time. In addition, since it is configured to always reach when the jackpot, the reach determination random value is not referred to when the jackpot. The reach determination random number and the special figure variation random value both have a random number range of 100 (0 to 99).

  Further, in the special symbol variation pattern determination table shown in FIGS. 9 and 10, for example, the variation pattern 1 is set so that the average variation time of the special symbol becomes shorter as the number of reserved balls (U1 or U2) of the special symbol increases. The fluctuation time (3 seconds) of the fluctuation pattern 2 (shortening fluctuation) is set to be shorter than the fluctuation time (10 seconds) of (normal fluctuation).

  The special symbol variation pattern is determined by special symbol variation pattern determination (step S313-3) at the time of starting the variation display of the special symbol (during the special symbol memory determination processing in step S310). The main CPU 101a refers to the special symbol variation pattern determination table shown in FIG. 9 to FIG. 12, and displays the special symbol display device (type of the start opening), the lottery result of the jackpot lottery, the special symbol to be stopped, the number of special symbol holding balls ( U1 or U2), the variation pattern of the special symbol and the variation time of the special symbol are determined based on the reach determination random number value and the special symbol variation random value. Although the maximum number of balls “4” may be stored as the number of reserved balls of the special symbol, the variation pattern of the special symbol is determined after subtracting 1 from the number of reserved balls of the special symbol. Therefore, “4” is not referred to as the number of reserved balls.

  Then, based on the determined special symbol variation pattern (special symbol variation pattern), a special symbol variation pattern designation command is generated, and information on the special symbol variation pattern is transmitted to the effect control board 120.

  The special symbol variation pattern designation command is composed of upper byte data for identifying the command classification and lower byte data indicating the content (function) of the command. In the present embodiment, if the upper byte data is “E6H”, it indicates that a game ball has entered the first start port 6, and if the upper byte data is “E7H”, the game is input to the second start port 7. Indicates that a ball has entered. The lower byte data corresponds to the type of variation pattern. For example, when the lower byte data is “00H”, it indicates that the variation pattern is “variation pattern 1”.

  Here, in the effect control board 102, as will be described later, the effect contents in the image display device 14 and the like are determined based on the type of the special symbol variation pattern (variation pattern designation command). In the rightmost column of the special symbol variation pattern determination table shown in FIG. 9 to FIG. 12, the types of effects such as the reach effect of the image display device 14 and the like corresponding to each variation pattern and the number of pseudo consecutive times are described as a reference. .

  Here, “normal fluctuation” and “shortening fluctuation” as production contents means that multiple production symbols fluctuate at high speed and stop without reaching, and normal fluctuation and shortening. The fluctuation is different in that the shortening fluctuation is completed in a shorter fluctuation time than the normal fluctuation.

  In addition, the “reach effect” is a variation mode that gives a player a sense of expectation of jackpot, such that a part of the combination of effect symbols informing the jackpot is temporarily stopped and other effect symbols fluctuate. means. For example, when the combination of the three-digit production symbol “777” is set as the combination of the production symbols for notifying the jackpot, the two production symbols are temporarily stopped at “7”, and the remaining production symbols change. The aspect which is performing. “Temporary stop” refers to an aspect in which the player is shown as if the production symbol is stopped. In the present embodiment, multiple types of “reach effects” can be executed.

  For example, “normal reach” refers to an effect symbol (hereinafter referred to as a left effect symbol) in the left area of the display unit 140 of the image display device 14, an effect symbol (hereinafter referred to as a medium effect symbol), a center area (hereinafter referred to as a medium effect symbol). The right effect design is temporarily stopped at “7” and subsequently the right effect design is “7”, thereby forming a reach state. This is an effect in which the medium effect symbol is stopped after the medium effect symbol is scroll-displayed. In this case, “7” is temporarily stopped in the medium effect symbol, and finally the effect symbol “777” is aligned. When the variable display is stopped, it is notified that it is a “big hit”, while when the variable display is stopped in a state where the same effect symbols such as “767” are not aligned, it is notified that it is “lost”. As shown in FIG. 9, “normal reach” is a reach effect that has a high ratio when the jackpot determination result is lost, but a low ratio when the jackpot determination result is low, so-called a jackpot expectation is low. is there. Further, as shown in FIGS. 11 and 12, when a game ball enters the second starting port 7, “normal reach” is not determined.

  In addition, “long reach” is an effect that has a longer production time than “normal reach”. “Long reach” has a high ratio when the jackpot determination result is a loss, whereas the ratio determined when the jackpot is low. In “Long Reach”, the ratio determined when the jackpot judgment result is lost is lower than that for normal reach, and the ratio determined for jackpot is higher than that for normal reach. High reach production. Similarly to “normal reach”, “long reach” is not determined when a game ball enters the second starting port 7 (see FIG. 10 and FIG. 12). It can be said that “long reach” is almost never performed.

  “SP reach 1” is a reach production that develops from “normal reach”, and is a reach production that has a higher expectation of jackpot than “normal reach”. Specifically, this is a reach effect that develops from the temporarily stopped display state after temporarily displaying the combination of the “lost” effect symbols by “normal reach”.

  This “SP reach 1” will be described following the example of “normal reach” described above. After “tentative reach”, the left production symbol, middle production symbol, and right production symbol are temporarily stopped and displayed in a combination of “767”, and then the middle production. When the symbol “6” is scroll-displayed at a high speed, the symbol “6” is developed into “SP reach 1”. In “SP reach 1”, when the left effect symbol “7” and the right effect symbol “7” are displayed in a reduced size, and the medium effect symbol displayed at high speed scroll becomes “5”, “5 → 6 → 7 → 8 ”is displayed at a low speed scroll, the character A is displayed around the medium effect symbol, and a stop action for the character A to stop“ 7 ”is displayed. Then, as a result of the stop action, “7” is temporarily stopped in the medium effect symbol, and finally the variable display is stopped in a state where the effect symbol of “777” is aligned, so that “big hit” is notified. , “767”, “787”, and the display of fluctuations are stopped in a state where the production symbols are not aligned, so that “losing” is notified.

  Similarly to “SP reach 1”, “SP reach 2” is a reach effect that develops from the temporarily stopped display state after temporarily displaying a combination of “lost” effect symbols by “normal reach”. It is.

  “SP reach 2” becomes “SP reach 2” by forming a reach state after the left effect symbol, middle effect symbol, and right effect symbol of the display unit 140 of the image display device 14 start to change, and character B is displayed. In addition, after the middle production symbol is reduced and displayed larger than the left and right production symbols, the middle production symbol is enlarged and displayed larger than the left and right production symbols, and then the middle production symbol is deleted and the next middle production symbol is displayed. Repeatedly displaying the image in a reduced size. For example, the left effect symbol is temporarily stopped at “7”, the right effect symbol is temporarily stopped at “7”, and the character B begins to dance, and the middle effect symbol “5” is reduced and gradually enlarged. Then, after the display is enlarged and displayed larger than the left and right effect symbols “7”, the middle effect symbol “5” is deleted and the next effect symbol “6” is reduced and displayed. In the case of “big hit”, “7” is displayed on the medium effect symbol in the same size as the left and right effect symbols, and the display is changed with the effect symbol “777” finally arranged. By stopping, it is notified that it is a “hit”. On the other hand, in the case of “losing”, “6” or “8” is displayed on the medium effect symbol in the same size as the left and right effect symbols, and finally “767” or “787” is displayed. It is notified that the display is “lost” when the variable display is stopped in a state where the production symbols are not aligned. Note that “SP Reach 2” is a reach production that has a higher expectation of jackpot than “SP Reach 1”.

  “SPSP Reach 1” is performed after “SP Reach 1” or “SP Reach 2”, and is a reach effect that has a higher expectation of jackpot than “SP Reach 1” or “SP Reach 2”. Specifically, this is a reach effect that develops from the temporarily stopped display state after temporarily displaying a combination of the “lost” effect symbols by “normal reach” and “SP reach 1” or “SP reach 2”. .

  This “SPSP reach 1” will be described following the example of “SP reach 1” described above. After “normal reach”, the left effect symbol, the middle effect symbol, and the right effect symbol are temporarily stopped and displayed in a combination of “767”. "SP reach 1" is performed, and the variable display is temporarily stopped in the state where the effect symbols are not aligned like "767" and "787" again. Thereafter, the medium effect symbol starts to fluctuate again to develop into “SPSP reach 1”.

  In “SPSP reach 1”, a predetermined music is output from the audio output device 15, and a PV video corresponding to the music is displayed on the display unit 140. Along with the start of the display of the PV video, an effect is performed in which the medium effect symbols are displayed frame by frame in accordance with the tempo of the music. Then, the medium effect design is temporarily stopped at the end of the music. Then, “7” is temporarily stopped on the medium effect symbol, and finally, the display of variation is stopped in a state where the effect symbols of “777” are aligned, so that “big hit” is notified, while “767”. When the change display is stopped in a state where the production symbols are not aligned like “787”, it is informed that “lost”.

  “SPSP Reach 2” is performed after “SP Reach 1” or “SP Reach 2” in the same manner as “SPSP Reach 1”, and the expectation of jackpot is higher than “SP Reach 1” or “SP Reach 2”. High reach production. That is, after temporarily displaying the combination of the “losing” effect symbol by “normal reach”, the “SP reach 1” or “SP reach 2” is performed, and the combination of the “losing” effect symbol is temporarily displayed again. It develops after long.

  In the present embodiment, “SPSP reach 2” indicates that after the left effect symbol, the middle effect symbol, and the right effect symbol of the display unit 140 of the image display device 14 start to change, the music is output from the audio output device 15 and the display unit In 140, a PV video corresponding to the music is displayed. In “SPSP reach 2”, when the display of the PV video is started, the player is prompted to operate the effect button 18A. Then, the left effect symbol and the right effect symbol are temporarily stopped according to the operation of the effect button 18A, and then the middle effect symbol is temporarily stopped. Then, “7” is temporarily stopped on the medium effect symbol, and finally, the display of variation is stopped in a state where the effect symbols of “777” are aligned, so that “big hit” is notified, while “767”. When the change display is stopped in a state where the production symbols are not aligned like “787”, it is informed that “lost”. Note that “SPSP reach 2” has a higher reach of jackpot expectation than “SPSP reach 1”.

  The “full rotation reach” is a reach that is determined to be a “big hit”. After the start of variation of the left effect symbol, the middle effect symbol, and the right effect symbol of the display unit 140 of the image display device 14, “congratulations”. After displaying the character congratulating the jackpot with the message image “!”, The low-speed scrolling display is started in a state where all the combinations of the effect symbols are complete (for example, “111”, “222”, etc.). And finally, it is notified that it is a “big hit” when the variable display stops at the combination of the effect symbol of “777”. In the present embodiment, “full rotation reach” is a reach effect that can be executed only when the special figure stop symbol data is “10” or “20”, that is, when the probability variation is a big hit, “Rotation reach” is a reach effect in which it is determined that the transition to the short-time gaming state and the high-probability gaming state is made after the jackpot game ends (the probability change confirmation). However, the present invention is not limited to this, and the “full rotation reach” may be executed even in a case of a normal big hit.

  “Pseudo-continuous display count” means “number of times of pseudo-variable display execution”, and after temporarily stopping the effect design during the temporary display of the special design corresponding to one lottery lottery. The effect of performing “pseudo-variable display” that is changed again and again is called “pseudo-continuous effect”. For example, when the “pseudo consecutive number” is 1, the left effect symbol is temporarily stopped at “3”, and after the right effect symbol is temporarily stopped at “2”, the middle effect symbol is “NEXT”. Stop. Then, the variation display of the effect symbols is performed again (for example, the process from FIG. 54 (c-2) to (c-3)). In this embodiment, the pseudo-continuous effect can be executed in “SP reach 1”, “SP reach 2”, “SPSP reach 1”, “SPSP reach 2”, and “full rotation reach”. In addition, when a game ball enters the second start port 7, the number of pseudo consecutive times is 1 at most, except in the case of “full rotation reach”.

  The total number of times in the rightmost column of the special symbol variation pattern determination table shown in FIG. 9 to FIG. 12 describes the number of times the pseudo variation display is performed during one variation display, and “before reach” The number of times of “pre-reach pseudo-variable display” is described, and “after reach” describes the number of times of “post-reach pseudo-variable display”.

  When the “total number of times” is 1, the effect symbol variation display and stop display are performed twice (for example, the process from FIG. 54 (c-1) to (c-4)). In the case of two times, the effect symbol variation display and stop display are performed three times (for example, the process from FIG. 55 (f-1) to (f-7)).

  The “pre-reach pseudo-variable display” is a pseudo-variable display performed before executing the reach effect, and the “post-reach pseudo-variable display” is a pseudo-variable display performed after the reach effect is performed. For example, if the “total number of times” of the “number of pseudo-continuations” is 2, the “pre-reach pseudo-variation display” is 1, and the “post-reach pseudo-variation display” is 1, the left effect design is “ After a temporary stop at “3” and then a temporary stop at “2” for the right effect symbol, a temporary stop at “NEXT” for the middle effect symbol. Then, a re-variable display is performed, the left effect symbol is temporarily stopped at “2”, the right effect symbol is temporarily stopped at “2”, and after “normal reach” is performed, the middle effect symbol is “NEXT”. ”To temporarily stop. Then, the variation display of the effect symbol is performed again (for example, the process from FIG. 55 (g-2) to (g-8)). In this case, the pseudo-change display from the temporary stop of the left effect symbol, the middle effect symbol, and the right effect symbol at “3”, “NEXT”, “2” to the next temporary stop of each effect symbol is “reach”. “Pseudo-variable display”. Then, the pseudo variation display after the left effect symbol, the middle effect symbol, and the right effect symbol are temporarily stopped at “2”, “NEXT”, and “2” respectively becomes “post-reach pseudo variation display”. That is, in the present embodiment, the pseudo-variable display when the pseudo-variable display is performed is triggered by “pre-reach pseudo-variable” triggered by the temporary stop at “NEXT” when any of the effect symbols is not formed. Display ". On the other hand, the pseudo-variable display when the pseudo-variable display is performed in response to the temporary stop at “NEXT” in the state where the reach state is formed is “post-reach pseudo-variable display”.

  In addition, during the variation display of the effect symbol, a “turning effect” is performed for determining whether or not the pseudo variation display is performed, that is, whether or not the variation display is continued without being ended. The “turning effect” is performed using the final temporary stop effect design symbol, and the fact that the pseudo temporary variation display is performed (the variable display continues) is notified when the final temporary stop effect design symbol is “NEXT”. Then, by temporarily stopping with a type other than “NEXT” (for example, a number such as “2”), the pseudo-variable display is not performed, and it is informed that the variable display has ended (gase effect). That is, by the time the effect symbol stops at “NEXT”, the other effect symbols are already temporarily stopped, and the “stopping effect” is performed using the final stop effect symbol. For example, the left effect symbol is temporarily stopped at “2”, and then the right effect symbol is temporarily stopped at “3”. Then, the “effect effect” is performed on the middle effect symbol, and then “NEXT” is temporarily stopped. In this case, it is referred to as “buzzing effect using medium effect symbols”. Also, if the left effect symbol and the middle effect symbol are temporarily stopped first, the “effect effect” is performed on the right effect symbol and then “NEXT” is temporarily stopped. .

  In the present embodiment, there are two types of “buzzing effects”, and in the case of performing a pseudo-continuous effect, one of “button-blowing effects” and “slacking effects” is executed. The “button strike effect” means that the two effect symbols are temporarily stopped and the remaining effect symbols (final stop effect symbols) are variably displayed, and the effect button 18A is displayed on the display unit 140 of the image display device 14. An image is displayed, and a message image prompting the player to operate the effect button 18A, such as “Press the button”, is displayed. Then, when the operation of the effect button 18A is detected within a predetermined time after the image is displayed on the display unit 140, when the pseudo-variable display is performed, the final stop effect symbol is temporarily stopped at “NEXT”. When pseudo-variable display is not performed, the display is stopped with other symbols. Thereby, it is possible to give an impression to the player that the pseudo-variable display can be performed by stopping and displaying “NEXT” by his / her own operation. If the operation button 18A is not detected within a predetermined time, the final stop effect symbol is stopped and displayed after the predetermined time has elapsed. In the “smoothing effect”, two effect symbols are temporarily stopped, and the final stop effect symbol is gradually scroll-displayed while the final stop effect symbol is variably displayed. Then, once the final effect design is stopped and displayed before "NEXT", when the final effect design is scrolled at high speed and pseudo-variable display is performed, the final stop effect design is temporarily stopped at "NEXT" When pseudo-variable display is not performed, the display is stopped with other symbols. Accordingly, it is possible to give a great expectation that the pseudo-variable display may be performed to the player when the final effect symbol is temporarily stopped and then scrolled at high speed.

  In the present embodiment, in order to prevent a variation effect with a long variation time in the short-time game state and a variation effect having a long variation time from being performed, a game ball is placed at the second start opening 7. When entering the ball, the maximum number of pseudo-reams is one, except when full rotation reach is reached.

  When the jackpot determination result is lost and the reach determination random value is “0 to 59”, the variation pattern of the special symbol is “variation pattern 1” or “variation pattern 2” depending on the number of reserved balls. Is determined, and the effect of “normal fluctuation” or “shortening fluctuation” is performed. When the jackpot determination result is lost and the reach determination random value is “60 to 79”, the variation pattern of the special symbol is “variation pattern 1” or “variation pattern” depending on the number of reserved balls. “3” is determined, and “normal fluctuation” or “normal reach” is produced.

Further, when the jackpot determination result is a loss and the reach determination result is “execution of reach production” (reach determination random value = 80 to 99), the variation pattern of the special symbol is the special diagram variation disturbance. Based on the numerical value, one of “variation pattern 3” to “variation pattern 28” is determined, and reach production is “normal reach” “long reach” “SP reach 1” “SP reach 2” “SPSP reach 1” “SPSP” Reach 2 ".
Specifically, the “variation pattern 3” is determined at a rate of 25%, and the reach production is “normal reach”. Further, the “variation pattern 4” is determined at a rate of 15%, and the reach effect is “long reach”.

  In addition, “variation patterns 5 to 10” are determined at a rate of 15%, and the reach effect is “SP reach 1”. More specifically, it is determined as “fluctuation pattern 5” in which the pseudo-continuous effect is not performed at the rate of 4% and the pseudo-continuous effect is not performed, and the pre-reach pseudo-variable display is performed once at the rate of 3%. “Fluctuation pattern 6” is determined, and “variation pattern 7” in which the pseudo-variable display after reach is performed once at a rate of 2%, and pseudo-variable display before reach is performed twice at a rate of 3%. “Fluctuation pattern 8” is determined to perform a pseudo-continuous effect, and “Fluctuation pattern 9” is performed to perform a pseudo-variable display of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 2%. Then, the post-reach pseudo-variable display at the rate of 1% is determined to be “variation pattern 10” that performs the pseudo continuous effect twice.

  Further, “variation patterns 11 to 16” are determined at a rate of 15%, and the reach effect is “SP reach 2”. More specifically, it is determined as “fluctuation pattern 11” in which the pseudo-continuous effect is not performed at the rate of 4% and the pseudo-continuous effect is not performed, and the pre-reach pseudo-variable display is performed once at the rate of 3%. “Fluctuation pattern 12” is determined and “variation pattern 13” in which the pseudo-variation display after reach is performed once at a rate of 2%, and pseudo-variation display before reach is performed twice at a rate of 3%. “Fluctuation pattern 14” for performing a pseudo-continuous effect of “1”, and “variation pattern 15” for performing a pseudo-variable display of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 2%. Then, the post-reach pseudo-variable display is determined to be “variation pattern 16” that performs the pseudo-continuous effect twice.

  Further, “variation patterns 17 to 22” are determined at a rate of 15%, and the reach effect is “SPSP reach 1”. More specifically, it is determined to be “fluctuation pattern 17” in which the pseudo-continuous effect is not performed at the rate of 4% and the pseudo-continuous effect is not performed, and the pseudo-variable display before reach is performed once at the rate of 3%. “Fluctuation pattern 18” is determined and “variation pattern 19” in which the pseudo-variation display after reach is performed once at a rate of 2%, and pseudo-variation display before reach is performed twice at a rate of 3%. “Fluctuation pattern 20” for performing a pseudo-continuous presentation of “2”, and “variation pattern 21” for performing a pseudo-continuous presentation of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 2%. Then, the post-reach pseudo-variable display at the rate of 1% is determined as the “variable pattern 22” that performs two pseudo-continuous effects.

  Further, the “variation patterns 23 to 28” are determined at a rate of 15%, and the reach effect is “SPSP reach 2”. More specifically, it is determined to be “variation pattern 23” in which the pseudo-continuous effect is not performed at the rate of 4% and the pseudo-continuous effect is not performed, and the pre-reach pseudo-variable display is performed once at the rate of 3%. “Fluctuation pattern 24” is determined and “variation pattern 25” in which the pseudo-variation display after reach is performed once at a rate of 2%, and pseudo-variation display before reach is performed twice at a rate of 3%. “Fluctuation pattern 26” for performing a pseudo-continuous effect of “2”, and “variation pattern 27” for performing a pseudo-variable display of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 2%. Then, the post-reach pseudo-variable display at the rate of 1% is determined to be the “variable pattern 28” in which the pseudo continuous effect is performed twice.

  In this way, when the jackpot determination result is a loss and the reach performance is any one of “SP reach 1”, “SP reach 2”, “SPSP reach 1”, and “SPSP reach 2”, the number of pseudo-reams is 0. The ratio of not performing pseudo-continuous production at the highest time is the highest. Further, when performing the pseudo-continuous effect, the ratio that the pseudo-variable display after reach is zero is the highest, and the ratio that the pseudo-variable display after reach is two is the lowest. Therefore, when the jackpot determination result is lost, it is easy to perform a pseudo-continuous effect with a small number of pseudo-variable display after reach.

If the jackpot determination result is a jackpot, the reach effect is always executed in this embodiment, so the random number value for reach determination is not referred to, and the type of special symbol to be stopped (special symbol stop symbol data) and special symbol Based on the random number value for fluctuation in the figure, one of “fluctuation pattern 29” to “fluctuation pattern 56” is determined, and the reach production is “normal reach” “long reach” “SP reach 1” “SP reach 2” “SPSP reach” 1 ”,“ SPSP reach 2 ”, or“ full rotation reach ”.
Specifically, the “variation pattern 29” is determined at a rate of 2%, and the reach effect is “normal reach”. Also, the “variation pattern 30” is determined at a rate of 3%, and the reach effect is “long reach”.

  Further, “variation patterns 31 to 36” are determined at a rate of 10%, and the reach effect is “SP reach 1”. More specifically, it is determined to be “variation pattern 31” in which the number of pseudo-continuous effects is 0 at a rate of 1% and the pseudo-continuous effect is not performed. “Fluctuation pattern 32” is determined and “variation pattern 33” in which the pseudo-variation display after reach is performed once at a rate of 2% and pseudo variation display before reach is performed twice at a rate of 1%. “Fluctuation pattern 34” for performing a pseudo-continuous presentation of “No.” and “Fluctuation pattern 35” for performing a pseudo-continuous presentation of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 2%. Then, the pseudo-variable display after reaching at a rate of 3% is determined as the “variation pattern 36” that performs the pseudo-continuous effect twice.

  Further, the “variation patterns 37 to 42” are determined at a rate of 10%, and the reach effect is “SP reach 2”. More specifically, it is determined to be “variation pattern 37” in which the pseudo-continuous effect is not performed at the rate of 1% and the pseudo-continuous effect is not performed, and the pre-reach pseudo-variable display is performed once at the rate of 1%. “Fluctuation pattern 38” is determined, and “variation pattern 39” in which the pseudo-variation display after reach is performed once at a rate of 2%, and pseudo-variation display before reach is performed twice at a rate of 1%. “Fluctuation pattern 40” for performing a pseudo-continuous effect of “2”, and “variation pattern 41” for performing a pseudo-variable display of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 2%. Then, the pseudo-variable display after reaching at a rate of 3% is determined to be the “variable pattern 42” that performs the pseudo continuous effect twice.

  Further, the “variation patterns 43 to 48” are determined at a rate of 20%, and the reach effect is “SPSP reach 1”. More specifically, it is determined to be “variation pattern 43” in which the number of pseudo-continuous effects is 0 at a rate of 2% and the pseudo-continuous effect is not performed. “Fluctuation pattern 44” is determined, and “variation pattern 45” in which the pseudo-variable display after reach is performed once at a rate of 4%, and pseudo-variable display before reach is performed twice at a rate of 2%. "Fluctuation pattern 46" is determined to perform the pseudo-continuous effect of 4%, and is determined to be "Fluctuation pattern 47" that performs pseudo-variable display of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 4%. Then, the pseudo-variable display after reach at a rate of 6% is determined as the “variable pattern 48” in which the pseudo continuous effect is performed twice.

  Further, “variation patterns 49 to 54” are determined at a rate of 25%, and the reach effect is “SPSP reach 2”. More specifically, it is determined to be “variation pattern 49” in which the pseudo-continuous effect is not performed at the rate of 3% and the pseudo-continuous effect is not performed, and the pre-reach pseudo-variable display is performed once at the rate of 3%. “Fluctuation pattern 50” is determined, and “fluctuation pattern 51” in which the pseudo-variation display after reach is performed once at a rate of 5%, and pseudo-variation display before reach is performed twice at a rate of 3%. “Fluctuation pattern 52” for performing a pseudo-continuous presentation of 5%, and “Fluctuation pattern 53” for performing a pseudo-continuous presentation of one pre-reach pseudo-variable display and one post-reach pseudo-variable display at a rate of 5%. Then, the pseudo-variable display after reach at a rate of 6% is determined as the “variable pattern 54” that performs the pseudo continuous effect twice.

  In addition, “variation patterns 55 to 56” are determined at a rate of 30%, and the reach effect is “full rotation reach”. More specifically, it is determined to be “variation pattern 55” which performs pseudo-continuous production of 10% of pre-reach pseudo-variation display and 2 post-reach pseudo-variation display, and 20% of post-reach pseudo-variation. The display is determined to be “fluctuation pattern 56” for performing the pseudo-continuous effect three times.

  In the present embodiment, the determination ratio of the variation pattern in the case of the special figure stop symbol data “11” or “12” is almost the same as that in the case of the special figure stop symbol data “10”. The difference is that “reach” is not determined. Therefore, “full rotation reach” is a reach effect that can be executed only in the case of a probable big hit.

  Thus, when the jackpot determination result is a jackpot, the determination ratio of “normal reach” is the lowest and the determination ratio of “SPSP reach 2” is the highest. Further, “SP reach 1” has a lower determination rate than “SP reach 2”, and “SPSP reach 1” has a lower determination rate than “SPSP reach 2”. Furthermore, the determination ratio of “SP reach 1” and “SP reach 2” is lower than the determination ratio of “SPSP reach 1” and “SPSP reach 2”. Accordingly, “normal reach” is the reach effect with the lowest jackpot expectation level, and “SPSP reach 2” is the reach effect with the highest jackpot expectation level excluding “full turn reach”. Also, “SP reach 2” has a higher jackpot expectation level than “SP reach 1”, and “SPSP reach 2” has a higher jackpot expectation level than “SPSP reach 1”. Furthermore, the jackpot expectation degree of “SPSP reach 1” and “SPSP reach 2” is higher than the jackpot expectation degree of “SP reach 1” and “SP reach 2”.

  Further, when the jackpot determination result is a jackpot and the reach effect is any one of “SP reach 1”, “SP reach 2”, “SPSP reach 1”, and “SPSP reach 2”, the ratio of not performing the pseudo-continuous effect The ratio of the pseudo-variable display before reach to the pseudo continuous effect of one time and the pseudo continuous effect of two times before the pseudo-variable display before reach are the lowest. On the other hand, the ratio of the pseudo-variable display after reach is the highest in the ratio of performing the pseudo-continuous presentation twice, and the ratio of performing the pseudo-variable display of one pre-reach pseudo-variable display and one post-reach pseudo-variable display is high, Next, the ratio of the pseudo-variable display after reach to a single pseudo-continuous effect is high. Thus, when the jackpot determination result is a jackpot, the number of pseudo-variable displays after reach tends to increase.

  When the total number of pseudo-continuous effects is 2, the pseudo-variable display after reach has the highest ratio of two pseudo-continuous effects, and then one pre-reach pseudo-variable display and one post-reach pseudo-variable display. The ratio of performing pseudo-continuous production is high. Therefore, the post-reach pseudo-variable display has a higher rate of execution after the second time when the pseudo-variable display is performed twice. Further, in the case where the pseudo-variable display is performed twice, the second pseudo-variable display has a higher ratio of executing the post-reach pseudo-variable display.

  As described above, in the present embodiment, the effect content to be executed on the effect control board 102 is determined based on the type of the special symbol variation pattern (variation pattern designation command). In particular, there are a plurality of types of reach effects and pseudo-continuous effects. When reach effects are executed, the types of reach effects and pseudo-continuous effects corresponding to the change pattern designation command are executed.

  FIG. 13 and FIG. 14 are diagrams showing a pre-judgment table for pre-determining the result of the jackpot lottery. As shown in FIG. 13 and FIG. 14, the preliminary determination table includes a lottery lottery result, a special symbol (special symbol stop symbol data), a reach determination random number value, a special symbol variation random value, and a start port. A winning designation command is associated.

  Here, it is possible to determine in advance whether it is a “big hit” or “losing” by using a random number for determining the special symbol obtained when the game ball enters the start opening, and by using the special symbol stop symbol data, The type and presence / absence of transition to the high-probability gaming state or the short-time gaming state can also be determined in advance. Furthermore, the production contents (whether the occurrence of reach, the type of reach production) and the like can be determined in advance by the reach determination random number value and the special figure variation random value. Thus, the information on the type of jackpot and the contents of the effect (planned variation pattern) can be discriminated in advance.

  The main CPU 110a refers to the prior determination table shown in FIGS. 13 and 14, and determines the start winning information based on the special figure stop symbol data, the reach determination random number value, and the special figure variation random value. Then, based on the determined start winning information, a start opening winning designation command is generated for determining in advance the result of the jackpot lottery or the variation pattern.

  Here, the start opening winning designation command is composed of upper byte data for identifying the command classification and lower byte data indicating the content (function) of the command. In the present embodiment, if the upper byte data is “E1H”, it indicates that a game ball has entered the first start port 6, and if the upper byte data is “E2H”, the game is input to the second start port 7. Indicates that a ball has entered. The lower byte data corresponds to the production type. For example, when the lower byte data is “02H”, the planned variation pattern is “variation pattern 3”.

  13 and 14 is similar to the special symbol variation pattern determination table shown in FIGS. However, the prior determination table shown in FIGS. 13 and 14 is used when the game ball enters the start opening, whereas the special symbol variation pattern determination table shown in FIGS. 9 to 12 is used when the special symbol variation starts. Each judgment time is different. In addition, it is also different whether or not “the number of reserved balls” is referred to.

  FIG. 15A to FIG. 15F show an example of a table used when controlling a normal symbol game based on winning to the first winning gate 9 or the second winning gate 10.

  FIG. 15A is a diagram illustrating an example of the hit determination table. The hit determination is to determine whether or not to execute an auxiliary game that involves opening the second start port 7. As will be described later, the winning determination is performed based on a winning determination random number acquired based on the passing of the winning gates 9 and 10 of the game ball.

  The hit determination table is divided according to the start opening winning easiness. Specifically, the hit determination table is divided into a hit determination table referred to in the non-time-saving gaming state and a hit determination table referred to in the time-saving gaming state.

  In each hit determination table, a hit determination value and a determination result are uniquely associated and stored. By collating the acquired random number for hit determination with the hit determination table, either “winning” or “losing” is determined. When “winning” is won, an auxiliary game with the opening of the second start port 7 is executed.

  FIG. 15B is a diagram illustrating an example of a normal symbol determination table. The normal symbol determination is to determine a normal symbol to be stopped and displayed on the normal symbol display device 22. The normal symbol determination table is divided according to the result of winning determination (winning and losing).

  Each normal symbol determination table stores a normal symbol determination value and a normal symbol that is stopped and displayed in a uniquely associated manner. As will be described later, the normal symbol to be stopped and displayed is determined by comparing the normal symbol determination random number acquired when the game ball passes the winning gates 9 and 10 with the normal symbol determination table. As the normal symbol identification information to be stopped and displayed, the normal symbol stop symbol data and the normal effect symbol designation command are set.

  The normal stop symbol data is used in the processing in the main control board 101, and the normal effect symbol designating command is transmitted to the effect control board 102 and used in the processing in the effect control board 102.

  FIG. 15C determines a variation pattern of a normal symbol (hereinafter referred to as a “normal diagram variation pattern”) associated with a time required to display a variation of the normal symbol (hereinafter referred to as a “normal diagram variation time”). It is a figure which shows the common figure fluctuation pattern determination table for this. The normal variation pattern determination table is composed of a general variation variation determination table that is referred to in the non-short game state and a general variation pattern determination table that is referred to in the short time gaming state.

  In each table, a common pattern variation pattern determination value and one or a plurality of common map variation patterns are uniquely associated and stored. As will be described later, the normal variation pattern is determined by collating the random number for determining the normal variation pattern acquired when the game ball passes the winning gates 9 and 10 with the normal variation variation determination table. The

  A command change pattern designation command is set corresponding to the command map change pattern. It is transmitted to the effect control board 102 after the normal pattern variation pattern is determined. When the production control board 102 receives the normal symbol variation pattern designation command, the normal symbol variation display is started from now on, and the determination result of the normal symbol determination relating to the variation display of the ordinary symbol is recognized. it can.

  The usual pattern change pattern designation command is composed of 1-byte MODE data for identifying the gaming state related to the current start opening winning ease, and 1-byte DATA data for identifying the usual figure change pattern. Yes. With respect to the usual variation pattern designation command, if the MODE data is “D6H”, it represents a non-short-time gaming state, and if the MODE data is “D7H”, it represents a time-short gaming state.

  FIG. 15D shows an example of the auxiliary game reference data determination table. This table stores data (auxiliary game reference data) that is referred to when performing an auxiliary game. As shown in FIG. 15D, in the auxiliary game reference data determination table, the combination of the current start port winning easiness and the usual figure stop symbol data is associated with the auxiliary game reference data. That is, the auxiliary game reference data includes information regarding the start opening winning easiness state and the result of the normal symbol determination when the normal symbol determination is performed.

  FIG. 15E is a diagram illustrating an example of an auxiliary game control table used when controlling the auxiliary game.

  The auxiliary game control table stores conditions for controlling the auxiliary game. As conditions for controlling the auxiliary game, an opening time, which is a period from when the auxiliary game is started to when the second opening 7 is first opened, and transmission to the effect control board 102 at the start of the opening. Opening designation command, type of table used to control opening / closing of the second starting port 7, ending time, which is a period from the end of the last opening of the second starting port 7 to the end of the auxiliary game, And the ending designation | designated command transmitted to the production | presentation control board 102 at the time of ending start is set. The conditions for controlling these auxiliary games are associated with auxiliary game reference data.

  FIG. 15 (f) is a diagram showing an example of a second start port opening / closing control table for auxiliary games used when controlling opening / closing of the second start port 7. Conditions for controlling the opening and closing of the second start port 7 during the auxiliary game are stored in the second start port opening / closing control table for the auxiliary game. As conditions for controlling the opening and closing of the second starting port 7, a general electric operation number (D) which is an opening number (operation of the second starting port control device 70) number of the second starting port 7 in the auxiliary game, 2 Opening time and closing time (operation time / non-operation time) of the start port 7 are set.

(Description of types of jackpot games)
The jackpot game will be described. The jackpot game is divided into a plurality of types depending mainly on the opening / closing mode of the big winning opening 8. In the present embodiment, as described above, it is divided into “8R / 8R jackpot”, “0R / 8R jackpot”, and “15R / 15R jackpot”.

  In the jackpot game, a round game involving one or more opening of the big winning opening 8 is executed a predetermined number of times. In each round game, the number of times that the special winning opening 8 can be opened (hereinafter referred to as the maximum number of times of opening) and the total time that can be opened (hereinafter referred to as the maximum opening time) are set in advance. The reason that “can be opened” is that the number of game balls that can enter the big winning opening 8 during one round game is limited (for example, 9). Even if the maximum opening time has not elapsed, the special winning opening 8 is closed and the round game may end. It should be noted that the maximum number of times and the maximum opening time of the big winning opening 8 in each round game may or may not be unified for each jackpot game.

(Description of game conditions)
Next, game conditions that are conditions when the game progresses will be described. In the present embodiment, the jackpot winning probability and the start opening winning easiness are set as the game conditions. As for the jackpot winning probability, the game progresses under the low-probability gaming state or the high-probability gaming state, and the game ball progresses under the short-time gaming state or the non-short-time gaming state with respect to the ease of winning the game opening. To do. The initial (when the RAM is cleared) gaming condition is set to a low probability gaming state and a non-time saving gaming state, and this low probability gaming state and a non-time saving gaming state are referred to as a normal gaming state.

  In the present embodiment, the low-probability gaming state with respect to the jackpot winning probability means that the jackpot winning probability in the jackpot determination is set to be relatively disadvantageous to the player at 1/350. On the other hand, the high probability gaming state is that the jackpot winning probability is higher than that of the low probability gaming state, that is, set to 1/40 which is relatively advantageous to the player. Therefore, when the jackpot winning probability is in a high probability gaming state, winning a jackpot is easier than in the low probability gaming state, and the number of winning jackpots per unit time is relatively large, which is advantageous to the player. It can be said that it is a state.

  The non-time-saving gaming state is a state in which the start opening winning easiness is normal. Specifically, in the non-time-saving gaming state, the normal time variation time is set to 12 seconds, and the operation time (second start) of the second start port control device 70 that operates when “winning” is won in the hit determination. The sum of the opening time of the mouth 7) is set to 0.2 seconds or 5.1 seconds, and the probability of winning in the hit determination for the normal symbol is set to 1/50. Note that the “total opening time” is that the second start port 7 may be opened multiple times for each win, and a game ball can be won for each win. This is because the number is limited, and when a game ball is won, it closes without waiting for the opening time.

  On the other hand, in the short-time gaming state, the opening time of the second starting port 7 per unit time (the operating time of the second starting port control device 70) is longer than in the non-short-time gaming state, and the second starting port 7 Is a gaming state that tends to be open. Due to the relatively high start opening prize ease, the number of times the second special symbol determination can be performed per unit time increases. Under the same jackpot winning probability, the number of executions of the second special symbol determination per unit time inevitably increases the number of winning jackpots per unit time. It can be said that this is an advantageous state for the player as compared to the gaming state.

  As described above, in the present embodiment, in the short-time gaming state, the normal variation time is set to 3.0 seconds, the total maximum opening time of the second start port 7 is set to 5.2 seconds, The probability of winning is set to 1/5. That is, all the components of the start opening winning ease are set to be more advantageous to the player than the non-time-saving gaming state. In the short-time gaming state, the second start port 7 is opened twice via a 1.0 second closure (interval). However, there is no such closure, and it may be opened only once. Moreover, the closure may be provided a plurality of times.

  In this embodiment, when a game ball enters the start openings 6 and 7, three prize balls can be obtained, but the player fires the game ball by operating the appropriate launch handle 32. However, the number of game balls possessed by the player tends to decrease. However, in the short-time gaming state, since it is easier to enter the second starting port 7 than in the non-short-time gaming state, it is possible to suppress a decrease in the number of game balls possessed by the player. That is, from the viewpoint of the number of game balls possessed by the player, the short-time game state is set to be more advantageous for the player than the non-short-time game state.

  In this way, the type of jackpot game and the game conditions newly set after the jackpot game (the combination of the low probability game state / high probability game state and the non-short-time game state / time-short game state) are determined by winning the jackpot. It is determined. In view of this, the substantial jackpot type (the jackpot type based on the profits enjoyed by the player) includes the type of jackpot game to be executed and the game conditions newly set after the jackpot game ends ( It can be said that it is a combination with (gaming state). Therefore, hereinafter, apart from the type of jackpot based on the special figure stop symbol data, based on the combination of the type of jackpot game derived by the jackpot and the game conditions after the jackpot game, that is, based on the type of profit that the player enjoys The jackpot type can be classified.

  For example, “8R / 8R jackpot” is executed by winning the jackpot, and then the jackpot that is set to the high probability gaming state and the short-time gaming state is referred to as “8R / 8R probability variable jackpot”. Is executed, and then the jackpot that is set to the high-probability gaming state and the short-time gaming state is referred to as “0R / 8R probability variable jackpot”, and “8R / 8R jackpot” is executed by winning the jackpot, and then the low-probability gaming state The jackpot that is set to the short-time gaming state is referred to as “8R / 8R normal jackpot”.

(Main processing of main control board)
The main process of the main control board 101 will be described with reference to FIG.

  When power is supplied from the power supply board 107 to the main CPU 101a, a system reset occurs in the main CPU 101a, and the main CPU 101a performs the following main processing.

  First, in step S10, the main CPU 101a performs an initialization process. In this process, the main CPU 101a reads a startup program from the main ROM 101b and initializes each storage area of the main RAM 101c in response to power-on.

  In step S20, the main CPU 101a updates the special figure fluctuation random number for determining the special figure fluctuation pattern in the fluctuation display of the special symbol composed of the reach determination random number and the special figure fluctuation pattern determination random number. .

  In step S30, the main CPU 101a updates an initial value random number including an initial value random number for jackpot determination, an initial value random number for special symbol determination, an initial value random number for hit determination, and the like. Thereafter, the processes of step S20 and step S30 are repeated until a predetermined interrupt process is performed.

(Timer interrupt processing of main control board)
The timer interrupt process of the main control board 101 will be described with reference to FIG. The following timer interrupt processing is executed by generating a clock pulse every predetermined period (4 milliseconds) by the reset clock pulse generation circuit provided on the main control board 101.

  First, in step S100, the main CPU 101a saves the information stored in the register of the main CPU 101a to the stack area.

  In step S110, the main CPU 101a performs a special game variable counter update process, a special symbol stop time update process, an opening time update process, an open / close time update process for the special winning opening 8, and the like. And the time control process which updates the auxiliary | assistant game timer counter which performs the update process of the change time of a normal symbol, the update process of the stop time of a normal symbol, the update process of the opening / closing time of the 2nd start port 7, etc. is performed.

  In step S120, the main CPU 101a updates a specific random number including a jackpot determining random number, a special symbol determining random number, and a winning determining random number.

  In step S130, the main CPU 101a performs an initial value random number update process for updating the jackpot determining initial value random number, the special symbol initial value random number, and the winning determination initial value random number.

  For updating various random numbers, the random number is updated by adding “1” to a random number counter provided for each type of random number. Various random numbers have a random number range. The random number range is from “0” to the maximum value determined for the random number. In the update of the random number, when the random number indicated by the random number counter is the maximum value in the random number range, the random number counter is reset to “0” without adding “1”, and each random number value is newly updated from the initial random number at that time. Update to

  In step S200, the main CPU 101a performs input control processing. In this process, the main CPU 101a performs an input control process for determining whether or not a new valid signal is transmitted from a predetermined detection sensor. Details will be described later with reference to FIGS.

  In step S300, the main CPU 101a performs the first special symbol display device 20, the second special symbol display device 21, the first special symbol hold display device 23, the second special symbol hold display device 24, and the special prize opening control device 80. Special symbol special electric control processing (special symbol related processing) for performing the above control (control of the special symbol system device). Details will be described later with reference to FIGS.

  In step S400, the main CPU 101a performs a normal signal normal power control process (normal signal control) for controlling the normal symbol display device 22, the normal symbol hold display device 25, and the second starting port control device 70 (control of the normal symbol system device). Perform symbolic processing. Details will be described later with reference to FIGS. 34 to 37.

  In step S500, the main CPU 101a performs a payout control process. In this process, the main CPU 101a determines whether or not the winning ball counters corresponding to the starting port (the first starting port 6 and the second starting port 7), the big winning port 8 and the general winning port 11 have exceeded “0”. If it exceeds “0”, a prize ball request signal indicating the number of prize balls corresponding to each prize opening is transmitted to the payout control board 103. When a prize ball signal is transmitted, an update process for subtracting “1” from the prize ball counter related to the signal is performed.

  In step S600, the main CPU 101a, external signal output control data for outputting information related to the game as an external signal to an external device such as the game information display device 700, the second start port opening / closing solenoid 70B, and the big prize opening / closing solenoid Drive control data for driving 80B (start opening / closing solenoid drive data and big prize opening / closing solenoid drive data), and predetermined symbols on the symbol display devices 20, 21, 22 and the hold display devices 23, 24, 25 Data creation processing of display control data (special symbol display data, normal symbol display data, special symbol hold display data, normal symbol hold display data) for display is performed.

  In step S700, the main CPU 101a performs output control processing. In this process, first, a port output process for outputting a signal based on the external signal output control data and the drive control data created in S600 is performed. Subsequently, in order to light each LED of the symbol display devices 20, 21, and 22 and the hold display devices 23, 24, and 25, display device output processing for outputting a signal based on the display control data created in step S600 is performed. . Finally, command transmission processing for transmitting the command set in the transmission buffer of the main RAM 101c to another board is also performed.

  In step S800, the main CPU 101a restores the information saved in step S100 to the register of the main CPU 101a.

  The input control process will be described with reference to FIG. First, in step S210, the main CPU 101a determines whether or not a detection signal is input from the general winning opening detection sensor 11a, that is, whether or not a game ball has entered the general winning opening 11. When the main CPU 101a does not input a detection signal from the general winning opening detection sensor 11a, the main CPU 101a moves the process to step S220. When the main CPU 101a receives a detection signal from the general winning opening detection sensor 11a, the main CPU 101a updates the general winning opening prize ball counter used for winning balls by adding predetermined data.

  In step S220, the main CPU 101a determines whether or not the detection signal from the big winning opening detection sensor 8a has been inputted, that is, whether or not the game ball has entered the big winning opening 8. Details will be described later with reference to FIG.

  In step S230, the main CPU 101a determines whether a detection signal from the first start port detection sensor 6a has been input, that is, whether or not a game ball has entered the first start port 6. Details will be described later with reference to FIG.

  In step S240, the main CPU 101a determines whether or not the detection signal from the second start port detection sensor 7a has been input, that is, whether or not the game ball has entered the second start port 7. Details will be described later with reference to FIG.

  In step S250, the main CPU 101a determines whether or not the detection signals from the winning gate detection sensors 9a and 10a are input, that is, whether or not the game ball has passed the winning gate 10. Details will be described later with reference to FIG.

  Next, the special winning opening detection signal input process will be described with reference to FIG. In step S220-1, the main CPU 101a determines whether or not a detection signal is input from the special winning opening detection sensor 8a. When a detection signal is input from the special winning opening detection sensor 8a, predetermined data is added to the special winning opening prize ball counter used for the winning ball and updated, and the process proceeds to step S220-2 to detect the detection signal. If no is input, the special winning opening detection signal input processing is terminated.

  In step S220-2, the main CPU 101a determines whether or not the current game is a big hit game. Specifically, the main CPU 101a determines whether or not the special figure special electric processing data = 3, and if the special figure special electric processing data = 3 and the current is a big hit game, the process is performed in step S220-3. If the current game is not a big hit game, the process proceeds to step S220-9.

  In step S220-3, the main CPU 101a adds “1” to the counter value (C) of the round winning counter for counting the game balls won in the big winning opening 8, and updates it.

  In step S220-4, the main CPU 101a adds "1" to the counter value (D) of the big prize opening detection counter for counting whether or not the game ball won in the big prize opening 8 is over-winning and updates it. .

  In step S220-5, the main CPU 101a determines whether or not the counter value (D) of the special winning opening detection counter is less than “10” (“1” or more and “9” or less). Then, if the counter value (D) of the big prize opening detection counter is less than “10”, the process proceeds to step S220-6, and if the counter value (D) of the big prize opening detection counter is “10” or more, step is performed. The processing is moved to S220-7.

  In step S220-6, the main CPU 101a generates a big prize winning designation command indicating that a game ball has won while the big prize winning opening 8 is open in the round game of the big hit game, and stores the transmission data for production in the main RAM 101c. Set in area (send buffer). By receiving this command, the effect control board 102 can execute a grand prize winning process.

  In step S220-7, the main CPU 101a determines whether or not the counter value (D) of the big prize opening detection counter is a value between “10” and “14”. If the main CPU 101a determines that the counter value (D) is not less than “10” and not more than “14”, the main CPU 101a shifts the processing to step S220-8, and the counter value (D) is not less than “10” and not more than “14”. If it is determined that the value is not the following value ("15" or more), the process proceeds to step S220-9.

  In step S220-8, the main CPU 101a generates an over-winning designation command indicating that a game ball has won the big winning opening 8 even after the opening of the big winning opening 8 in the jackpot game is finished, and the main RAM 101c transmits the effect. Set in the data storage area (transmission buffer). In the present embodiment, the special winning opening 8 is closed when the number of winning prizes in the special winning opening 8 reaches nine, which is the prescribed number in the round game. The over winning is to win the big winning opening 8 in a short time from when the predetermined number of round games reaches nine, until the big winning opening 8 is closed. The effect control board 102 can execute the over winning process by receiving this command.

  In step S220-9, the main CPU 101a confirms that a game ball has won the big prize opening 8 even though the big hit game is not being played, or that a predetermined number or more over wins have been made during the round game of the big win game. The error winning designation command shown is generated and set in the effect transmission data storage area (transmission buffer) of the main RAM 101c. The effect control board 102 can execute an error winning process by receiving this command.

  Next, the first start port detection signal input process will be described with reference to FIG. In step S231, the main CPU 101a determines whether or not there is a valid detection signal from the first start port detection sensor 6a. If there is no valid detection signal, the process ends. If there is a valid detection signal, the start opening prize counter is updated by adding “1” in step S232, and the first start opening entering the main RAM 101c is updated. The first start port winning flag is turned ON in the flag storage area.

  In step S233, the main CPU 101a determines whether or not the counter value of the first special figure hold number counter for counting the first special figure hold number (U1) is smaller than 4 (upper limit value). If the main CPU 101a determines that the counter value (U1) is not less than 4, the main CPU 101a terminates the processing. If the main CPU 101a determines that the first special figure hold number (U1) is smaller than 4, the first special figure hold in step S234. The counter value of the number counter is updated by adding “1”. In step S234, the main CPU 101a displays special symbol hold display data indicating the number of holds in the main RAM 101c in order to update the first special figure hold number (U1) displayed on the first special symbol hold display device 23. Set to a predetermined area.

  In step S235, the main CPU 101a determines the jackpot determination random number indicated by the jackpot determination random number counter, the special symbol determination random number indicated by the special symbol determination random number counter, the reach determination random number indicated by the reach determination random number counter, and the special figure variation pattern. The random number for special figure fluctuation pattern determination indicated by the random number counter for determination is stored in the first special symbol holding storage area. Hereinafter, the jackpot determination random number, the special symbol determination random number, the reach determination random number, and the special figure variation pattern determination random number are collectively referred to as “special pattern determination information”.

  The first special symbol storage area is divided into a first storage unit to a fourth storage unit (see FIG. 16A), and the special figure determination information is a number in a storage unit in which no random number is stored. Are stored in order from the smallest storage unit. Each storage unit is divided into regions for each stored random number (see FIG. 16B).

  In step S236, the main CPU 101a performs the first preliminary determination based on the game ball entering the first start port 6. In the first pre-determination, the main CPU 101a refers to the jackpot lottery pre-determination table shown in FIG. 13, and based on the special figure stop symbol data, the reach determination random number value and the special figure variation random value acquired this time, Start winning information for indicating the start opening determination information in advance is determined. In the short-time gaming state, the first pre-determination is not performed and the second pre-determination described later is performed.

  In step S237, the main CPU 101a generates a start opening winning designation command (see FIG. 13) for determining in advance the result of the jackpot lottery based on the start winning information determined in the first preliminary determination. It is set in the transmission data storage area (transmission buffer) for rendering in the RAM 101c. The effect control board 102 can execute the effect mode setting process by receiving this command. In the short-time gaming state, since the first pre-determination is not performed, a start opening prize designation command indicating that new data is stored in the storage unit of the first special symbol storage area is transmitted in the effect transmission data storage area. Set to.

  Next, the second start port detection signal input process will be described with reference to FIG. In step S241, the main CPU 101a determines whether or not there is a valid detection signal from the second start port detection sensor 7a. If the main CPU 101a determines that there is no valid detection signal, the main CPU 101a ends the process. If the main CPU 101a determines that there is a valid detection signal, the main CPU 101a moves the process to step S242.

  In step S242, the main CPU 101a adds and updates the start opening prize ball counter by adding “1”, and turns on the second start opening entry flag in the second start opening winning flag storage area of the main RAM 101c.

  In step S243, the main CPU 101a determines whether or not the counter value of the second special symbol reservation number counter for counting the second special symbol reservation number (U2) is smaller than 4 (upper limit value). If the main CPU 101a determines that the counter value (U2) is not smaller than 4, the main CPU 101a ends the process. If the main CPU 101a determines that the second special figure reservation number (U2) is smaller than 4, the process proceeds to step S244.

  In step S244, the main CPU 101a adds “1” to the counter value (U2) of the second special figure pending number counter and updates it. Further, in step S244, the main CPU 101a updates the second special symbol hold number (U2) displayed on the second special symbol hold display device 24 in step S244 to display the special symbol hold display data indicating the hold number in the main RAM 101c. Set to a predetermined area.

  In step S245, the main CPU 101a determines the jackpot determination random number indicated by the jackpot determination random number counter, the special symbol determination random number indicated by the special symbol determination random number counter, the reach determination random number indicated by the reach determination random number counter, and the special figure variation pattern. The random number for special pattern fluctuation pattern determination indicated by the random number counter for determination is stored in the second special symbol storage area.

  The second special symbol storage area is divided into a first storage section to a fourth storage section (see FIG. 16A), and the special figure determination information is a number in a storage section in which no random number is stored. Are stored in order from the smallest storage unit. Each storage unit is divided into regions for each stored random number (see FIG. 16B).

  In step S246, the main CPU 101a performs a second preliminary determination based on the game ball entering the second start port 7. In this second pre-determination, the main CPU 101a refers to the jackpot lottery pre-determination table shown in FIG. 14, and based on the special figure stop symbol data, the reach determination random number value and the special figure variation random value acquired this time, Start winning information for indicating the start opening determination information in advance is determined. In the non-time-saving gaming state, the first prior determination is performed without performing the second prior determination.

  In step S247, the main CPU 101a generates a start opening winning designation command (see FIG. 12) for determining in advance the result of the jackpot lottery based on the start winning information determined in the second pre-determination. It is set in the transmission data storage area (transmission buffer) for rendering in the RAM 101c. The effect control board 102 can execute the effect mode setting process by receiving this command. Since the second prior determination is not performed in the non-short game state, a start opening prize designation command indicating that new data has been stored in the storage unit of the second special symbol storage area is displayed in the effect transmission data storage area. set.

  Next, winning gate detection signal input processing will be described with reference to FIG. In step S251, it is determined whether there is a valid detection signal from the winning gate detection sensors 9a, 10a. If the main CPU 101a determines that there is no valid detection signal, the main CPU 101a ends the process. If the main CPU 101a determines that there is a valid detection signal, the main CPU 101a moves the process to step S252.

  In step S252, the main CPU 101a determines whether or not the counter value of the normal symbol holding number counter for counting the number of normal symbol holdings (G) is smaller than 4 (upper limit value). If the main CPU 101a determines that the counter value (G) is not smaller than 4, the main CPU 101a ends the process. If the main CPU 101a determines that the counter value (G) is smaller than 4, the main CPU 101a moves the process to step S253.

  In step S 253, the main CPU 101 a adds “1” to the counter value (G) of the usual figure holding number counter and updates it. In step S253, the main CPU 101a updates the normal symbol hold number (G) displayed on the normal symbol hold display device 25 in the predetermined area of the main RAM 101c in order to update the normal symbol hold number (G). set.

  In step S254, the main CPU 101a determines a hit determination random number indicated by the hit determination random number counter, a normal symbol determination random number indicated by the normal symbol determination random number counter, and a normal pattern variation pattern determination random number indicated by the normal symbol variation pattern determination random number counter. Is stored in the normal symbol storage area, and the winning gate detection signal input process is terminated. Hereinafter, the hit determination random number, the normal symbol determination random number, and the common pattern variation pattern determination random number are collectively referred to as “normal pattern determination information”.

  The normal symbol holding storage area is divided into a first storage unit to a fourth storage unit (see FIG. 16C), and the common symbol determination information is stored in a storage unit in which a random number is not stored. It is memorized in order from the part. Each storage unit has an area for each stored random number (see FIG. 16D).

  Next, the special figure special electric control process will be described with reference to FIG. In step S301, the value of the special figure special electricity processing data is loaded, and the branch destination address is referred to from the special figure special electric treatment data loaded in step S302. ), The process moves to the special symbol variation process (step S320) if the special symbol special electric processing data = 1, and the special symbol stop process (step S330) if the special symbol special electric treatment data = 2. If the special figure special electric processing data = 3, the process is transferred to the jackpot game processing (step S340). If the special figure special electric processing data = 5, the process is transferred to the big hit game end process (step S360). Details will be described later with reference to FIGS.

  The special symbol memory determination process will be described with reference to FIG. First, in step S310-1, the main CPU 101a determines whether or not the special symbol is being variably displayed. If the main CPU 101a determines that the special symbol variation display is in progress, the main CPU 101a ends the process.

  In step S310-2, the main CPU 101a determines whether or not the second special figure holding number (U2) is 1 or more. If it is determined that the second special figure hold number (U2) is not 1 or more, the process proceeds to step S310-4. If it is determined that the second special figure hold number (U2) is 1 or more, the process proceeds to step S310-3. Move processing.

  In step S310-3, the main CPU 101a updates the counter value of the second special symbol hold count counter by subtracting “1”, and in step S310-6, the data stored in the second special symbol hold storage area is shifted. Processing is performed to shift the special figure determination information stored in the first storage unit to the fourth storage unit to the previous storage unit.

  For example, the special symbol determination information stored in the fourth storage unit of the second special symbol reservation storage area is shifted to the third storage unit of the second special symbol reservation storage region. Also, the special symbol determination information stored in the first storage unit of the second special symbol storage area is shifted to the special symbol common storage area (the zeroth storage unit) common to the first special symbol and the second special symbol. Then, the special figure determination information stored in the 0th storage unit is deleted. Thereby, the special figure determination information used in the previous game is deleted. Further, the special figure stop symbol data and game condition data used in the previous game are also erased from the corresponding storage areas.

  On the other hand, in step S310-4, the main CPU 101a determines whether or not the first special figure hold number (U1) is 1 or more. If the main CPU 101a determines in step S310-4 that the first special figure hold number (U1) is 1 or more, the main CPU 101a moves the process to step S310-5.

  The main CPU 101a updates the counter value of the first special symbol reservation number counter by subtracting “1” in step S310-5 and updates the special symbol determination stored in the first special symbol reservation storage area in step S310-6. Information shift processing is performed.

  For example, the special symbol determination information stored in the fourth storage unit of the first special symbol reservation storage area is shifted to the third storage unit of the first special symbol reservation storage region. Also, the special symbol determination information stored in the first storage unit of the first special symbol storage area is shifted to the special symbol storage area (the zero storage unit) and stored in the zero storage unit. The figure determination information is deleted. Thereby, the special figure determination information used in the previous game is deleted. Further, the special figure stop symbol data and game condition data used in the previous game are also erased from the corresponding storage areas.

  In addition, in order to update the 1st special figure reservation number (U1) or the 2nd special figure reservation number (U2) with the shift process of the special figure determination information in step S310-6, specifically, the data In order to change the display contents of the special symbol hold display devices 23 and 24 corresponding to the type of the start port according to the above, first and second special symbol hold display data are set in a predetermined area of the main RAM 101c. The hold display data includes information on the type of the special symbol hold display device and information on the special symbol hold number (U1 or U2).

  In the present embodiment, the second special symbol reservation storage area is shifted in priority to the first special symbol reservation storage area in steps S310-2 to S310-6, but the game ball enters the start port. The first special symbol reserved storage area or the second special symbol reserved storage area may be shifted in the order of the balls, or the first special symbol reserved storage area may be shifted with priority over the second special symbol reserved storage area. May be.

  If it is determined in step S310-4 that the first special symbol hold number (U1) is not 1 or more, the process proceeds to steps S319-1 to S319-3 to set the customer waiting state. Wait state setting processing is performed. The customer waiting state refers to a state in which the special symbol variation display and the jackpot game are not executed.

  As the customer waiting state setting process, the main CPU 101a first determines whether or not the customer waiting state determination flag “01H” is set in the customer waiting state determination flag storage area in step S319-1. When the customer waiting state determination flag “01H” is set in the customer waiting state determination flag storage area, the main CPU 101a ends the special symbol storage determination process, and determines the customer waiting state determination in the customer waiting state determination flag storage area. If the flag “01H” is not set, the process proceeds to step S319-2.

  In step S319-2, the main CPU 101a sets the customer waiting state determination flag “01H” in the customer waiting state determination flag storage area because the customer waiting state is not repeatedly set.

  In step S319-3, the main CPU 101a sets a customer waiting state designation command in the effect transmission data storage area, and ends the special symbol memory determination process.

  In step S311, the main CPU 101a executes jackpot determination processing based on the data shifted in step S310-6 and newly stored in the 0th storage unit.

  Here, the jackpot determination process will be described with reference to FIG. First, in step S311-1, the main CPU 101a determines whether the jackpot determination process is performed based on a game ball entering the first start port 6.

  If the main CPU 101a determines in step S311-1 that it is the first start port 6, the first special symbol jackpot determination table is selected in step S311-2. On the other hand, if the main CPU 101a determines that it is not the first start port 6 (is the second start port 7) in step S311-1, the second special symbol jackpot determination table is selected in step S311-3.

  Next, in step S311-4, the main CPU 101a determines whether or not a flag is turned on in the high probability flag storage area. Here, the fact that the flag is turned on in the high-probability flag storage area means that the current jackpot winning probability is a high-probability gaming state.

  If the main CPU 101a determines in step S311-4 that the flag is ON in the high probability flag storage area, in step S311-5, the main CPU 101a further selects “from the table selected in step S311-2 or step S311-3”. The “first high probability jackpot determination table” or the “second high probability jackpot determination table” is selected.

  On the other hand, when the main CPU 101a determines that the flag is not turned on in the high probability flag storage area, in step S311-6, the “first low probability” is further selected from the table selected in step S311-2 or step S311-3. "Big jackpot determination table" or "Second low probability jackpot determination table" is selected.

  In step S311-7, the main CPU 101a shifts the jackpot determination random number in the 0th storage unit after being shifted in step S310-6 to the “high probability jackpot selected in step S311-5 or step S311-6”. It is compared with the “determination table” or the “low probability jackpot determination table” to determine whether it is “big jackpot” or “losing”, and the jackpot determination processing ends.

  When the big hit determination process ends, the main CPU 101a returns to the special symbol storage determination process shown in FIG. 25, and performs the special symbol determination process in step S312. In the special symbol determination process, a special symbol that is stopped and displayed in the special symbol display devices 20 and 21 is determined based on the result of the jackpot determination process. Here, the special symbol determination process will be described with reference to FIG.

  First, in step S312-1, the main CPU 101a confirms the type of the start port related to the processing based on the flag turned on in the start port winning flag storage area.

  In step S312-2, the main CPU 101a determines whether or not the result of the jackpot determination is “jackpot”. If it is determined that the game is a “hit”, the main CPU 101a selects a special symbol determination table for winning a jackpot in step S312-5. If it is not determined that it is a “hit”, step S312— The processing is moved to 3.

  In step S <b> 312-3, the main CPU 101 a performs reach determination. Specifically, the reach determination random number value shifted in step S310-6 and stored in the 0th storage unit is collated with the reach determination table (FIG. 4B).

  In step S <b> 312-4, the main CPU 101 a determines whether or not “reach” is determined as a result of the reach determination in step S <b> 312-3. If it is determined that “reach is present”, the process proceeds to step S312-6, and a special symbol determination table for reach loss is selected. On the other hand, if it is determined that it is not “with reach”, ie, “without reach”, the process proceeds to step S312-7, and a special symbol determination table for loss without reach is selected.

  In step S312-8, the main CPU 101a determines which one of the special symbol determination table for the first startup port or the special symbol determination table for the second startup port based on the type of the startup port confirmed in step S312-1. Select either one.

  In step S312-9, the main CPU 101a performs a special symbol determination in which the special symbol determination random number value shifted in step S310-6 and stored in the 0th storage unit is checked against the selected special symbol determination table.

  In step S312-10, an effect symbol designation command is determined based on the result of the special symbol determination in step S312-9 (see FIG. 5), and the determined effect symbol designation command is set in the effect transmission data storage area. To do.

  Next, the main CPU 101a determines in step S311-11 stop symbol data related to the special symbol based on the result of the special symbol determination in step S312-9 (hereinafter referred to as "special symbol stop symbol data"), that is, a special symbol. The determined special figure stop symbol data is set in a predetermined area of the main RAM 101c.

  The determined special symbol stop symbol data is determined to be “special bonus special symbol” or the like in the special symbol stop process of FIG. 30 when determining the special symbol variation pattern in the special symbol variation pattern determination process of FIG. 28 as will be described later. At this time, it is also used when determining the opening / closing mode of the big winning opening 8 in the big hit game processing of FIG.

  When the special symbol determination process is completed as described above, the main CPU 101a returns to the special symbol memory determination process shown in FIG. 25, and performs the special symbol variation pattern determination process in step S313. In the special figure fluctuation pattern determination process, a special figure fluctuation pattern including information on the special figure fluctuation time and the effect type of the fluctuating effect described later, based on the result of the jackpot determination, the result of the special symbol determination, and the result of the reach determination is generated. decide.

  The special figure variation pattern determination process will be described with reference to FIG. First, in step S313-1, the main CPU 101a refers to ON / OFF of a high-probability flag, which will be described later, and ON / OFF of a short-time flag, to determine the current gaming state (high probability gaming state / low probability gaming state, and (Time saving gaming state / non-time saving gaming state) is checked, and a special figure variation pattern determination table associated with the gaming state is selected.

  In step S313-2, the main CPU 101a checks the special figure stop symbol data stored in the main RAM 101c, and determines the special figure fluctuation pattern determination table shown in FIGS. 9 to 12 based on the special figure stop symbol data. To do.

  If the special figure fluctuation pattern determination table is determined, the main CPU 101a performs special figure fluctuation pattern determination in step S313-3. Specifically, referring to the determined special symbol variation pattern determination table (FIGS. 9 to 12), the lottery result of the big hit lottery, the special symbol to be stopped, the number of special symbol reserved balls (U1 or U2), and reach determination Based on the random number value and the special figure variation random value, the variation pattern of the special symbol is determined.

  When the main CPU 101a determines the special symbol variation pattern, the main CPU 101a returns to the special symbol memory determination process shown in FIG. 25. In step S310-7, the special CPU variation pattern designation command corresponding to the special symbol variation pattern is transmitted for production in the main RAM 101c. Set in the data storage area. The special figure variation pattern designation command is transmitted to the production control board 102. Upon receiving this command, the production control board 102 recognizes that the special symbol fluctuation display starts, and finally designates the special figure fluctuation pattern designation. Based on the command, the variation effect pattern associated with the content of the variation effect is determined. In addition, when receiving the command, the effect control board 102 recognizes that the change display of the special symbol starts and can execute the change effect described later.

  In step S310-8, the main CPU 101a confirms the state of the gaming conditions at the start of the variable symbol display of the special symbol, and sets a gaming state designation command reflecting the state in the effect transmission data storage area of the main RAM 101c. .

  In step S310-9, the main CPU 101a sets the special figure change time (see FIGS. 9 to 12) associated with the special figure change pattern in the special game timer counter. The special game timer counter is subtracted every 4 ms in step S110.

  In step S310-10, the main CPU 101a sets special symbol variation display data in order to perform variation display of the special symbol on the first special symbol display device 20 or the second special symbol display device 21. The special symbol variation display data includes information such as the type of the special symbol display device to be operated, the variation display mode, and the variation time.

  In step S310-11, the main CPU 101a sets a flag “00H” in the customer waiting state determination flag storage area, that is, clears the customer waiting state determination flag storage area. In step S310-12, the special figure special electric processing data = 1 is set, and the special symbol memory determination process is terminated.

  Next, the special symbol variation process will be described with reference to FIG. First, in step S320-1, the main CPU 101a determines whether or not the special symbol variation display is terminated in step S310-9, in other words, whether or not the set special symbol variation time has elapsed (special). Game timer counter = 0). As a result, if it is determined that the special symbol variation display does not end, the special symbol variation processing is terminated, and the next subroutine is executed.

  If the main CPU 101a determines that the variation display of the special symbol is finished, in step S320-2, the main CPU 101a uses a special diagram stop designation command for the effect control board 102 to notify the end of the variation display of the special symbol. Set in the transmission data storage area.

  In step S320-3, the main CPU 101a displays special figure stop display data based on the special figure stop symbol data set in step S312-11 in order to stop and display the special symbols on the special symbol display devices 20 and 21. Set. Thereby, the result of the special symbol lottery is notified to the player. In step S320-4, the main CPU 101a sets the time required for the special symbol stop display (hereinafter referred to as "special figure stop time", for example, 0.8 seconds) to the special game timer counter. The special game timer counter is subtracted every 4 ms in step S110.

  In step S320-5, the main CPU 101a sets 2 in the special figure special electricity processing data, and in step S320-6, turns off the first starting opening prize flag or the second starting opening prize flag, and the special symbol variation process. Exit.

  The special symbol stop process will be described with reference to FIG. First, the main CPU 101a first determines whether or not the special symbol stop display ends in step S330-1, in other words, the special figure stop time set in the special game timer counter in step S320-4 has elapsed. It is determined whether or not (special game timer counter = 0?). As a result, if it is determined that the special symbol stop display does not end, the special symbol stop processing is ended. If it is determined that the special symbol stop display ends, the process proceeds to step S330-2.

  In step S330-2, the main CPU 101a determines whether or not a flag is turned on in the time reduction flag storage area. The fact that the flag is ON in the time-short flag storage area means that the current state is the time-short game state. If the flag is turned on in the time reduction flag storage area, the process proceeds to step S330-3. If the flag is turned off in the time reduction flag storage area, the process proceeds to step S330-6.

  In step S330-3, the main CPU 101a calculates “1” from the counter value of the remaining number counter in the short time gaming state indicating the remaining number of times the special symbol change display according to the short time gaming state (J: hereinafter referred to as “the remaining number of short time gaming states”). The operation value (J-1) obtained by subtracting "is stored as the remaining time-saving gaming state count (J).

  In step S330-4, the main CPU 101a determines whether or not the remaining time-saving gaming state count (J) = 0. If the remaining time-saving gaming state (J) = 0, the process proceeds to step S330-5. If the remaining time-short gaming state remaining number (J) = 0, the process proceeds to step S330-6.

  In step S330-5, the main CPU 101a turns off the flag stored in the time reduction flag storage area. It should be noted that the fact that the short time gaming state remaining number (J) is “0” means that the special symbol is displayed in a variable number of times (Ja) in the short time gaming state. Means to end.

  In step S330-6, the main CPU 101a determines whether or not a flag is turned on in the high probability flag storage area. The fact that the flag is turned on in the high probability flag storage area means that the current state is a high probability gaming state. If the flag is ON in the high probability flag storage area, the process proceeds to step S330-7. If the flag is OFF in the high probability flag storage area, the process proceeds to step S330-10.

  In step S330-7, the main CPU 101a displays the counter value of the high-probability gaming state remaining number counter indicating the remaining number of times of display of the special symbol variation display due to the high-probability gaming state (X: hereinafter referred to as “the remaining number of high-probability gaming states”). The operation value (X−1) obtained by subtracting “1” from the value is stored as a new high probability gaming state remaining number (X).

  In step S330-8, the main CPU 101a determines whether or not the high probability gaming state remaining count (X) = 0. If the high probability gaming state remaining number (X) = 0, the process proceeds to step S330-9. If the high probability gaming state remaining number (X) = 0 is not satisfied, the process proceeds to step S330-10.

  In step S330-9, the main CPU 101a turns off the flag stored in the high probability flag storage area. Note that the high probability gaming state remaining count (X) is “0” means that the special symbol is displayed in a variable number of executable times (Xa) in the high probability gaming state, and the special symbol based on the “high probability” state. This means that the fluctuation display of is finished.

  In step S330-10, the main CPU 101a confirms the state of the current gaming condition, and sets a gaming state designation command indicating the gaming state in the effect transmission data storage area.

  In step S330-11, the main CPU 101a determines whether or not the determination result of the jackpot determination related to the special symbol stop process is “jackpot”. Specifically, it is determined whether or not the special figure stop symbol data stored in the special figure stop symbol data storage area relates to the jackpot special symbol (special symbol stop symbol data = 10 to 14, 20 to 23). To do. If it is determined that the jackpot special symbol is determined, the process proceeds to step S330-13. If the jackpot special symbol is not determined, the process proceeds to step S330-12.

  In step S330-12, the main CPU 101a sets 0 in the special symbol special electricity processing data, and shifts the processing to the special symbol memory determination processing shown in FIG.

  In step S330-13, the main CPU 101a sets 3 to the special figure special processing data, and in step S330-14, the game condition flag storage area (time-short flag storage area and high-probability flag storage area), high-probability gaming state The remaining variation counter and the remaining variation counter in the short-time gaming state are reset.

  In step S330-15, the main CPU 101a collates the special figure stop symbol data with the jackpot game control table of FIG. 6 as a special game opening process, and stores an opening designation command corresponding to the special figure stop symbol data for transmission data for production Set to area. Next, the main CPU 101a sets the opening time corresponding to the special figure stop symbol data in the special game timer counter. The special game timer counter is subtracted every 4 ms in step S110. The effect control board 102 receives the opening designation command according to the special figure stop symbol data, thereby grasping the type of the stop special symbol that has been a big hit, and can execute the jackpot game effect according to the special stop symbol It becomes possible.

  The jackpot game process will be described with reference to FIG. First, in step S340-1, the main CPU 101a determines whether or not it is currently opening. The term “opening” as used herein refers to a period from the start of the jackpot game to the start of the first round game (first opening of the big winning opening 8). If it is determined that the current opening is being performed, the process proceeds to step S340-2. If it is determined that the current opening is not currently performed, the process proceeds to step S340-6.

  In step S340-2, the main CPU 101a 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 if the special game timer counter = 0, it is determined that the opening time has elapsed. As a result, if the set opening time has not elapsed, the jackpot game process is terminated, the next subroutine is executed, and if the opening time has elapsed, the process proceeds to step S340-3. .

  In step S340-3, the main CPU 101a performs a jackpot game start process. Specifically, with reference to the jackpot game control table shown in FIG. 6, a special winning opening opening / closing control table is selected from the special winning opening opening / closing control tables 01-10 shown in FIG. Then, it is set in a predetermined area of the main RAM 101c. Next, the main CPU 101a adds “1” to the value (round number (R)) stored in the round game number storage area and stores the value. Since the round game has not been executed at the time of step S340-3, the main CPU 101a stores “1” in the round game count storage area.

  In step S340-4, the main CPU 101a performs a special prize opening process. Specifically, the main CPU 101a sets the big prize opening / closing solenoid energization start data in a predetermined area of the main RAM 101c in order to energize the big prize opening / closing solenoid 80B and open the big prize opening 8. Here, the main CPU 101a refers to the special winning opening / closing control table determined in step S340-3, and based on the round number (R) and the special operation number (K), the opening time of the special winning opening 8 ( The operating time of the big prize opening control device 80) is set in the special game timer counter. The special game timer counter is subtracted every 4 ms in step S110. Further, the main CPU 101a performs a process of resetting (“0”) the counter value (D) of the special winning opening detection counter. Therefore, the counter value (D) of the big prize opening detection counter is added every time the big prize opening 8 is won from when the big prize opening 8 is opened until just before the next big prize opening 8 is opened. It is supposed to be.

  In step S340-5, the main CPU 101a performs a round designation command transmission determination process. Specifically, it is determined whether or not K = 1. If K = 1, a round designation command is set in the effect transmission data storage area. This is because information indicating that the round game starts is transmitted to the effect control board 102. Specifically, according to the special figure stop symbol data, the type of jackpot is confirmed, the special symbol stop symbol data is collated with the jackpot game control table of FIG. 6, and the jackpot type transmitted to the effect control board 102 is supported. The attached round designation command is set in the effect transmission data storage area. For example, when the first round game of the jackpot game is released for the first time, “1” is set in the round game number storage area and “1” is set in the special operation number storage area. A round designation command indicating a round game is set in the effect transmission data storage area. On the other hand, if “1” is not set in the special operation number storage area, the big hit game process is terminated without setting the round designation command in the effect transmission data storage area. That is, since the case where K = 1 means the start of a round game, the main CPU 101a transmits a round designation command only at the start of the round. When the effect control board 102 receives the round designation command, an effect display is performed on the image display device 14 such as “ROUND1”, and various round games to be described later are executed according to the number of round games. The

  In step S340-6, the main CPU 101a determines whether or not it is currently ending. Ending here refers to the period from the end of all preset round games (after the final opening of the big winning opening 8 is completed) to the end of the jackpot game. Therefore, if it is determined that the current ending is in progress, the process proceeds to step S340-17, where it is determined whether or not the ending time has elapsed, and if it is determined that the current ending is not currently in progress, step S340-7 is performed. Move processing to.

  In step S340-7, the main CPU 101a determines whether or not the big prize opening 8 is open, that is, whether or not the big prize opening control device 80 is in operation. If the main CPU 101a determines that the big prize opening 8 is being opened, it determines in step S340-8 whether or not an “opening end condition” for ending the opening of the big prize opening 8 is satisfied. To do. As the “opening end condition”, the counter value of the round winning counter has reached a specified number (for example, 9) in the round game, or the maximum open time has elapsed (special game timer counter = 0) ) Is adopted. If it is determined that the “opening end condition” is satisfied, the process proceeds to step S340-9. If it is determined that the “opening end condition” is not satisfied, the jackpot game process is ended.

  In step S340-9, the main CPU 101a performs a special winning opening closing process. In the special winning opening closing process, the energization stop data of the special winning opening / closing solenoid 80B is set in a predetermined area of the sub RAM 102c in order to close the special winning opening 8, and the opening / closing of the special winning opening determined in step S340-3 is performed. Referring to the control table, based on the current round number (R) and special operation number (K), the closing time of the special winning opening 8 is set in the special game timer counter. As a result, the special winning opening 8 is closed.

  In step S340-10, the main CPU 101a determines whether or not one round game has ended. Specifically, in one round game, the special electric operation number (K) is the number of times of opening set in the round game, or the counter value (C) of the round winning counter is a specified number (for example, 9) ) Is reached on condition that it has been reached, it is determined whether or not such an end condition is satisfied. If it is determined that one round game has been completed, the process proceeds to step S340-12. If it is determined that one round has not been completed, the jackpot game process is ended.

  If the main CPU 101a determines in step S340-7 that the special winning opening 8 is not open, the main CPU 101a determines in step S340-11 whether a preset closing time has elapsed. As a result, if the closing time has not elapsed, the jackpot game process is terminated, and if the closing time has elapsed, the process proceeds to step S340-4.

  In step S340-12, the main CPU 101a performs a reset process. Specifically, the special electric operation number storage area is cleared and the counter value (C) of the round winning counter is cleared.

  In step S340-13, the main CPU 101a determines whether or not the jackpot game ends, that is, whether the value (round number (R)) stored in the round game number storage area is the number of round games executed in the jackpot game. Determine whether or not. When determining “Yes”, the main CPU 101a moves the process to step S340-15, and when determining “No”, the main CPU 101a moves the process to step S340-14.

  In step S340-14, the main CPU 101a updates and stores the current round number (R) stored in the round game count storage area by adding “1”.

  In step S340-15, the main CPU 101a performs jackpot game end processing. Specifically, the round number (R) stored in the round game number storage area is reset.

  In step S340-16, the main CPU 101a performs an ending process. Specifically, according to the special figure stop symbol data, the type of jackpot is confirmed, the special symbol stop symbol data is collated with the jackpot game control table of FIG. 6, and the jackpot type transmitted to the effect control board 102 is supported. The attached ending designation command is set in the transmission data storage area for presentation. Next, the main CPU 101a sets the ending time corresponding to the special figure stop symbol data in the special game timer counter.

  In step S340-17, the main CPU 101a determines whether or not the set ending time has elapsed. If it is determined that the ending time has elapsed, the main CPU 101a proceeds to step S340-18 and passes the ending time. If it is determined that it is not, the jackpot game process is terminated as it is.

  In step S340-18, the main CPU 101a sets 5 in the special figure special electric processing data, and shifts the processing to the jackpot game end processing shown in FIG.

  The jackpot game end process will be described with reference to FIG. First, in step S360-1, the main CPU 101a checks the special figure stop symbol data set in the main RAM 101c against the gaming state setting table shown in FIG. 8, and turns on the high probability flag in the high probability flag storage area. Determine whether or not. If the main CPU 101a determines that the high probability flag is not turned ON, the process proceeds to step S360-3. If the main CPU 101a determines that the high probability flag is ON, in step S360-2, the high probability flag is stored in the high probability flag storage area of the main RAM 101c. (01H) is turned ON, and the executable number (X) (10000 times in this embodiment) is set in the high probability gaming state remaining number counter.

  In step S360-3, the main CPU 101a collates the special figure stop symbol data set in the main RAM 101c with the gaming state setting table shown in FIG. 8, and determines whether or not the hourly flag is turned on in the hourly flag storage area. I do. If the main CPU 101a determines that the time reduction flag is not turned on, the process proceeds to step S360-5. If the main CPU 101a determines that the time reduction flag is turned on, in step S360-4, the time reduction flag (01H) is set in the time reduction flag storage area of the main RAM 101c. At the same time, the number of executable times (J) (in this embodiment, 100 times or 10,000 times) is set in the time-saving gaming state remaining number counter.

  In step S360-5, the main CPU 101a confirms the current gaming condition status, sets a gaming status designation command indicating the current gaming condition status in the effect transmission data storage area, and in step S360-6 The special electric processing data is set to 0, and the processing moves to the special symbol memory determination processing shown in FIG.

  The ordinary power control process will be described with reference to FIG. First, the main CPU 101a loads the value of the ordinary power transmission processing data in step S401, refers to the branch address from the loaded ordinary power transmission processing data loaded in step S402, and if the ordinary power transmission processing data = 0. For example, a normal symbol memory including a normal symbol determination as to whether or not to execute an auxiliary game (the second start port 7 is opened) based on the general symbol determination information acquired based on winning at the winning gates 9 and 10. If the normal symbol display device 22 is fluctuating based on the normal symbol determination, the normal symbol variation process (step S420) is performed. If the normal symbol display data = 2, the normal symbol display device 22 is stopped and the normal symbol stop process (step S430) is executed. Data = if 3 controls the opening and closing of the second start hole 7 (actuating the second start hole control device 70) and moves the process to the auxiliary game process (step S440).

  The normal symbol memory determination process will be described with reference to FIG. First, in step S410-1, the main CPU 101a determines whether or not the normal symbol is being displayed in a variable manner. If it is determined that the normal symbol is being displayed, the main CPU 101a ends the normal symbol storage determination process. If it is determined that there is not, the process proceeds to step S410-2.

  In step S410-2, the main CPU 101a determines whether or not the counter value of the universal figure holding number counter for counting the normal figure holding number is 1 or more. When the number of held general symbols (G) is “0”, the normal symbol variation display is not performed, so the normal symbol variation process is terminated.

  When the main CPU 101a determines in step S410-2 that the number of reserved symbols (G) is “1” or more, in step S410-3, the main CPU 101a determines from the counter value (G) of the normal symbol reservation number counter “G”. 1 "is subtracted and updated, and a new number of reserved general drawings (G) is set.

  In step S410-4, the main CPU 101a performs a shift process of the normal symbol determination information stored in the normal symbol reservation storage area. Specifically, the common figure determination information stored in the first storage unit to the fourth storage unit is shifted to the storage unit with the previous number. At this time, the common symbol determination information stored in the previous storage unit is written in a predetermined processing area and is erased from the normal symbol holding storage area. Here, in order to change the display content of the normal symbol hold display device 25 in accordance with the shift of the general symbol determination information, specifically, the normal symbol hold display data for displaying the current general symbol hold number (G). Is set in a predetermined area of the main RAM 101c.

  In step S410-5, the main CPU 101a performs a hit determination, that is, a determination of a hit determination random number stored in the normal symbol holding storage area. Specifically, the main CPU 101a checks whether or not the hit determination random number for the normal symbol stored in the main ROM 101b is compared with the hit determination random number stored in the main ROM 101b after being shifted in step S410-4. Judgment is made. In the present embodiment, the winning determination table is associated with the start opening winning ease state (non-short-time gaming state / short-time gaming state) (see FIG. 15A), so the short-time flag storage area And a hit determination table for a normal symbol related to the current start port winning easiness state is selected.

  In step S410-6, the main CPU 101a performs normal symbol determination. Specifically, the main CPU 101a performs normal symbol determination by comparing the normal symbol determination random number stored in the 0th storage unit with the normal symbol determination random number stored in the main ROM 101b after being shifted in step S410-4. As described above, since this normal symbol determination table is associated with the result of the hit determination (win / loss), the result of the hit determination is confirmed, and the normal symbol determination table related to the result of the hit determination is determined. select.

  In step S410-7, the main CPU 101a determines the stop symbol data related to the normal symbol (hereinafter referred to as “general symbol stop symbol data”), that is, the type of the normal symbol, based on the result of the normal symbol determination. The determined general map stop symbol data is set in a predetermined area of the main RAM 101c.

  When the determined general symbol stop symbol data is determined as a general symbol variation pattern in the general symbol variation pattern determination, it is determined in the normal symbol stop processing in FIG. Is also used when determining the opening / closing mode of the second starting port 7.

  In step S410-8, the main CPU 101a performs general-purpose variation pattern determination. Specifically, since the normal pattern variation pattern determination table for performing the universal map variation pattern determination is classified according to the start opening winning easiness state, the main CPU 101a first confirms the time-short flag storage area, A general-purpose variation pattern determination table according to the current start opening winning easiness state is selected. Then, the main CPU 101a compares the random number for determining the customary pattern fluctuation pattern in the 0th storage unit, which is shifted in the above step S410-4, with the selected customary pattern fluctuation pattern determination table, and determines the normal pattern fluctuation pattern (normal map). (Variation time).

  In step S410-9, the main CPU 101a sets a universal pattern change pattern designation command corresponding to the determined normal pattern change pattern in the effect transmission data storage area of the main RAM 101c. The normal pattern change pattern designation command is transmitted to the effect control board 102, and the effect control board 102 recognizes that the change display of the normal symbol starts by receiving this command, and can execute the roulette effect described later.

  In step S410-10, the main CPU 101a sets the base map change time corresponding to the determined base map change pattern in the auxiliary game timer counter. The auxiliary game timer counter is subtracted every 4 ms in step S110.

  In step S410-11, the main CPU 101a sets the normal symbol variation display data to perform the normal symbol variation display on the ordinary symbol display device 22, and if the hit determination result is a hit, the main CPU 101a determines in step S410-12. The normal game stop symbol data is collated with the auxiliary game reference data determination table to determine auxiliary game reference data and set in the auxiliary game reference data storage area of the main RAM 101c.

  In step S410-13, the main CPU 101a sets “1” in the normal-plot normal power processing data, and ends the normal symbol variation process. The normal symbol variation display data includes information such as the type of the normal symbol display device 22 to be operated, the variation display mode, and the variation time.

  Next, the normal symbol variation process will be described with reference to FIG. First, in step S420-1, the main CPU 101a terminates the normal symbol variation display, in other words, whether or not the normal diagram variation time set in step S410-10 has elapsed (auxiliary game timer counter). = 0). As a result, when it is determined that the normal symbol variation display does not end, the normal symbol variation processing is terminated and the next subroutine is executed.

  In step S420-2, the main CPU 101a sets a normal effect symbol stop designation command in the effect transmission data storage area. In step S420-3, the main CPU 101a performs normal processing based on the normal symbol stop symbol data set in step S410-8. Data for stop display of general symbols for stopping display on the symbol display device 22 is set. As a result, the player is notified of the result of the normal symbol lottery. In step S420-4, the main CPU 101a sets a normal symbol stop time (for example, 0.8 seconds) in the auxiliary game counter. The auxiliary game timer counter is subtracted every 4 ms in step S110.

  Then, in step S420-5, the main CPU 101a sets 2 to the ordinary figure / electric power process data, and ends the normal symbol variation process.

  Next, the normal symbol stop process will be described with reference to FIG. First, in step S430-1, the main CPU 101a determines whether or not the normal symbol stop display ends, in other words, whether or not the normal symbol stop time set in the auxiliary game timer counter in step S420-4 has elapsed. Whether or not (auxiliary game timer counter = 0?) Is determined. As a result, when it is determined that the normal symbol stop display does not end, the normal symbol stop processing ends, and the next subroutine is executed.

  If the main CPU 101a determines that the stop display of the normal symbol is finished, the main CPU 101a determines in step S430-2 whether the result of the hit determination related to the normal symbol stop process is “win”. More specifically, it is determined whether or not the general symbol stop symbol data stored in the normal symbol stop symbol data storage area is related to a normal symbol. Here, if it is determined that the symbol is a normal symbol, the process proceeds to step S430-4. If it is not determined that the symbol is a normal symbol, the process proceeds to step S430-3.

  In step S430-4, the main CPU 101a sets 3 to the ordinary power transmission processing data. Then, in step S430-5, the main CPU 101a sets an opening designation command corresponding to the usual figure stop symbol data in the effect transmission data storage area of the main RAM 101c, and responds to the usual figure stop symbol based on the auxiliary game control table. Set the opening time in the auxiliary game timer counter. The auxiliary game timer counter is subtracted every 4 ms in step S110. When this process is finished, the normal symbol stop process is finished.

  In step S430-3, the main CPU 101a sets 0 to the ordinary figure ordinary electricity processing data, and ends the normal symbol suspension process.

  The auxiliary game process will be described with reference to FIG. The main CPU 101a first determines in step S440-1 whether or not it is currently opening. If it is determined that it is currently opening, the process proceeds to step S440-2. If it is determined that it is not currently opening, the process proceeds to step S440-5.

  In step S440-2, the main CPU 101a determines whether or not a preset opening time has elapsed. That is, it is determined whether or not the auxiliary game timer counter = 0, and when the auxiliary game timer counter = 0, it is determined that the opening time has elapsed. As a result, when the opening time has not elapsed, the auxiliary game process is terminated, and when the opening time has elapsed, the process proceeds to step S440-3.

  In step S440-3, the main CPU 101a performs auxiliary game start processing. In the auxiliary game start process, the main CPU 101a first selects the second start port opening / closing control table based on the auxiliary game reference data stored in the auxiliary game reference data storage area of the main RAM 101c, and enters the predetermined area of the main RAM 101c. set.

  In step S440-4, the main CPU 101a performs a second start port opening process. In the second opening opening process, first, “1” is added to the value stored in the ordinary power operation number storage area (the ordinary power operation number (D)) and stored. And in order to operate 70 A of normal movable pieces, while setting the energization start data of the 2nd starting port opening / closing solenoid 70B, with reference to the 2nd starting port opening / closing control table set by said step S440-3, The opening time of the second start port 7 based on the general electric operation number (D) is set in the auxiliary game timer counter.

  In step S440-5, the main CPU 101a determines whether or not it is currently ending. Ending here refers to the period from the end of the last opening of the second start port 7 to the end of the auxiliary game. Therefore, the main CPU 101a moves the process to step S440-12 when determining that it is currently ending, and shifts the process to step S440-6 when determining that it is not currently ending.

  In step S440-6, the main CPU 101a determines whether or not the second start port 7 is being opened. If the main CPU 101a determines that the second start port 7 is open, whether or not the “open end condition” for ending the opening of the second start port 7 is satisfied in step S440-7. Determine. As the “opening end condition”, the counter value of the starting opening prescribed winning counter has reached a prescribed (maximum) number (for example, 10), or that the opening time of one opening of the second starting opening 7 has elapsed ( Auxiliary game timer counter = 0) is adopted. Then, the main CPU 101a moves the process to step S440-8 when it is determined that the “opening end condition” is satisfied, and ends the auxiliary game process when it is determined that the “opening end condition” is not satisfied. .

  In step S440-8, the main CPU 101a performs a second start port closing process. In the second start port closing process, energization stop data of the second start port opening / closing solenoid 70B is set to close the second start port 7, and the second start port opening / closing control table set in step S440-3 is set. The closing time of the second start port 7 is set in the auxiliary game timer counter on the basis of the current general electric operation number (D). As a result, the second start port 7 is closed.

  In step S440-9, the main CPU 101a determines whether or not the auxiliary game end condition is satisfied and the auxiliary game is ended. The auxiliary game end condition is that the number of times the second start opening 7 is opened with a preset number of power transmission operation (D), or the counter value of the start opening prescribed winning counter is the maximum number (for example, 10). It has been reached. The main CPU 101a moves the process to step S440-10 when it is determined that the auxiliary game end condition is satisfied, and ends the auxiliary game process when it is determined that the auxiliary game end condition is not satisfied. .

  In step S440-10, the main CPU 101a sets “0” in the general electric operation number storage area and sets “0” in the second start opening prize prescribed counter. That is, the general electric operation number storage area and the second start opening prescribed winning counter are cleared.

  In step S440-11, the main CPU 101a sets an ending designation command corresponding to the normal-design stop symbol data in the effect transmission data storage area, and at the same time, the ending time according to the standard-design stop symbol data based on the auxiliary game control table. Is set in the auxiliary game timer counter.

  When determining that the second start port 7 is not open in step S440-6, the main CPU 101a determines in step S440-13 whether or not the closing time set in step S440-8 has elapsed. To do. Note that the closing time is also determined by whether or not the auxiliary game timer counter = 0 as in the opening time. As a result, when determining that the closing time has not elapsed, the main CPU 101a ends the auxiliary game process, and when determining that the closing time has elapsed, the main CPU 101a moves the process to step S440-4.

  In step S440-12, the main CPU 101a determines whether or not the set ending time has elapsed. If the main CPU 101a determines that the ending time has elapsed, the main CPU 101a proceeds to step S440-14 and passes the ending time. If it is determined that it is not, the auxiliary game process is terminated.

  In step S440-14, the main CPU 101a sets the ordinary power transmission process data = 0, and ends the auxiliary game process.

(Main processing by production control board)
Next, processing executed by the sub CPU 102a in the effect control board 102 will be described.

  First, the main process of the effect control board 102 will be described with reference to FIG. When power is supplied from the power supply board 107 to the sub CPU 102a, a system reset occurs in the sub CPU 102a, and the sub CPU 102a performs the following main processing.

  First, in step S1001, the sub CPU 102a performs an initialization process. In this processing, the main processing program is read from the sub ROM 102b, and the sub RAM 102c in which flags and commands are stored is initialized.

  In step S1002, the sub CPU 102a controls an effect made up of a special figure hold icon mode determination random number, a variation effect pattern determination random number, an effect mode determination random number, a reach effect pattern determination random number, a jackpot effect determination random number, and the like. A process for updating the random number for presentation used in the process is performed.

  Note that a random number counter is provided in the sub-RAM 102c for each of various random numbers constituting the production random number. In the effect random number update process, “1” is added to the random number counter provided for each type of random number. A random number range is provided for various random numbers constituting the production random number. The random number range is from “0” to the maximum value determined for the random number. Then, in the update of the random number, when the random value indicated by the random number counter is the maximum value in the random number range, the random number counter is returned to “0” without adding “1”.

  Further, the maximum value of the random number range is set to be different depending on the type of random number. This is to prevent the random number counter related to the production random number from being completely synchronized and always having the same random number value. Since it is only necessary to prevent the random number counter related to the production random number from being completely synchronized, different initial value random numbers are provided to the various production random numbers instead of making the maximum values of the various random number ranges different, When updating the random number, if the random value indicated by the random number counter is the maximum value in the random number range, each random value may be newly updated from the initial random number at that time.

(Timer interrupt processing by production control board)
The timer interrupt process shown in FIG. 39 is executed by generating a clock pulse every predetermined period (for example, 4 milliseconds) by the reset clock pulse generation circuit provided on the effect control board 102.

  First, in step S1100, the sub CPU 102a saves information stored in the register of the sub CPU 102a to the stack area.

  In step S1200, the sub CPU 102a performs time control processing for updating each timer counter for performing time management related to various effects.

  In step S1300, the sub CPU 102a performs command analysis processing. In this processing, the sub CPU 102a performs processing for analyzing a command stored in the reception buffer of the sub RAM 102c. Details will be described later with reference to FIGS. 40 to 46.

  When the effect control board 102 receives the command transmitted from the main control board 101, the effect control board 102 performs a reception interrupt process of the effect control board 102 (not shown) and stores the received command in the reception buffer. Thereafter, processing for analyzing the received command is performed in step S1300.

  In step S1400, the sub CPU 102a performs a customer waiting effect control process for controlling the customer waiting effect performed in the customer waiting state.

  In step S1500, the sub CPU 102a checks an input signal from the effect button detection switch 18a or the selection button detection switch 19a, and performs an effect input control process based on an operation on the effect button 18A or the selection button 19A.

  In step S1600, the sub CPU 102a performs data output processing for transmitting various effect control commands set in the transmission buffer of the sub RAM 102c to the lamp control board 104 and the image control board 105.

  In step S1700, the sub CPU 102a restores the information saved in step S1100 to the register of the sub CPU 102a.

(Command analysis processing by production control board)
A command analysis process performed by the effect control board 102 will be described with reference to FIGS. 40 and 41.

  In step S1310, the sub CPU 102a newly receives a command and determines whether the command is stored in the reception buffer. If the sub CPU 102a determines that the command has not been received, the sub CPU 102a ends the command analysis process. If the sub CPU 102a determines that the command has been received, the process moves to step S1311.

  In step S1311, the sub CPU 102a determines whether or not the command stored in the reception buffer is a customer waiting state designation command. If the sub CPU 102a determines that the command stored in the reception buffer is a customer waiting state designation command, it moves the process to step S1312, and if it determines that the command is not a customer waiting state designation command, it moves the process to step S1320.

  In step S1312, the sub CPU 102a performs customer waiting effect preparation processing, and moves the processing to step S1392. In the customer waiting effect preparation process, the sub CPU 102a turns on the customer waiting effect waiting flag in the customer waiting effect flag storage area of the sub RAM 102c and waits until the customer waiting effect starts (customer waiting effect waiting time: for example, 30 seconds) is set in the customer waiting effect timer counter.

  The sub CPU 102a determines in the customer waiting effect control process in step S1400 whether or not the customer waiting effect waiting time set in the customer waiting effect timer counter has elapsed, and determines that the customer waiting effect waiting time has elapsed. Then, the customer waiting effect standby flag is turned OFF and the customer waiting effect execution flag is turned ON, and a customer waiting effect control command indicating the effect information of the customer waiting effect is set in the transmission buffer of the sub RAM 102c. The set customer waiting effect control command is transmitted to the lamp control board 104 and the image control board 105 by the data output process of step S1600. When the lamp control board 104 and the image control board 105 receive the customer waiting effect control command, the lamp control board 104 and the image control board 105 repeatedly execute the customer waiting effect for a predetermined time (for example, 20 seconds) based on the command.

  In step S1320, the sub CPU 102a determines whether or not the command stored in the reception buffer is a start slot winning designation command. If the sub CPU 102a determines that the command stored in the reception buffer is a start opening winning designation command, it moves the process to step S1321, and if it determines that the command is not a starting opening winning designation command, it moves the process to step S1330.

  In step S1321, the sub CPU 102a executes special figure hold icon display processing. Here, the special figure hold icon display process will be described with reference to FIG. The special figure hold icon display process is a process for displaying the special figure hold icon on the display unit 140 of the image display device 14.

  The special figure hold icon means that special figure determination information is stored in the main RAM 101c in the first start opening detection signal input process in step S230 or the second start opening detection signal input process in step S240, and the special symbol variation display (or An icon (image) indicating the right to execute the variable display of the special symbol in the hold state because the right to execute the special symbol lottery) has been obtained, but the change display of the special symbol cannot be started immediately. It is. The special figure hold icon includes a first special figure hold icon for the right to execute the variable display of the first special symbol based on the winning at the first starting port 6 and the second special based on the winning at the second starting port 7. And a second special figure hold icon for the right to execute symbol display (hereinafter, when referring to both the first special figure hold icon and the second special figure hold icon, simply “hold special figure” Icon ”).

  In step S1321-1, the sub CPU 102a stores the start opening winning designation command determined to have been received in step S1320 in the effect information hold storage area of the sub RAM 102c.

  As shown in FIG. 47 (a), the effect information hold storage area includes a first effect information hold storage area in which the first start opening prize designation command is stored and a second start information winning designation command in the second entry. The production information hold storage area and the production information related storage area for storing the first start opening prize designation command or the second start opening prize designation command corresponding to the special figure fluctuation display (fluctuation production) currently being performed. Has been.

  The first effect information hold storage area and the second effect information hold storage area are the first storage unit to the fourth storage unit, like the first special figure hold storage area and the second special figure hold storage area of the main RAM 101c. It is divided into. The first start opening prize designation command and the second start opening prize designation command are stored in order from the storage unit with the smallest number in the storage unit in which the start opening prize designation command is not stored in the corresponding production information hold storage area. It will be done. It should be noted that the production information in which the first start opening prize designation command and the second start opening prize designation command are stored is handled as the 0th storage section for convenience.

  Each storage unit stores a start opening prize designation command area in which a start opening prize designation command is stored, and special figure hold icon effect pattern data representing a special figure hold icon effect pattern which is an effect pattern for the special figure hold icon display. And a special figure hold icon effect pattern data area.

  In step S1321-2, the sub CPU 102a acquires a special figure hold icon effect pattern determination random number indicated by the special figure hold icon effect pattern determination random number counter. In step S1321-3, the special figure hold icon effect pattern determination (not shown) is determined. Select a table. The special figure hold icon production pattern determination table is a table for determining a special figure hold icon mode to be subjected to the special figure hold icon display process, and is associated with the start opening prize designation command. The special figure hold icon mode includes a hold change notice. The hold change notice is a notice of a change in the shape or color of the special figure hold icon that is different from the usual one, and a change in reach or a high expectation of the reach is announced in advance. It is a kind of pre-reading notice effect. A notice that the display mode of the special figure hold icon gradually changes over one or more times from the time when the winning prize is held and displayed until the start of the variation effect by the hold display. is there. With regard to the lottery of the pending change notice, for example, when the lottery result is “losing” and the variation pattern is “variation pattern 1”, “no execution” is selected with a probability of 80%, but the remaining 20% is “ “Blue” is selected. “Blue” is an effect in which the hold display, which is normally “white”, is displayed in blue. The degree of expectation varies depending on the display color of the special figure hold icon, and the degree of expectation increases in the order of “white”, “blue”, “green”, “red”, and “zebra”.

  In step S1321-4, the sub CPU 102a compares the acquired special figure hold icon effect pattern determination random number with the selected special figure hold icon effect pattern determination table to determine the special figure hold icon effect pattern determination pattern. Thereby, the display of the special figure hold | maintenance icon according to the lottery result determined beforehand or the content of production, the mode change of the displayed special figure hold | maintenance icon, etc. can be set. In step S1321-5, the special figure hold icon effect pattern data representing the determination result is stored in the effect information hold storage area of the sub RAM 102c, and the special figure hold icon display process ends.

In step S1330, the sub CPU 120a checks whether or not the command stored in the reception buffer is an effect designating command.
If the command stored in the reception buffer is an effect designating command, the sub CPU 120a moves the process to step S1331. On the other hand, if the command stored in the reception buffer is not an effect designating command, the sub CPU 120a moves the process to step S1340.

  In step S1331, the sub CPU 120a performs an effect symbol stop display pattern determination process for determining the type of effect symbol to be stopped and displayed on the image display device 31, based on the content of the received effect symbol designation command.

  In this effect symbol determination process, the effect symbol designation command is analyzed, the presence / absence of jackpot and the type of jackpot are identified, the stop symbol data of the effect symbol to be stopped and displayed is determined, and the stop symbol data of the determined effect symbol is sub- Set to the stop symbol storage area of the RAM 120c. Then, the stop symbol data stored in the stop symbol storage area is set in the transmission buffer of the sub RAM 120c in order to transmit the stop symbol data of the determined effect symbol to the image control unit 150, the lamp control unit 170, and the frame control board 180. To do.

  In step S1340, the sub CPU 102a determines whether or not the command stored in the reception buffer is a special figure variation pattern designation command. If the sub CPU 102a determines that the command stored in the reception buffer is a special figure variation pattern designation command, it moves the process to step S1341, and if it determines that there is no special figure fluctuation pattern designation command, it moves the process to step S1350. .

  In step S1341, the sub CPU 102a configures a special drawing lottery effect, and displays a variation effect pattern that is the effect content of the variation effect (including the variation display of the effect symbol) performed when the special symbol variation display is performed. The variable effect pattern determination process to determine is performed.

  Here, the variation effect pattern determination process by the effect control board 102 will be described with reference to FIG. First, in step S1341-1, the special figure variation pattern designation command determined to have been received in step S1340 is stored in the start opening prize designation command area of the effect information storage area of the sub RAM 102c. In other words, the start opening prize designation command that has been stored in the storage area for the production information is overwritten by the special figure variation pattern designation command.

  In step S1341-2, the sub CPU 102a determines the random number value indicated by the random number counter related to the effect type determination random number, the random number value indicated by the random number counter related to the random effect determination random number, and the random number value indicated by the random number counter related to the title determination random number. Etc.

  In step S1341-3, the sub CPU 102a performs a variation effect determination process for determining a variation effect based on a special figure variation pattern designation command.

  Here, the variation effect pattern determination process by the effect control board 102 will be described with reference to FIG. First, in step S1341-3-1, the sub CPU 102a analyzes the special figure variation pattern designation command, the variation pattern of the special symbol is any one of “variation patterns 3 to 30”, and the production contents are “normal reach”, “ It is determined whether or not any of “Long Reach”, “SP Reach 1”, “SP Reach 2”, “SPSP Reach 1”, “SPSP Reach 2”, and “Full Rotation Reach” (see FIGS. 9 to 12). And when it is any reach production, a process is moved to step S1341-3-2. If none of the reach effects, that is, if the lower byte of the special figure variation pattern designation command is “00H” (if it is “fluctuation pattern 1”), the lower byte of the special figure fluctuation pattern designation command is “01H”. In the case of (in the case of “variation pattern 2”), the process proceeds to step S1341-3-3.

  In step S1341-3-2, the sub CPU 102a executes reach effect type determination processing for determining the type of reach effect. In the present embodiment, the reach effect includes “normal reach effect”, “long reach effect”, “SP reach 1 effect”, “SP reach 2 effect”, “SPSP reach 1 effect”, “SPSP reach 2 effect”, and “full rotation reach effect”. In addition, “pseudo-continuous production” and “story production” ranging from 1 to 3 stages are included.

  The “pseudo-continuous effect” is an effect of performing pseudo-variable display once or a plurality of times together with a “swing effect” described later. By performing the “pseudo variation effect”, it is possible to make it appear as if a plurality of variation effects have been performed during one variation effect. "Story production" is a production with a story from 1 to 3 stages. For example, in the case of a story production based on the fairy tale Momotaro, Momotaro was born from Momo in the first stage and Momotaro in the second stage. It is a continuous story like making three ancestors and getting rid of demons in three stages.

  Specifically, the sub CPU 102a refers to the reach effect type determination table shown in FIG. 48, and determines the reach effect based on the variation pattern designation command and the effect type determination random value acquired in step S1341-2. Determine the type of. In the present embodiment, the random number value for determining the effect type is used only when the pseudo-continuous number indicated by the variation pattern designation command is 1 or more, that is, when the variation pattern designation command is for performing the pseudo-continuous presentation. is there. Of course, in the reach effect type determination table shown in FIG. 48, there are few effect types for convenience of explanation, and “normal reach effect”, “long reach effect”, “SP reach 1 effect”, “SP reach 2 effect”, and “SPSP reach”. There are multiple types of “1 effect”, “SPSP reach 2 effect”, and “full rotation reach effect”, and either type of reach effect may be determined using a random value for determining the effect type.

  When the lower byte of the variation pattern designation command is “04H”, the number of pseudo-continuous times is “SP reach 1”, and “SP reach 1 effect” is determined. In addition, when the lower byte of the variation pattern designation command is “05H”, the lottery result is “SP reach 1” with a losing result and the number of pseudo-reams being one, and “pseudo-ream effect + SP reach 1 effect” at a rate of 98%. ”And“ 2 stories + 1 stage + SP reach 1 production ”. In the “pseudo-continuous effect + SP reach 1 effect”, the SP reach 1 effect is executed after the pseudo-ream effect is executed, and in the “story 1 stage + SP reach 1 effect”, the SP reach 1 is executed after executing the story effect up to one stage. Perform the production. In addition, when the lower byte of the variation pattern designation command is “17H”, the lottery result is “SP reach 1” with a big hit and the number of pseudo-continuous runs twice, and the ratio of “pseudo-continuous effect + SP reach 1 effect” is 85%. ”And“ Story 2 stages + SP reach 1 production ”at a rate of 15%. In “story 2 stage + SP reach 1 effect”, the SP reach 1 effect is executed after executing the story effect up to 2 stages. Also, when the lower byte of the variation pattern designation command is “E4H”, it is determined to be “pseudo-continuous effect + SPSP reach 1 effect” at a rate of 80%, and “story 2 stages + SPSP reach 1 effect” at a rate of 15%. Decided to determine “pseudo-continuous production + story 3 stages + SPSP reach 1” at a rate of 5%. In “pseudo-continuous effect + story 1 stage + SPSP reach 1”, after executing the pseudo-continuous effect, the third-stage story effect is executed, and then the SPSP reach 1 effect is executed. Further, when the variation pattern designation command is “F7H”, the number of pseudo-continuous times is “full rotation reach”, and “pseudo continuous effect + full rotation reach effect” is determined at a rate of 60%, and 40% Will be determined as “3 stories + full-reach reach”. In “Story 3 stages + full rotation reach production”, the full rotation reach production is executed after executing the story production up to 3 stages. Therefore, if the story production is executed when the number of pseudo-continuations is 3, the story up to 3 stages is completed.

  As described above, the “story effect” is a reach effect that can be determined only when the number of pseudo-continuous times indicated by the change pattern designation command is 1 or more, and the variation time for performing the pseudo-continuous effect (execution period of the pseudo-continuous effect) It is an effect performed using. In addition, during the execution period of the pseudo-continuous production, in addition to the “story production”, “pseudo-continuous production + story production” can be executed. In other words, “story production” and “pseudo sequence production + story production” are productions that can be executed in place of “pseudo series production”. In the present embodiment, the ratio of determining the “story effect” is higher when the lottery result is a big hit than when the lottery is lost. That is, the “story production” is a production with a higher degree of expectation of jackpot than the “pseudo-continuous production”. In this embodiment, as shown in FIG. 48, the “pseudo-continuous effect + story effect” is a reach effect that can be determined only in the case of a jackpot, so it is a so-called jackpot confirmed reach effect. Not only, but also in the case of losing, “pseudo-continuous effect + story effect” may be determined.

  In step S1341-3-3, the sub CPU 102a analyzes the special figure variation pattern designation command, the variation pattern of the special symbol is “variation pattern 1” or “variation pattern 3”, and the effect content is “normal variation”. It is determined whether it is one of “normal reach” (see FIGS. 9 to 12). If it is “normal fluctuation” or “normal reach”, the process proceeds to step S1341-3-4. If it is neither “normal fluctuation” nor “normal reach”, the process proceeds to step S1341-3-5. .

  In step S <b> 1341-3-4, the sub CPU 102 a executes a turning effect execution determination process for determining whether or not to execute the “turning effect”. Here, both “normal fluctuation” and “normal reach” are effects that do not perform pseudo-continuous effects. Therefore, when it is determined to execute the “swing effect” here, the effect to be executed is the “gase effect”. When executing “Gassing effect”, after performing “Button effect” or “Slip effect”, the final stop effect symbol is not “NEXT” (for example, a number such as “2”). Then, the changing production is finished.

  In step S1341-3-5, the sub CPU 102a analyzes the special figure variation pattern designation command and determines whether or not the special symbol variation pattern is to execute the pseudo-continuous effect, that is, the pseudo-continuous number is one or more times. Is determined (see FIG. 9). Then, when the pseudo continuous effect is executed, the process proceeds to step S1341-3-6. When the pseudo continuous effect is not executed (when the pseudo continuous effect number is 0), the process moves to step S1341-3-7.

  In step S <b> 1341-3-6, the sub CPU 102 a executes a roaring effect determination process for determining an effect symbol (“beating line”) used for the roaring effect and the type of the roaring effect. As described above, the “turning effect” is performed using the final temporary stop effect design, and the temporary temporary stop effect design is temporarily stopped at “NEXT”, so that the pseudo variable display is performed (the variable display is continued). To do). That is, the final temporary stop effect symbol in the roaring effect becomes the “turning line”. For example, as shown in FIGS. 54 (c-2) and (c-3), after the left effect symbol is temporarily stopped at “3” and then the right effect symbol is temporarily stopped at “2”, After performing the “buzzing effect”, temporarily stop at “NEXT”. In this case, the medium performance symbol is the “scoring line”. Therefore, in the present embodiment, the effect symbol is composed of three columns of the left effect symbol, the middle effect symbol, and the right effect symbol, so that the “swing line” is any one of the left effect symbol, the middle effect symbol, and the right effect symbol. Further, there are two types of turn production, “button production production” and “slip production production”, and one type of production production is determined.

  Specifically, the sub CPU 102a refers to the table for determining the production effect shown in FIG. 49, and based on the variation pattern designation command and the random value for judging the production effect obtained in step S1341-2, Decide on the line and the type of production.

  For example, when the low-order byte of the variation pattern designation command is “05H”, the pre-reach pseudo variation display is “SP reach 1”, and therefore the turn effect is one. In this case, the roaring line is determined to be the left effect symbol at a rate of 15%, the type of the roaring effect is determined to be the button effect, and the roaring column is determined to be the left effect symbol at the rate of 15%. It is determined to be a sprinkle production, and the strike line is determined to be a medium production symbol at a rate of 25%, the type of the roll production is decided to be a button production, and the strike row is decided to be a medium production symbol at a rate of 15%. The type of production is determined to be a smooth production, the rate of 15% is determined to be the right design, the type of performance is determined to be the button production, and the rate is 15% to the right design. As a result, the type of the squealing effect is determined to be a smoothing effect.

  Further, when the lower byte of the variation pattern designation command is “06H”, the pseudo variation display after reach is “SP reach 1” once, so that the turn effect is one. In this case, the hit line is determined to be a medium effect symbol at a rate of 50%, the type of the hit effect is determined to be a button effect, and the hit column is determined to be a medium effect symbol at a rate of 50%. Decided to produce a smooth play. As described above, in the present embodiment, when the pseudo-continuous effect includes the post-reach pseudo-variable display, the roaring effect is a medium effect symbol.

  Further, when the lower byte of the variation pattern designation command is “07H”, the pre-reach pseudo variation display is “SP reach 1” twice, so that the roaring effect is twice. In this case, at the rate of 15%, the first hitting effect is determined as a button hitting effect with a left effect symbol for the hitting row, and the second hitting effect is determined as a button hitting effect with the hitting symbol for the left effect symbol. Further, at the rate of 15%, the first roll production is determined to be a smooth production of the left production symbol in the turn row, and the second roll production is determined to be a smooth production of the left production design in the turn row. Further, at the rate of 25%, the first hitting effect is determined to be a button hitting effect in which the hitting row is a middle effect symbol, and the second hitting effect is determined to be a button hitting effect in which the hitting row is a middle effect symbol. In addition, at the rate of 15%, the first roll production is determined to be a smooth production with a middle production symbol in the middle row, and the second production is determined to be a middle production design with the middle production symbol. Further, at the rate of 15%, the first hitting effect is determined to be a button-ringing effect with the right effect symbol for the hitting row, and the second hitting effect is determined to be the buttoning effect for the right effect symbol with the hitting row. Further, at the rate of 15%, the first roll production is determined to be a smooth production with the right production symbol in the turn column, and the second production production is a production of the right production in the right production pattern.

  As described above, when the number of pseudo-continuations is two or more and the roaring effect is performed a plurality of times, the roaring row is the same for the first roaring effect and the second and subsequent roaring effects. In other words, when the first turn effect line is the right effect design, the second and subsequent turn effects are also the right effect design. In addition, when the number of pseudo-continuations is two or more and the roaring effect is performed a plurality of times, the type of the first roaring effect and the type of the roaring effect after the second time are the same. In other words, if the first roll production is a button production, the second production or later is also a button production, and if the first production is a smooth production, the second or later production is also a smooth production. .

  Note that, in this embodiment, the first turn effect and the second and subsequent turn effects are the same, but for example, the first time is the turn effect of the pre-reach pseudo-variable display. When both the pre-reach pseudo-variation display and post-reach pseudo-variation display are performed during one fluctuation display, such as when the post-reach pseudo-variation display is a flip effect, the first turn effect and the second and subsequent flip effects The hit lines may be the same or different.

  In step S1341-3-7, the sub CPU 102a executes a title mode determination process for determining a title display mode. The title is a title display for notifying the type of the reach effect when the reach effect is started (for example, the title display shown in FIG. 54 (b-3)). In this embodiment, the title mode is “black characters”. ”(For example, FIG. 54 (b-3))“ red character ”and“ gold character ”(for example, FIG. 57 (1-15)), one of them is determined. Note that the form of the title is not limited to the character color of the title, but the character type displayed with the title display, the voice type output with the title display, or the movement of the characters when the title is displayed. There may be.

  Specifically, the sub CPU 102a refers to the title mode determination table shown in FIG. 50, and determines the type of the notice effect based on the variation pattern designation command and the random number value for title determination acquired in step S1341-2. To decide. For example, if the lower byte of the variation pattern designation command is “03H”, the lottery result is “Long Reach”, which is determined to be “Long Reach” at a rate of 90%, and “Red” at a rate of 1%. The title is “letter”. In addition, when the lower byte of the variation pattern designation command is “04H”, the lottery result is “SP reach 1” with the number of pseudo-continuations being zero, and the “black character” title at a rate of 80%. The title of “red letters” is decided at a rate of 19%, and the title of “gold letters” is decided at a rate of 1%. Also, when the lower byte of the variation pattern designation command is “06H”, the lottery result is “lost” and the number of pseudo-continuations is “SP reach 1”, and the title of “black character” is 60%. The title of “red letters” is decided at a rate of 39%, and the title of “gold letters” is decided at a rate of 1%. In addition, when the lower byte of the variation pattern designation command is “C1H”, the lottery result is “SPSP reach 2” with the number of pseudo-continuations being zero, and the title of “black characters” at a rate of 60%. The title of “red letters” is decided at a rate of 35%, and the title of “gold letters” is decided at a rate of 5%. If the lower byte of the variation pattern designation command is “02H”, the lottery result is “normal reach” for losing, and the title is not displayed.

  Thus, the determination ratio of the title mode differs depending on the type of reach production. In addition, the title of “gold characters” is not determined for “normal reach” and “long reach”. In addition, “SPSP reach 1” and “SPSP reach 2” have a higher ratio of “red character” titles than “SP reach 1” and “SP reach 2”. Also, the title of “gold characters” is higher in the determination ratio of “SPSP reach 1” or “SPSP reach 2” than “SP reach 1” or “SP reach 2”. Furthermore, even for the same type of reach production, the greater the number of pseudo-reams, the higher the ratio of “red letters” and “gold letters” being determined. Also, even if it is the same type of reach production, and even if the number of pseudo-repetition times is the same, the determination ratio of the aspect of the title determined by whether the lottery result is a loss or a big hit is different, and the lottery result is a loss In the case where the lottery result is a big hit, the ratio of “red letters” and “gold letters” titles is higher than “black letters”. Therefore, it can be said that the title of “red letters” and “gold letters” is a production with a higher expectation degree of jackpot than the title of “black letters”. In addition, when comparing the decision ratio of the title of “red letters” and the decision ratio of the titles of “gold letters”, the title of “red letters” is determined even if the lottery result is lost, The title of “gold characters” is hardly determined when the lottery result is lost, but the determination ratio is high when the winner is a big hit. Therefore, it can be said that the expectation degree of jackpot for “gold characters” is the highest and the expectation degree for jackpot of “black letters” is the lowest.

  In step S1341-3-8, the sub CPU 102a executes a jackpot expectation degree display mode determination process for determining a mode for performing the jackpot expectation level display performed on the display unit 140 of the image display device 14. The jackpot expectation level display is a display for visually informing the player of the expectation level that will be a jackpot as a result of the reach effect. In the present embodiment, the jackpot expectation display is performed by displaying a maximum of 10 stars on the display unit 140 of the image display device 14 together with the title display of the reach effect (for example, as shown in FIG. 54B-3). Expected jackpot expectation display). Then, the larger the number of stars displayed, the higher the degree of expectation for jackpots. In the present embodiment, the jackpot expectation display is performed by displaying a maximum of 10 stars. However, the present invention is not limited to this. For example, the jackpot expectation is notified by a barometer bar display, a numerical display, a pie chart display, or the like. You may make it do.

  Specifically, the sub CPU 102a refers to the jackpot expectation degree determination table shown in FIG. 51 and is determined in step S1341-3-7, the type of reach effect analyzed from the variation pattern designation command, the number of pseudo consecutive times, and the like. The mode of the jackpot expectation degree display is determined based on the type of the title display and the current gaming state. The jackpot expectation (number of stars) displayed by the jackpot expectation display is a guideline display of the jackpot expectation given to the player to the last.

  For example, if the reach performance is “SP reach 1”, the pseudo-repetition count is 0, the title is “black letters”, and the current state is a non-short game state, the jackpot expectation is determined to be “1”. Then, the expectation of big hit of “one star” is displayed. In addition, when the reach production is “SP reach 1”, the number of pseudo-continuous times is 1 (pre-reach pseudo-variable display 1 time), the title is “black letters”, and the current state is a non-short game state, The jackpot expectation is determined to be “1”, and the jackpot expectation display of “one star” is performed. In addition, when the reach production is “SP reach 1”, the number of pseudo-continuations is 1 (1 pseudo-variable display after reach), the title is “black letters”, and the current state is a non-short game state, The jackpot expectation is determined to be “2”, and the jackpot expectation display of “two stars” is performed. In this way, when the reach type is the same type and the number of pseudo-reams is the same, the expectation of jackpot is greater when the pseudo-ream effect is a pseudo-variable display after reach than when it is a pseudo-variable display before reach. Is getting higher.

  In addition, when the reach production is “SP reach 1”, the pseudo-continuous number is 2 times (pre-reach pseudo-variable display 2 times), the title is “black letters”, and the current state is a non-short game state, The jackpot expectation is determined as “3”, and the jackpot expectation display of “three stars” is performed. On the other hand, when the reach performance is “SP reach 1”, the number of pseudo-continuations is 2 (post-reach pseudo-variable display 2 times), the title is “black letters”, and the current state is a non-short game state. The jackpot expectation degree is determined to be “5”, and the jackpot expectation degree display of “5 stars” is performed. Thus, when the same kind of reach effect is performed, the greater the number of post-reach pseudo-variable displays, the higher the jackpot expectation.

  Also, if the reach performance is “SP reach 1”, the number of pseudo-reams is 0, the title is “red letters”, and the current state is a non-short game state, the jackpot expectation is “2”. It is determined, and the jackpot expectation degree display of “two stars” is performed. As described above, when the title is “red character”, the expected degree of jackpot displayed is higher when the title is “red character”.

  In addition, if the reach production is “SP reach 1”, the number of pseudo-continuations is 1 (pre-reach pseudo-variable display 1 time), the title is “black letters”, and the current state is a short-time game state, The degree of expectation is determined to be “4”, and the jackpot expectation degree display of “4 stars” is performed. Thus, the jackpot expectation is higher in the short-time gaming state than in the non-short-time gaming state.

  When the reach effect is “full rotation reach”, the big hit expectation is determined as “10”, and the big hit expectation display of “10 stars” is performed.

  As described above, in this embodiment, the aspect of the jackpot expectation display is determined based on the type of reach effect and the number of pseudo-continuations, but not limited thereto, for example, after determining the aspect of the jackpot expectation display, The type of reach effect and the number of pseudo-continuations may be determined based on the determined jackpot expectation degree display mode. Further, the type of reach effect and the mode of the jackpot expectation degree display may be determined simultaneously.

  In step S1341-3-9, the sub CPU 102a performs processing for determining a variation effect pattern. The variation effect pattern is to determine the specific contents of the variation effect executed in the effect device such as the image display device 14, and the passage of the variation time based on the determined variation effect pattern. A fluctuating effect accompanying this will be performed.

  Specifically, the sub CPU 102a analyzes the special figure variation pattern designation command, and when it is not any reach production, for example, when it is “variation pattern 1”, the variation production pattern is not shown in the variation production pattern determination table (not shown). The random numbers for determination are collated to determine which type of “normal fluctuation” from a plurality of types of “normal fluctuation”. Further, in the case of “variation pattern 2”, the variation effect pattern determination random number is collated with the variation effect pattern determination table to determine which type of “shortening variation” from plural types of “shortening variation”. .

  Also, the special figure variation pattern designation command is analyzed, and in the case of “normal reach” or “long reach”, the variation effect pattern determination random number is collated with a variation effect pattern determination table (not shown), and determined in step S1341-3-7. Based on the displayed title display mode, it is determined which type of “normal reach” or “long reach” is selected from a plurality of types of “normal reach” and “long reach”. Further, in the case of “normal fluctuation” or “normal reach”, and when it is determined in step S1341-3-4 that the gassing effect is to be executed, the roaring row and the type of the roaring effect are determined.

  In addition, when the special pattern fluctuation pattern designation command is analyzed and “SP reach 1”, “SP reach 2”, “SPSP reach 1”, “SPSP reach 2”, and “full rotation reach”, the fluctuation production pattern determination table (not shown) The pattern determination random numbers are collated, the reach effect type determined in step S1341-3-2, the beat sequence and the effect type determined in step S1341-3-6, and in step S1341-3-7 A plurality of types of “SP reach 1”, “SP reach 2”, “SPSP reach 1”, “SPSP reach” based on the determined title display mode and the jackpot expectation level display mode determined in step S1341-3-8. “SP Reach 1” “SP Reach 2” “SPSP” Determining whether the over switch 1 "" SPSP Reach 2 "" full rotation reach ".

  The variation effect pattern determined in this way is collated with the variation effect pattern determination tables of FIGS. 52 and 53, and the variation effect is performed. For example, in the case of “normal reach”, the normal reach is performed after the normal change during the change time of 15 seconds. In addition, in the case of “normal reach” and performing a gassing effect, the effect is performed after the normal reach. Further, when the effect type is “SP reach 1 effect”, the normal change evolves to normal reach and SP reach 1 within a change time of 45 seconds.

  In addition, in the case of “pseudo-continuous effect + SP reach 1 effect” for one time of pre-reach pseudo-change display, the first turn effect is performed after the normal change within the change time of 50 seconds, and further normal change, normal reach, SP reach It develops to 1. Also, in the case of “story 1 stage + SP reach 1 production” with one pseudo-variation display before reach, normal reach and SP reach 1 will be developed after the normal change has progressed to the A story 1 stage within the 50 second fluctuation time. Done. In addition, in the case of “pseudo-continuous effect + SP reach 1 effect” for one time of pseudo-variation display after reach, the first effect is produced after development from normal change to normal reach within 55 seconds of change time. To SP Reach 1. In addition, in the case of “story 1 stage + SP reach 1 production” with one pseudo-variation display after reach, normal reach and SP reach 1 will be performed after developing from normal change to B story 1 stage within 55 seconds of change time. Is called.

  Although the story content is different between the A story and the B story, for example, the appearance characters can be smoothly changed from the first stage of the A story to the second stage of the B story, for example, the appearance characters are the same.

  In addition, in the case of “pseudo-continuous effect + SPSP reach 1 effect” with 2 times of pre-reach pseudo-variation display, within the change time of 75 seconds, the first turn effect is given after the normal change, and then the normal change is made for the second time. Produce a roaring effect, and then develop into normal fluctuation, normal reach, SP reach 1, and SPSP reach 1. In addition, in the case of “story 2 stage + SP reach 1 production” with two pseudo-variation display before reach, normal reach after developing from normal fluctuation to A story 1 stage and A story 2 stage within the fluctuation time of 75 seconds. SP reach 1 and SPSP reach 1 are performed.

  In this way, the determined variation effect pattern advances in accordance with the variation effect pattern determined table based on the variation effect pattern determination table shown in FIGS. 52 and 53. A specific description of each variation effect will be described later with reference to FIGS.

  In step S1341-3-10, the sub CPU 102a sets a variable effect control command corresponding to the variable effect pattern determined in step S1341-3-9 in the transmission buffer of the sub RAM 102c. The variation effect control command set in the transmission buffer is transmitted to the lamp control board 104 and the image control board 105 by the data output processing in step S1600. When the lamp control board 104 and the image control board 105 receive the fluctuation effect control command, the lamp control board 104 and the image control board 105 cause the effect display device such as the image display device 14 to execute the change effect based on the change effect pattern indicated by the command. Thereby, the variation effect based on the variation effect pattern determined in step S1341-3-9 is performed on the display unit 140 of the image display device 14 or the like.

  Here, the display contents of the reach effect are specifically exemplified. 54 to 57 are diagrams illustrating an example of the transition of reach effects performed on the display unit 140 of the image display device 14.

  FIG. 54A is a diagram showing a case where the reach effect is “normal reach”. After starting the variable display (a-1), for example, the left effect symbol is temporarily stopped at “2”, and then the right effect symbol is temporarily stopped at “2”, thereby forming a reach state (a-2). ).

  FIG. 54B is a diagram showing a case where the reach effect is “SP reach 1” with the pseudo-continuous number “0” and the title is “black character”. After starting the variable display (b-1), developing from the normal reach (b-2), the title display of "black letters" and the jackpot expectation display of "one star" are performed (b-3). . When the title display and the jackpot expectation display are performed, the effect of “SP reach 1” is started (b-4).

  FIG. 54 (c) shows that the reach effect is “SP reach 1” with the pseudo-continuous number of times “1” (pre-reach pseudo-variation display 1 time), and the hit effect is a smooth hit with a mid-effect pattern. FIG. 11 is a diagram showing a case where the production is a title and the title is “black letters”. After starting the variable display (c-1), the left effect symbol and the right effect symbol are temporarily stopped at “3” and “2”, respectively, and the medium effect symbol is gradually scroll-displayed at a low speed (c-2). . Then, the medium effect symbol is temporarily stopped at “NEXT” (c-3), the variable display is performed again (c-4), the normal reach is developed (c-5), and the title “black character” is displayed. At the same time, a jackpot expectation degree display of “one star” is performed (c-6). When the title display and the jackpot expectation display are performed, the effect of “SP reach 1” is started (c-7).

  FIG. 54 (d) shows a case where the reach effect is “1 story” + SP reach 1 ”with a pseudo-repetition count of“ 1 ”(one pseudo-variation display before reach) and the title is“ black letters ”. FIG. After starting the variable display (d-1), "A story 1 stage" is performed (d-2, d-3, d-4), developed from normal reach (d-5), the title of "black character" The display is performed, and the jackpot expectation display of “one star” is performed (d-6). When the title display and the jackpot expectation display are performed, the effect of “SP reach 1” is started (d-7). FIG. 54 (c) shows “pseudo-continuous effect + SP reach 1”, whereas FIG. 54 (d) shows “story 1 stage + SP reach 1”, but FIG. 54 (c) and FIG. 54 (d) Are the same variation patterns (see FIGS. 9 to 12, 52, and 53).

  FIG. 54E shows “SP reach 1” in which the reach effect is “1 time” (1 time pseudo-variable display after reach), and the turn effect is a smooth turn of the medium effect symbol in the hit line. FIG. 11 is a diagram showing a case where the production is a title and the title is “black letters”. After starting the variable display (e-1), both the left effect symbol and the right effect symbol are temporarily stopped at “2” and become normal reach (e-2), and the medium effect symbol is gradually scroll-displayed at a low speed. (E-3). Then, the medium effect symbol is temporarily stopped at “NEXT” (e-4), and the variable display is performed again (e-5), which is developed from the normal reach (e-6), and the title of “black character” is displayed. At the same time, a jackpot expectation degree display of “two stars” is performed (e-7). Then, when the title display and the jackpot expectation display are performed, the effect of “SP reach 1” is started (e-8).

  FIG. 55 (f) shows that the reach effect is “SP reach 1” with the pseudo-continuous number of times “2” (pre-reach pseudo-variable display 2 times), and the beat effect is a smooth turn of the left effect symbol. FIG. 11 is a diagram showing a case where the production is a title and the title is “black letters”. After starting the fluctuating display (f-1), the middle effect symbol and the right / left effect symbol are temporarily stopped at “3” and “2”, respectively, and the left effect symbol is gradually scroll-displayed slowly (f-2). The left effect symbol is temporarily stopped at “NEXT” (f-3), and the variable display is performed again (f-4). Then, the middle effect symbol and the right effect symbol are temporarily stopped at “3” and “2”, respectively, the left effect symbol is gradually scroll-displayed at low speed (f-5), and the left effect symbol is “NEXT”. Temporarily stop (f-6). Further, a variable display is performed (f-7), and both the left effect symbol and the right effect symbol are temporarily stopped at “2” and become normal reach (f-8), and the title display of “black character” is displayed. Is displayed and the jackpot expectation degree display of “three stars” is performed (f-9). When the title display and the jackpot expectation display are performed, the effect of “SP reach 1” is started (f-10).

  FIG. 55 (g) shows that the reach effect is “SP reach 1” in which the number of pseudo-continuations is “2” (one pseudo-variation display before reach and one pseudo-variation display after reach), It is the figure which showed the case where a column is a button effect production of a medium production | presentation design, and a title is a "black character." After starting the variable display (g-1), the left effect symbol and the right left effect symbol are temporarily stopped at “3” and “2”, respectively, and the image “Press the button” is temporarily stopped at the middle effect symbol (g -2) When the player operates the operation button 18A or when a predetermined time elapses, the medium effect symbol is temporarily stopped at "NEXT" (g-3). Then, the variable display is performed again (g-4), and both the left effect symbol and the right effect symbol are temporarily stopped at “2” and become normal reach (g-5), and then the “button” is displayed on the medium effect symbol. The image “push” is temporarily stopped (g-6), and when the player operates the operation button 18A or a predetermined time elapses, the medium effect symbol is temporarily stopped at “NEXT” (g-7). Furthermore, a variable display is performed (g-8), and both the left effect design and the right effect design are temporarily stopped at “3” and become normal reach (g-9), and the title display of “black character” is displayed. Is displayed, and the jackpot expectation degree display of “4 stars” is performed (g-10). When the title display and the jackpot expectation display are performed, the effect of “SP reach 1” is started (g-11).

  FIG. 55 (h) shows that the reach effect is “2 stories + SP reach 1” with a pseudo-continuous number of “2” (one pseudo-variation display before reach and one pseudo-variation display after reach). It is the figure which showed the case where is a "black character." After starting the variable display (d-1), "A story 1 stage" is performed (h-2, h-3, h-4), and "B story 2 stages" are performed (h-5, h). -6, h-7, h-8). The left effect design and the right effect design are both temporarily stopped at “3” and become normal reach (h-9), the title of “black letters” is displayed, and “4 stars” The jackpot expectation is displayed (h-10), and the effect of “SP reach 1” is started (h-11). FIG. 55 (g) shows “pseudo-continuous effect + SP reach 1”, whereas FIG. 55 (h) shows “story 2 stages + SP reach 1”. FIG. 55 (g) and FIG. 55 (h) Are the same variation patterns (see FIGS. 9 to 12, 52, and 53).

  FIG. 56 (i) shows that the reach effect is “SP reach 1” with the pseudo-continuous number of times “2” (post-reach pseudo-variable display 2 times), and the hit effect is a button stroke with a middle effect symbol in the hit line FIG. 11 is a diagram showing a case where the production is a title and the title is “black letters”. After starting the variable display (i-1), both the left effect symbol and the right effect symbol are temporarily stopped at “2” and become normal reach (i-2), and the middle effect symbol is “push button”. When the image is temporarily stopped (i-3) and the operation button 18A is operated by the player or a predetermined time elapses, the medium effect symbol is temporarily stopped at "NEXT" (i-4). Then, the variable display is resumed (i-5), and the left effect symbol and the right effect symbol are both temporarily stopped at “2” and become normal reach (i-6). Is temporarily stopped (i-7), and when the player operates the operation button 18A or when a predetermined time elapses, the medium effect symbol is temporarily stopped at "NEXT" (i-8). Further, the variable display is resumed (i-9), and the left effect design and the right effect design are both temporarily stopped at “3” and become normal reach (i-10), and the title display of “black character” is displayed. Is performed, and a jackpot expectation degree display of “5 stars” is performed (i-11), and an effect of “SP reach 1” is started (i-12).

  FIG. 56 (j) shows a case where the reach effect is “story 2 stages + SP reach 1” with a pseudo-continuous number of “2” (pseudo-variable display after reach 2) and the title is “black characters”. FIG. After starting the variable display (j-1), "B story 1 stage" is performed (j-2, j-3, j-4, j-5), and "B story 2 stage" is performed (j -6, j-7, j-8, j-9). The left effect design and the right effect design are both temporarily stopped at "3" and become normal reach (j-10). The title of "black letters" is displayed and "5 stars" The jackpot expectation is displayed (j-11), and the effect of “SP reach 1” is started (j-12). 56 (i) shows “pseudo-continuous effect + SP reach 1”, whereas FIG. 56 (j) shows “story 2 stage + SP reach 1”, but FIG. 56 (i) and FIG. 56 (j) Are the same variation patterns (see FIGS. 9 to 12, 52, and 53).

  FIG. 56 (k) shows “SPSP reach 1” in which the reach effect is “twice” (2 times pseudo-variable display after reach), and the turn effect is a smooth turn of the medium effect symbol. FIG. 11 is a diagram showing a case where the production is a title and the title is “black letters”. After starting the fluctuating display (k-1), both the left effect symbol and the right effect symbol are temporarily stopped at "2" and become normal reach (k-2), and the medium effect symbol is gradually scroll-displayed at a low speed. Then (k-3), the medium effect symbol is temporarily stopped at “NEXT” (k-4). Then, the variable display is resumed (k-5), and the left effect symbol and the right effect symbol are both temporarily stopped at “2” and become normal reach (i-6), and the medium effect symbol is gradually scrolled at a low speed. It is displayed (k-7), and temporarily stops when the medium effect symbol is “NEXT” (k-8). Further, the variable display is resumed, and both the left effect design and the right effect design are temporarily stopped at “3” and become normal reach (k-9), and the title display of “black character” is performed. A big hit expectation display of “5 stars” is performed (h-10), and the effect of “SP reach 1” is started (k-11, k-12). Further, the title of “black letters” is further developed, and the jackpot expectation degree display of “6 stars” is performed to produce “SPSP reach 1” (k-13, k-14).

  FIG. 57 (l) shows a “full rotation reach” in which the number of pseudo-continuations is “3 times” (3 times pseudo-variable display after reach), and the squeezing effect is a button squeezing effect with a squealing row having a medium effect design. It is the figure which showed the case where a title is a "red character". After the change display is started (l-1), both the left effect symbol and the right effect symbol are temporarily stopped at “2” and become normal reach (l-2), and the middle effect symbol is “push button”. When the image is temporarily stopped (1-3) and the operation button 18A is operated by the player or a predetermined time elapses, the medium effect symbol is temporarily stopped at “NEXT” (1-4). Then, the variable display is resumed (1-5), and the left effect symbol and the right effect symbol are both temporarily stopped at “2” to become normal reach (1-6). ”Is temporarily stopped (1-7), and when the player operates the operation button 18A or when a predetermined time has elapsed, the medium effect symbol is temporarily stopped at“ NEXT ”(1-8). Furthermore, the fluctuating display is resumed (1-9), both the left effect symbol and the right effect symbol are temporarily stopped at “3” and become normal reach (1-10). When the operation button 18A is operated by the player or a predetermined time elapses, the medium effect symbol is temporarily stopped at “NEXT” (1-12). Then, the fourth variation display is performed (l-13), and after both the left effect symbol and the right effect symbol are temporarily stopped at “7” and normal reach is reached (1-14), “red character” is displayed. The title display of “10 stars” is displayed (1-15), and the effect of “full rotation reach” is performed (1-16).

  FIG. 57 (m) shows that the reach effect is “3 stories + full rotation reach” with a pseudo-repetition count of “3 times” (3 times pseudo-variable display after reach), and the title is “red letters”. It is the figure which showed the case. After starting the variable display (m-1), "B story 1 stage" is performed (m-2, m-3, m-4, m-5), and then "B story 2 stage" is performed ( m-6, m-7, m-8, m-9) and "B story 3 stages" are performed (m-10, m-11, m-12, m-13). The left effect design and the right effect design are both temporarily stopped at "7" and become normal reach (m-14), and the title of "red letters" is displayed and "10 stars" is displayed. Jackpot expectation is displayed (m-15), and the effect of “full rotation reach” is started (m-16). FIG. 57 (l) shows “pseudo-continuous effect + full rotation reach”, whereas FIG. 57 (m) shows “story 3 stages + full rotation reach”, but FIG. 57 (l) and FIG. 57 (m). ) Is the same variation pattern (see FIGS. 9 to 12, 52, and 53).

  When the variation effect determination process ends, the sub CPU 102a sets a variation effect control command corresponding to the determined variation effect pattern in the transmission buffer of the sub RAM 102c in step S1341-4, and the variation that is the effect time of the variation effect. The effect time is set in the change effect timer counter of the sub RAM 102c, and in step S1341-5, the change effect data corresponding to the change effect pattern is set in the change effect data storage area of the sub RAM 102c.

  The variation effect control command set in the transmission buffer is transmitted to the lamp control board 104 and the image control board 105 by the data output process in step S1600. When the lamp control board 104 and the image control board 105 receive the fluctuation effect control command, the lamp control board 104 and the image control board 105 cause the effect display device such as the image display device 14 to execute the change effect based on the change effect pattern indicated by the command.

  The variation effect timer counter is subtracted every 4 ms in step S1200. The sub CPU 102a can specify the remaining time of the variation effect, that is, the time elapsed since the variation effect was started, by the variation effect timer counter. The sub CPU 102a returns to the command analysis process shown in FIG.

  In step S1350, the sub CPU 102a determines whether or not the command stored in the reception buffer is a special figure fluctuation stop designation command. If the sub CPU 102a determines that the command stored in the reception buffer is a special figure fluctuation stop designation command, it moves the process to step S1351, and if it determines that the command is not a special figure fluctuation stop designation command, it moves the process to step S1360. .

  In step S1351, the sub CPU 102a sets the effect symbol stop control command indicating that the effect symbol stop display is stopped and the effect symbol stop display is performed in the transmission buffer of the sub RAM 102c as the effect symbol change stop processing. The effect symbol fluctuation stop control command is transmitted to the lamp control board 104 and the image control board 105 by the data output process of step S1600. The lamp control board 104 and the image control board 105 receive the effect symbol stop control command, recognize that the variation effect is ended, end the variation effect, and perform stop display of the effect symbol.

  In step S1360, the sub CPU 102a determines whether or not the command stored in the reception buffer is a gaming state designation command. If the sub CPU 102a determines that the command stored in the reception buffer is a gaming state designation command, it moves the process to step S1361, and if it determines that there is no gaming state designation command, it moves the process to step S1362.

  In step S 1361, the sub CPU 102 a performs a gaming state setting process for performing setting according to the gaming state indicated by the received gaming state designation command.

  Here, the game state setting process by the effect control board 102 will be described with reference to FIG. First, in step S1361-1, the sub CPU 102a performs processing for setting data indicating the gaming state indicated by the received gaming state designation command in the gaming state storage area of the sub RAM 102c.

  In step S1361-2, the sub CPU 102a determines whether or not the gaming state has been changed from the short-time gaming state to the non-short-time gaming state in step S1361-1. The case where the time-short gaming state is changed to the non-time-short gaming state is a case where the remaining time-short gaming state (J) = 0, that is, a case where a so-called continuous change is completed. If the gaming state is changed from the time-saving gaming state to the non-time-saving gaming state, the process proceeds to step S 1361-3, and if the gaming state has not been changed from the time-saving gaming state to the non-time-saving gaming state (time-saving gaming state or non-time-saving gaming state). When the state continues or when the non-time saving gaming state is changed to the time saving gaming state), the gaming state setting process is terminated.

  In step S 1361-3, the sub CPU 102 a performs processing for resetting the counter value (P) of the payout point counter. The number of points to be played is the number of points that can be earned by winning at the big prize opening 8 during the big hit. “15”, which is the same as the number of balls to be paid out, is added to the counter value (P), and is reset when the continuous chain ends. By displaying the payout points on the display unit 140 such as the image display device 14, the player can recognize the number of payout balls acquired during the consecutive change as points.

  In step S 1362, the sub CPU 102 a checks whether or not the command stored in the reception buffer is a big winning opening winning designation command or an over winning designation command. Then, if the command stored in the reception buffer is a big prize opening prize designation command or an over prize designation command, the sub CPU 102a shifts the processing to step S1363. On the other hand, if the command stored in the reception buffer is neither the big prize opening prize designation command or the over prize prize designation command, the process proceeds to step S1364.

  In step S 1363, the sub CPU 102 a executes a big winning opening winning process according to the winning of the game ball in the big winning opening 8.

  Here, with reference to FIG. 46A, the big winning opening winning process by the effect control board 102 will be described. First, in step S1363-1, the sub CPU 102a determines whether or not the command stored in the reception buffer is a big winning opening prize designation command. Then, if the command stored in the reception buffer is a big prize opening prize designation command, the process proceeds to step S1363-2, and the command stored in the reception buffer is not a big prize mouth prize designation command but an over prize designation command. If so, the process proceeds to step S1363-4.

  In step S1363-2, the sub CPU 102a performs a process of adding “15” to the counter value (P) of the payout point counter.

  In step S1363-3, the sub CPU 102a uses the values of the “total payout point” and “exit ball point” displayed on the display unit 140 such as the image display device 14 as the counter value (P) of the payout point counter. Update processing is performed according to (see FIG. 58A). The details of the display of “total payout points” and “output points” will be described later.

  In step S1363-4, the sub CPU 102a performs a process of adding “1” to the counter value (O) of the over-winning counter. The value of the over-winning counter is incremented by “1” every time the big winning opening 8 is over-winned, and is reset at the end of the big hit game.

  In step S1363-5, the sub CPU 102a, as shown in FIG. 58B, displays over winning information and a counter value (O) for notifying that the display unit 140 such as the image display device 14 has over won. Process to display the value. Thereby, the player can recognize that it has been over-winning and the number of over-winnings. In the present embodiment, when there is an overwinning, the overwinning information and the overwinning number are only displayed on the display unit 140, but the present invention is not limited to this, and a special effect such as displaying a special character is displayed. May be performed. Further, the special effect may be changed every time the value (O) of the over-winning counter is added. For example, every time the number of over-winning balls increases, the displayed character or background may change, or the shape or color of a message image for notifying that over-winning has occurred. Further, even if the number of over-winning balls increases, the over-winning information may be continuously displayed. In any case, by winning over, an effect different from normal is performed, and an effect that promotes over winning to the player is performed.

  As described above, when the over-winning designation command is received, the process of adding the counter value (P) of the payout point counter is not performed. The counter value (P) of the payout point counter is added only when a special winning opening prize designation command is received. The prize winning designation command is a command that is transmitted when a game ball wins the prize winning slot 8 when the number of prizes received at the prize winning slot 8 is within a predetermined number in the round game. Therefore, the counter value (P) of the payout point counter is only when the game ball wins the big prize opening 8 when the number of winning prizes in the big prize opening 8 is within the predetermined number in the round game. Will be added.

  In the present embodiment, in the special winning opening detection signal input process, the main CPU 101a determines whether or not it is an overwinning and outputs a predetermined command (see FIG. 20). However, the present invention is not limited to this, and the main CPU 101a may cause the sub CPU 102a to perform such a process without determining whether or not an over-winning is received when a large winning opening detection signal is input. Hereinafter, a modified example will be described with reference to FIG. When this modified example is used, the main CPU 101a performs steps S220-4, S220-5, S220-7, S220-8, and S220-9 in the special winning opening detection signal input process shown in FIG. Do not perform the process. Thereby, the control burden of the main CPU 101a can be reduced. Further, since the main CPU 101a does not output an over-winning designation command or an error winning designation command, the sub CPU 102a does not perform the processing of Step S1364 and Step S1365 described later.

  If the command stored in the reception buffer is a big prize opening designation command, first, the sub CPU 102a counts whether or not the game ball won in the big prize opening 8 is over-winning in step S1363-1b. The counter value (D) of the special winning opening detection counter is updated by adding “1”.

  In step S1363-2b, the sub CPU 102a determines whether or not the counter value (D) of the big prize opening detection counter is less than “10” (“1” or more and “9” or less). Then, if the counter value (D) of the big prize opening detection counter is less than “10”, the process proceeds to step S1363-3b, and if the counter value (D) of the big prize opening detection counter is “10” or more, step is performed. The process moves to S1363-5b.

  In step S1363-3-3b, the sub CPU 102a performs a process of adding “15” to the counter value (P) of the outgoing ball point counter.

  In step S1363-4b, the sub CPU 102a uses the values of the “total payout points” and “output points” displayed on the display unit 140 such as the image display device 14 as the counter value (P) of the payout point counter. Update processing is performed according to

  In step S <b> 1363-5 b, the sub CPU 102 a determines whether or not the counter value (D) of the special winning opening detection counter is a value between “10” and “14”. If the sub CPU 102a determines that the counter value (D) is a value not less than “10” and not more than “14”, the sub CPU 102a shifts the process to step S1363-6b, and the value of the counter value (D) is not less than “10” and “14”. If it is determined that the value is not the following value ("15" or more), the process proceeds to step S1363-8b.

  In step S1363-6b, the sub CPU 102a performs a process of adding “1” to the counter value (O) of the over-winning counter. The value of the over-winning counter is incremented by “1” every time the big winning opening 8 is over-winned, and is reset at the end of the big hit game.

  In step S <b> 1363-7 b, the sub CPU 102 a performs a process of displaying over winning information for notifying the display unit 140 such as the image display device 14 that over winning has been performed and the value of the counter value (O).

  In step S1363-8b, the sub CPU 102a displays error information for notifying that an error has been won on the display unit 140 such as the image display device 14, and the like. 16 blinks and external output of error information via the game information output terminal board 108 is executed. Above, description of the modification shown to Fig.46 (a) is complete | finished.

  Note that when the number of wins to the big winning opening 8 exceeds a predetermined number (when over winning), the main CPU 101a may not output the big winning opening detection signal. As a result, the sub CPU 102a does not perform the big winning opening winning process in the case of over winning, and therefore does not perform the process of adding the counter value (P) of the payout point counter. Further, the sub CPU 102a may stop adding the counter value (P) of the payout point counter when the counter value (P) of the payout point counter reaches a predetermined value. The predetermined value is, for example, the maximum payout point in a single jackpot game when there is no over winning, and in this embodiment, the maximum payout point in one round is “2025”. .

  In step S1364, the sub CPU 102a checks whether or not the command stored in the reception buffer is an error winning designation command. If the command stored in the reception buffer is an error winning designation command, the sub CPU 102a proceeds to step S1365. On the other hand, if the command stored in the reception buffer is not an error winning designation command, the process proceeds to step S1370.

  In step S1365, the sub CPU 102a displays error information for notifying that an error has been won on the display unit 140 such as the image display device 14 as shown in FIG. Audio output, blinking of the lighting device 16 for production, and external output of error information via the game information output terminal board 108 are executed. As shown in FIG. 58C, the error information is displayed on the display unit 140 so as to cover the over-winning information. However, the present invention is not limited to this, and error information and over-winning information may be displayed so that they can be viewed at the same time, or the display of over-winning information may be erased when displaying error information.

  This error information is output when a large winning opening prize designation command is received and there are over a predetermined number (for example, 15) or more, even though the current game is not a big hit game. When error information is output when the jackpot game is not in progress, the normal game image is displayed on the display unit 140, so that the display of the game image is not disturbed. You may make it perform only audio | voice output and external output, without displaying error information. Also, the error information output method may be different between when the jackpot game is not played and when the jackpot game is not played.

In step S1370, the sub CPU 102a checks whether or not the command stored in the reception buffer is an opening designation command.
If the command stored in the reception buffer is an opening designation command, the sub CPU 102a shifts the processing to step S1371. On the other hand, if the command stored in the reception buffer is not an opening designation command, the sub CPU 102a moves the process to step S1380.

  In step S1371, the sub CPU 102a performs an opening effect pattern determination process for determining an opening effect pattern.

  In this opening effect pattern determination process, an opening effect pattern is determined based on the opening designation command, and the determined opening effect pattern is set in the effect pattern storage area. Then, in order to transmit the information of the determined opening effect pattern to the lamp control board 104 and the image control board 105, an effect pattern designation command based on the determined opening effect pattern is set in the transmission buffer of the sub RAM 102c.

  Further, as shown in FIG. 58A, the sub CPU 102 a performs a process of displaying “total payout points” and “output points” on the display unit 140 such as the image display device 14. In this “Total Outgoing Points”, the outgoing ball points (counter value (P)) added during the so-called continuous change are displayed, and in “Outgoing Ball Points”, the planned outgoing points in the jackpot game, The current value of the play points during the jackpot game is displayed. The scheduled payout point is a value obtained by multiplying “15”, which is the same as the number of balls to be paid out, every time a prize is placed in the big winning opening 8, and “9”, which is the prescribed number in a round game, and the number of rounds of the jackpot game.

  In the present embodiment, during the jackpot game, the “total appearance points” and the “out appearance points” are displayed on the display unit 140, but only one of them may be displayed. In addition, “Outgoing points” displays the scheduled outgoing points for the jackpot game and the current outgoing points during the jackpot game, but do not display the scheduled outgoing points. Also good. Moreover, you may make it perform various effects, such as performing the audio | voice output from the audio | voice output apparatus 15, whenever a payout point increases.

In step S1380, the sub CPU 102a checks whether or not the command stored in the reception buffer is a round designation command.
If the command stored in the reception buffer is a round designation command, the sub CPU 120a moves the process to step S1381. On the other hand, if it is not a round designation command, the sub CPU 102a moves the process to step S1390.

  In step S1381, the sub CPU 102a performs a round effect pattern determination process for determining a round effect pattern.

  In this round effect pattern determination process, a round effect pattern is determined based on the round designation command, and the determined round effect pattern is set in the effect pattern storage area. Then, in order to transmit information on the determined round effect pattern to the lamp control board 104 and the image control board 105, an effect pattern designation command based on the determined round effect pattern is set in the transmission buffer of the sub RAM 102c.

In step S1390, the sub CPU 102a checks whether or not the command stored in the reception buffer is an ending designation command.
If the command stored in the reception buffer is an ending designation command, the sub CPU 102a moves the process to step S1391. On the other hand, if it is not an ending designation command, the sub CPU 102a ends the command analysis processing this time.

  In step S1391, the sub CPU 120a performs an ending effect pattern determination process for determining an ending effect pattern, and ends the current command analysis process.

  In this ending effect pattern determination process, an ending effect pattern is determined based on the ending designation command, and the determined ending effect pattern is set in the effect pattern storage area. Then, in order to transmit information on the determined ending effect pattern to the lamp control board 104 and the image control board 105, an effect pattern designation command based on the determined round effect pattern is set in the transmission buffer of the sub RAM 102c.

  Further, the sub CPU 102a performs processing for resetting the counter value (O) of the over-winning counter. Further, when error information is output from the display unit 140 such as the image display device 14, the audio output device 15, the effect lighting device 16, and the game information output terminal board 108, the sub CPU 102a outputs the error information. Process to stop.

  ◆ As mentioned above, when the number of pseudo-continuations is 2 or more and the roaring effect is performed multiple times, the roaring row is the same for the first roaring effect and the second and subsequent roaring effects. . In other words, if the first roll production line is the right production design, the second production production is also the right production design, and the first production production is the middle production design. The roaring production also has a medium production pattern (see Fig. 49).

  In addition, in this embodiment, when performing the turn production multiple times, the turn rows of all turn production are the same, but not limited to this, the turn row and post reach of the turn production of the pre-reach pseudo variation It may be different from the quasi-variable inversion sequence. In other words, it is sufficient that at least the hit lines of the turn effect before reaching reach are the same. For example, as in the modification shown in FIG. 59 (n), the hit line of the turn effect before reaching is performed. The roaring line of the roaring effect after the reach is performed does not have to be the same. FIG. 55 (n) shows that the reach effect is “SP reach 1” with a pseudo-continuous number of “2 times” (one pseudo-variation display before reach and one pseudo-variation display after reach), and the first turn The effect is a diagram showing a case where the hitting line is a button effect effect of the left effect symbol, and the second effect of the effect is a button effect effect of the hit effect row being the button effect effect of the middle effect symbol. After starting the variable display (n−1), the left effect symbol and the right left effect symbol are temporarily stopped at “3” and “2”, respectively, and the image “Press the button” is temporarily stopped on the left effect symbol (n -2) When the player operates the operation button 18A or when a predetermined time elapses, the left effect symbol is temporarily stopped at "NEXT" (n-3). Then, the variable display is performed again (n-4), and both the left effect symbol and the right effect symbol are temporarily stopped at “2” and become normal reach (n-5), and then the “button” is displayed on the middle effect symbol. The image “push” is temporarily stopped (n-6), and when the player operates the operation button 18A or a predetermined time elapses, the medium effect symbol is temporarily stopped at “NEXT” (n-7).

  In addition, when the number of pseudo-continuations is two or more and the roaring effect is performed a plurality of times, the type of the first roaring effect and the type of the roaring effect after the second time are the same. In other words, if the first roll production is a button production, the second production or later is also a button production, and if the first production is a smooth production, the second or later production is also a smooth production. (See FIG. 49).

  Note that in this embodiment, two types of “buzzing effect” and “slave effect” are performed as the effect of turning, but not limited to this, for example, after the effect symbol scrolls and “NEXT” passes. Various types of roaring effects such as “return reach” that scrolls in the reverse direction and stops at “NEXT” may be executed. In addition, the symbol for notifying that the pseudo-variable display is performed is not limited to “NEXT”, and it may be notified that the pseudo-variable display is performed when a specific character or a numerical symbol is stopped. Furthermore, not only a specific symbol stops but you may make it alert | report that a pseudo-variable display is performed when the symbol of a specific combination called a "chance eye" stops at a specific position.

  Also, when the total number of pseudo-continuous effects is 2, the post-reach pseudo-variable display has the highest ratio of two pseudo-ream effects, and then one pre-reach pseudo-variable display and one post-reach pseudo-display. A high ratio of performing pseudo-continuous production with variable display. Therefore, when the pseudo-variable display after reach is performed twice, the proportion of the pseudo-variable display executed after the second time is high (see FIGS. 9 to 12). That is, when performing pseudo-variable display a plurality of times, the ratio of pseudo-variable display after reach in the second and subsequent pseudo-variable displays is high (see FIGS. 52 to 57).

  In addition, when performing pseudo fluctuation display a plurality of times, the ratio of the second pseudo fluctuation display to the pseudo fluctuation display after reach is high (see FIGS. 9 to 12 and FIGS. 52 to 57).

  In addition, SP reach 1, SP reach 2, SPSP reach 1, SPSP reach 2, and full rotation reach have higher expectation levels than normal reach. When performing pseudo-continuous production, normal reach is executed before execution of pseudo-variable display, but SP reach 1, SP reach 2, SPSP reach 1, SPSP reach 2, and full rotation reach are executed with pseudo-variable display. Done later. Therefore, the reach effect performed after the execution of the pseudo-variable display has a higher jackpot expectation than the reach effect performed before the execution of the pseudo-variable display (see FIGS. 51 to 53).

  In addition, when the jackpot determination result is a jackpot, the post-reach pseudo-variable display has the highest ratio of performing two pseudo-continuous effects, then one pre-reach pseudo-variable display and one post-reach pseudo-variable display. The ratio of performing the pseudo-continuous effect is high, and the ratio of the pseudo-variable display after reaching once is high. Thus, when the jackpot determination result is a jackpot, the number of post-reach pseudo-variable displays tends to increase, and the greater the number of post-reach pseudo-variable displays, the higher the jackpot expectation. (See FIGS. 9 to 12).

  Further, when the number of pseudo consecutive times is the same, the expectation of jackpot is higher when the post-reach pseudo-variable display is performed than when the pre-reach pseudo-variable display is performed (FIGS. 9 to 12 and FIG. 51). reference).

  In addition, during the execution period of the pseudo-continuous effect, in addition to performing the pseudo-continuous effect, it is possible to perform a special effect. Special effects are effects that combine story effects and pseudo-ream effects and story effects. In other words, the special effect is an effect that can be executed instead of the pseudo-continuous effect. When the lottery result is a big win, the ratio of determining the special effect is higher than the case of the big win, and the special effect has a higher degree of expectation of the big hit than the pseudo-continuous effect (see FIG. 48). .

  In the present embodiment, during the jackpot game, the number of balls that can be obtained by winning the jackpot 8 during the jackpot on the display unit 140 such as the image display device 14 is expressed as a point. Point (P) is displayed (see FIG. 58 (a)). As for the payout points (P), “15”, which is the same as the number of payout balls, is added every time a prize is placed in the special winning opening 8. However, in the case of over-winning in which the prize winning opening 8 is closed after reaching the predetermined number 9 in the round game until the closing prize opening 8 is closed, the payout points (P) are not added. (See FIG. 41).

  Further, in this embodiment, when there is an over winning, as shown in FIG. 58 (b), it is notified that there has been an over winning and the number of over winning (O) during the round game is displayed. The However, when the number of over winnings exceeds five, error information is displayed on the display unit 140 such as the image display device 14, the sound output from the sound output device 15, the blinking of the lighting device 16 for production, and the game Error information is externally output via the information output terminal board 108 (see FIGS. 20 and 41).

  Even when the game ball is won in the big winning opening 8 even though the game is not a big hit game, error information is displayed on the display unit 140 such as the image display device 14 and the sound from the audio output device 15 is also displayed. Output, blinking of the lighting device 16 for production, and external output of error information via the game information output terminal board 108 are performed (see step S1363-4 above).

  Note that the gaming machine of the present invention is not limited to a pachinko gaming machine, and can also be used for a swing type gaming machine (so-called slot machine). Furthermore, it can also be used for Jiyan ball game machines and arrange ball game machines.

Y gaming machine 6 first start opening 6a first start opening detection sensor 7 second start opening 7a second start opening detection sensor 8 large winning opening 9 first winning gate 10 second winning gate 14 image display device 70 second starting opening Control device 80 Big prize opening control device 101 Main control board 101a Main CPU
101b Main ROM
101c Main RAM
102 Production control board 102a Sub CPU
102b Sub ROM
102c Sub RAM

The gaming machine according to the first invention variably displays special game determination means for determining whether or not to control a special game advantageous to the player and a plurality of types of effect symbols when the starting condition is satisfied. When the determination is made by the variable display means having a plurality of variable display parts and the special game determination means, the variable display means controls the variable display of the effect symbols on the variable display parts of the variable display means, and If the determination result indicates that the control is to be performed, an effect symbol display control means for stopping and displaying a predetermined combination of effect symbols is provided, and the effect symbol display control means is in a single variation display. In the above, a pseudo continuous effect control means capable of executing a pseudo continuous effect for performing a pseudo variable display which is a variable display of a pseudo effect design a plurality of times, and the pseudo variation table by the pseudo continuous effect control means During the plurality of using at least one variable display portion of the variable display unit, and the executable tilt effect control means tilting effect that inflame or not again, or pseudo-variable display is performed, the tilt effect control means Pseudo continuous notification control means for notifying that the pseudo-variable display is performed again by causing the variable display unit used for the turning effect executed by And the turning effect control means after executing the turning effect before entering a reach state that constitutes a part of the combination of the specific effect symbols in at least a part of the plurality of variable display portions. In the pseudo-variable display, when the turning effect is executed again, the turning effect is executed using the same variable display unit.

Claims (1)

Special game determination means for determining whether or not to control special game advantageous to the player when the start condition is satisfied;
Variable display means having a plurality of variable display units for variably displaying a plurality of types of effect designs;
When the determination is made by the special game determination means, if the determination result is to control the variation display of the effect symbols in the plurality of variable display portions of the variable display means, and to control the special game, An effect symbol display control means for stopping and displaying a predetermined combination of effect symbols;
The effect symbol display control means includes:
A pseudo continuous effect control means capable of executing a pseudo continuous effect for performing a pseudo variable display which is a variable display of a pseudo effect symbol a plurality of times during one time of variable display;
During the pseudo-variable display by the pseudo-continuous effect control means, it is possible to execute a squeak effect that determines whether or not pseudo-variable display is performed again using at least one of the plurality of variable display units. And a production control means,
The roaring effect control means includes:
At least in a part of the plurality of variable display portions, the turning effect is executed again in the pseudo-variable display after the turning effect is executed before the reach state that constitutes a part of the combination of the specific effect symbols. In the case of playing, the game machine is characterized in that the turning effect is executed using the same variable display unit.